TPS25833QCWRHBRQ1

TPS25832-Q1, TPS25833-Q1 SLVSEH7D – JULY 2019 – REVISED MARCH 2022 TPS2583x-Q1 Automotive USB Type-C® and BC1.2 5-V 3.5-A Output, 36-V Input Synchronous DC/DC Regulator with Cable Compensation • 1 Features • • • • • 2 Applications • • • Automotive infotainment USB media hubs USB charger ports 3 Description The TPS2583x-Q1 is a USB Type-C and BC1.2 charging port controller that includes a synchronous DC/DC converter. With cable droop compensation, the VBUS voltage remains constant regardless of load current, ensuring connected portable devices charge at optimal current and voltage. The TPS25832-Q1 includes high bandwidth analog switches for DP and DM pass-through, while the TPS25833-Q1 includes a thermistor input pin and thermal warning flag for user programmable thermal overload protection. Device Information(1) PART NUMBER TPS25832-Q1 TPS25833-Q1 (1) PACKAGE VQFN (32) BODY SIZE (NOM) 5.00 mm × 5.00 mm For detail part numbers for all available different options, see the orderable addendum at the end of the data sheet. 100 CBOOT 95 VIN BOOT IN L RSNS SW 90 RSET EN/UVLO CSP RT/SYNC CSN/OUT VCC TPS2583x-Q1 LS_GD FAULT Optional LD_DET POL BUS CTRL1 CC1 CTRL2 CC2 DP_OUT (THERM_WARN) DP_IN DM_OUT (NTC) IMON DM_IN ILIMIT AGND PGND Simplified Schematic TPS2583x-Q1 Efficiency (%) • AEC-Q100 qualified for automotive applications: – Temperature grade 1: –40°C to +125°C, TA – HBM ESD classification level H2 – CDM ESD classification level C5 Functional Safety-Capable – Documentation available to aid functional safety system design Synchronous buck DC/DC regulator – Input voltage range: 4.5 V to 36 V – Output current: 3.5 A – 5.1-V output voltage with ±1% accuracy – Current mode control – Adjustable frequency: 300 kHz to 2.2 MHz – Frequency synchronization to external clock – FPWM with spread-spectrum dithering – Internal compensation for ease of use Compliant to USB-IF standards – USB Type-C® Rev 1.3 • CC logic, VCONN source and discharge • USB cable polarity detection (POL) – CDP/SDP Mode per USB BC1.2 – Automatic DCP modes (TPS25833-Q1 only) • DCP shorted mode and YD/T 1591-2009 • 2.7-V divider 3 mode • 1.2-V mode Optimized for USB power and communication – User-programmable USB current limit – Cable droop compensation up to 1.5 V – High bandwidth data switches on DP and DM (TPS25832-Q1 only) – NTC input for intelligent thermal management (TPS25833-Q1 only) Type-C Connector • Integrated protection – DP_IN and DM_IN Short-to-VBUS protection – DP_IN, DM_IN, CCx IEC 61000-4-2 rated • ±8-kV contact and ±15-kV air discharge Fault flag reports 32-pin QFN package with wettable flank 85 80 75 70 VIN = 6V VIN = 13.5V VIN = 18V VIN = 36V 65 60 0.1 1 OUT Current (A) 4 A001 Efficiency vs Output Current fsw = 400 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. TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 Table of Contents 1 Features............................................................................1 2 Applications..................................................................... 1 3 Description.......................................................................1 4 Revision History.............................................................. 2 5 Description (Continued)..................................................3 6 Device Comparison Table...............................................3 7 Pin Configuration and Functions...................................4 8 Specifications.................................................................. 6 8.1 Absolute Maximum Ratings........................................ 6 8.2 ESD Ratings............................................................... 7 8.3 Recommended Operating Conditions.........................7 8.4 Thermal Information....................................................8 8.5 Electrical Characteristics.............................................8 8.6 Timing Requirements................................................ 13 8.7 Switching Characteristics..........................................13 8.8 Typical Characteristics.............................................. 15 9 Parameter Measurement Information.......................... 21 10 Detailed Description....................................................22 10.1 Overview................................................................. 22 10.2 Functional Block Diagram....................................... 23 10.3 Feature Description.................................................23 10.4 Device Functional Modes........................................47 11 Application and Implementation................................ 51 11.1 Application Information............................................51 11.2 Typical Application.................................................. 51 12 Power Supply Recommendations..............................62 13 Layout...........................................................................62 13.1 Layout Guidelines................................................... 62 13.2 Ground Plane and Thermal Considerations............63 13.3 Layout Example...................................................... 64 14 Device and Documentation Support..........................65 14.1 Documentation Support.......................................... 65 14.2 Receiving Notification of Documentation Updates..65 14.3 Support Resources................................................. 65 14.4 Trademarks............................................................. 65 14.5 Electrostatic Discharge Caution..............................65 14.6 Glossary..................................................................65 15 Mechanical, Packaging, and Orderable Information.................................................................... 65 4 Revision History NOTE: Page numbers for previous revisions may differ from page numbers in the current version. Changes from Revision C (August 2020) to Revision D (March 2022) Page • Added RHB0032AA package to the data sheet..................................................................................................4 • Added the thermal information for RHB0032AA package.................................................................................. 8 Changes from Revision B (May 2020) to Revision C (August 2020) Page • Updated the numbering format for tables, figures and cross-references throughout the document...................1 • Added functional safety link to the Features section.......................................................................................... 1 Changes from Revision A (September 2019) to Revision B (May 2020) Page • Changed Layout description for clarity............................................................................................................. 62 Changes from Revision * (July 2019) to Revision A (September 2019) Page • Changed TPS25832-Q1 to Production Data...................................................................................................... 1 2 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 5 Description (Continued) The synchronous buck regulator operates with current mode control and is internally compensated to simplify the design. A resistor on the RT pin sets the switching frequency between 300 kHz and 2.2 MHz. Operating below 400 kHz results in better system efficiency. Operation above 2.1 MHz avoids the AM radio bands and allows for use of a smaller inductor. The TPS2583x-Q1 integrates standard USB Type-C port controller functionality including Configuration Channel (CC) logic for 3-A and 1.5-A current advertisement. Battery Charging (Rev. 1.2) integration provides the required electrical signatures necessary for non-Type-C, legacy USB devices that use USB data line signaling to determine USB port current sourcing capabilities. A precision current sense amplifier is included for user programmable cable droop compensation and current limit tuning. Cable compensation aids portable devices in charging at optimum current and voltage under heavy loads by changing the buck regulator output voltage linearly with load current to counteract the voltage drop due to wire resistance in automotive cabling. The VBUS voltage measured at a connected portable device remains approximately constant, regardless of load current, allowing the portable device's battery charger to work optimally. The USB specifications require current limiting of USB charging ports, but give system designers reasonable flexibility to choose overcurrent protection levels based on system requirements. The TPS2583x-Q1 uses a novel two-threshold current limit circuit allowing system designers to either program average current limit protection of the buck regulator, or optionally, current limit using an external NMOS between the CSN/OUT and BUS pins. The NFET implementation enables the TPS2583x-Q1 buck regulator to supply a 5-V output for other loads during an overcurrent fault condition on the USB port. The TPS25832-Q1 includes high bandwidth analog switches for DP and DM pass-through. The TPS25833-Q1 includes a thermistor input pin and thermal warning flag for user programmable thermal overload protection. Integrated protection features include cycle-by-cycle current limit, hiccup short-circuit protection, undervoltage lockout, VBUS overvoltage and overcurrent, CC overvoltage and overcurrent, data line (Dx) short-to-VBUS and die overtemperature protection. 6 Device Comparison Table PACKAGE DCP AUTO DP AND DM SWITCHES NTC INPUT TPS25832-Q1 VQFN (32) No Yes No No No TPS25833-Q1 VQFN (32) Yes No Yes Yes No PART NUMBER THERMAL DP/DM/CC SHORT WARNING FLAG TO VBAT Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 3 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 SW SW PGND PGND PGND 28 27 26 25 PGND 25 SW PGND 26 29 PGND 27 30 SW 28 SW SW 29 31 SW 30 BOOT SW 31 A1 32 BOOT 32 7 Pin Configuration and Functions A4 A1 IN 1 24 FAULT IN 1 24 FAULT IN 2 23 LD_DET IN 2 23 LD_DET IN 3 22 POL IN 3 22 POL EN 4 21 VCC EN 4 21 VCC A4 Thermal Pad Thermal Pad CC1 19 CC2 DP_OUT 7 18 DP_IN THERM_WARN 7 18 DP_IN 17 DM_IN NTC 8 17 DM_IN AGND CSP BUS CSN/OUT IMON ILIMIT LS_GD SW SW SW PGND PGND PGND 29 28 27 26 25 25 30 PGND Figure 7-2. TPS25833QWRHBRQ1 Package 32-Pin (VQFN) Top View (1) SW PGND 26 NOTES: 1) A1, A2, A3, and A4 are corner anchors for enhanced package stress performance. 2) A1, A2, A3, and A4 are electrically connected to the thermal pad. 3) A1, A2, A3, and A4 PCB lands should be electrically isolated or electrically connected to thermal pad and PGND. 31 SW PGND 28 SW 29 27 SW SW 31 30 BOOT Figure 7-1. TPS25832QWRHBRQ1 Package 32-Pin (VQFN) Top View (1) RT/SYNC As of 11/14/2017 NOTES: 1) A1, A2, A3, and A4 are corner anchors for enhanced package stress performance. 2) A1, A2, A3, and A4 are electrically connected to the thermal pad. 3) A1, A2, A3, and A4 PCB lands should be electrically isolated or electrically connected to thermal pad and PGND. 32 A3 BOOT AGND CSP BUS CSN/OUT IMON ILIMIT As of 11/14/2017 LS_GD RT/SYNC A3 A2 32 A2 9 16 15 14 13 12 10 11 8 9 DM_OUT 16 20 6 15 5 CTRL2 14 CTRL1 CC2 13 CC1 19 12 20 6 11 5 CTRL2 10 CTRL1 IN 1 24 FAULT IN 1 24 FAULT IN 2 23 LD_DET IN 2 23 LD_DET IN 3 22 POL IN 3 22 POL EN 4 21 VCC EN 4 21 VCC Thermal Pad Thermal Pad DP_IN 17 8 17 DM_IN 13 14 15 16 BUS AGND ILIMIT CSP 12 IMON CSN/OUT 10 11 LS_GD 9 RT/SYNC 8 Figure 7-3. TPS25832QCWRHBRQ1 Package 32Pin (VQFN) Top View (2) 16 18 AGND 7 NTC 15 THERM_WARN DM_IN BUS DP_IN 14 18 CSP 7 13 DP_OUT DM_OUT CSN/OUT CC2 12 CC1 19 ILIMIT 20 6 11 5 CTRL2 IMON CTRL1 CC2 10 CC1 19 LS_GD 20 6 9 5 CTRL2 RT/SYNC CTRL1 Figure 7-4. TPS25833QCWRHBRQ1 Package 32Pin (VQFN) Top View (2) Table 7-1. Pin Functions 4 NAME 832-Q1 NO. 833-Q1 NO. TYPE (3) I/O AGND 16 16 G – BOOT 32 32 P BUS 15 15 A I CC1 20 20 A I/O DESCRIPTION Analog ground terminal. Ground reference for internal references and logic. All electrical parameters are measured with respect to this pin. Connect to system ground on PCB. Boot-strap capacitor connection for HS FET driver. Connect a high quality 100-nF capacitor from this pin to the SW pin. VBUS discharge input. Connect to VBUS on USB Connector. Analog input/output. Connect to Type-C CC1 pin. Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 Table 7-1. Pin Functions (continued) NAME 832-Q1 NO. 833-Q1 NO. TYPE (3) I/O DESCRIPTION CC2 19 19 A I/O CSN/OU T Analog input/output. Connect to Type-C CC2 pin. 13 13 A I Negative input of current sense amplifier, also buck output for internal voltage regulation. CSP 14 14 A I Positive input of current sense amplifier. CTRL1 5 5 A I Logic-level control inputs for device/system configuration (see Table 10-10). CTRL2 6 6 A I Logic-level control inputs for device/system configuration (see Table 10-10). DM_IN 17 17 A DM data line. Connect to USB connector. DM_OU T 8 – A DM data line. Connect to USB host controller. DP_IN 18 18 A DP data line. Connect to USB connector. DP_OU T 7 – A DP data line. Connect to USB host controller. EN/ UVLO 4 4 A Enable pin. Do not float. High = on, Low = off. Can be tied to VIN. Precision enable input allows adjustable UVLO by external resistor divider. FAULT 24 24 A ILIMIT 12 12 A External resistor used to set the current-limit threshold (see Table 10-2). IMON 11 11 A External resistor used to set the max cable comp voltage at full load current. IN 1, 2, 3 1, 2, 3 P I Input Supply to regulator. Connect a high-quality bypass capacitor(s) directly to this pin and PGND. LD_DET 23 23 A O Active LOW open-drain output. Asserted when a Type-C UFP is identified on the CC lines. LS_GD 10 10 A NTC – 8 PGND POL 25, 26, 27 25, 26, 27 22 22 O Active LOW open-drain output. Asserted during fault conditions (see Table 10-4). External NMOS gate driver. For TPS25832-Q1, LS_GD pin must be pulled up through a 2.2-kΩ resistor under average current limit mode.(see Current Limit Setting using RILIMIT). I Input for negative temperature coefficient resistor divider. Use to monitor external PCB temperature (see Thermal Sensing with NTC (TPS25833-Q1)). G – Power ground terminal. Connect to system ground and AGND. Connect to bypass capacitor with short wide traces. A O Active LOW open-drain output. Signals which Type-C CC pin is connected to the CC line. This gives cable orientation information needed to mux the super speed lines. Asserted when the CC2 pin is connected to the CC line in the cable. RT/ SYNC 9 9 A Resistor Timing or External Clock input. An internal amplifier holds this terminal at a fixed voltage when using an external resistor to ground to set the switching frequency. If the terminal is pulled above the PLL upper threshold, a mode change occurs and the terminal becomes a synchronization input. The internal amplifier is disabled and the terminal is a high impedance clock input to the internal PLL. If clocking edges stop, the internal amplifier is re-enabled and the operating mode returns to resistor frequency programming. SW 28, 29, 30, 31 28, 29, 30, 31 P Switching output of the regulator. Internally connected to source of the HS FET and drain of the LS FET. Connect to power inductor. THERM _WARN – 7 A VCC 21 21 P (1) (2) (3) O Active LOW open-drain output. Asserted when voltage at the NTC pin increases above the thermal warning threshold. Output of internal bias supply. Used as supply to internal control circuits. Connect a high quality 2.2-µF capacitor from this pin to GND. For the package drawing, please refer to RHB0032R at the end of the data sheet. For the package drawing, please refer to RHB0032AA at the end of the data sheet. A = Analog, P = Power, G = Ground. Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 5 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 8 Specifications 8.1 Absolute Maximum Ratings Voltages are with respect to GND (unless otherwise noted)(1) PARAMETER Input voltage Output voltage Voltage range MIN MAX IN to PGND –0.3 40 OUT to PGND –0.3 20 EN to AGND –0.3 VIN + 0.3 CSP to AGND –0.3 20 CSN to AGND –0.3 20 BUS to AGND –0.3 18 RT/SYNC to AGND –0.3 6 CTRL1 or CTRL2 to AGND –0.3 6 AGND to PGND –0.3 0.3 SW to PGND –0.3 VIN + 0.3 SW to PGND (less than 10 ns transients) –3.5 40 BOOT to SW –0.3 6 VCC to AGND –0.3 6 LS_GD –0.3 18 CC1 or CC2 to AGND –0.3 7 DP_IN, DM_IN to AGND –0.3 7 DP_OUT, DM_OUT to AGND (TPS25832-Q1 only) –0.3 6 FAULT, POL, LD_DET to AGND –0.3 6 THERM_WARN, NTC to AGND (TPS25833-Q1 only) –0.3 6 ILIMIT or IMON to AGND –0.3 6 Pin positive source current, IVCC VCC Source Current Pin positive source current, ISRC CC1, CC2 5 Pin positive sink current, ISNK CC1, CC2 (while applying VCONN) V mA 1 A THERM_WARN (TPS25833-Q1 only) Internally Limited A –100 100 DP_IN to DM_IN in DCP Auto Mode (TPS25833-Q1 only) –35 35 TJ Junction temperature -40 150 °C Tstg Storage temperature –65 150 °C I/O current (1) 6 V A FAULT, POL, LD_DET DP_IN to DP_OUT, or DM_IN to DM_OUT in SDP, CDP (TPS25832-Q1 only) V Internally Limited Internally Limited Pin positive sink current, ISNK UNIT mA Stresses beyond those listed under Absolute Maximum Rating 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 Condition. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability. Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 8.2 ESD Ratings VALUE V(ESD) (1) (2) (3) (4) Electrostatic discharge UNIT Human body model (HBM), per AEC Q100-002(1) ±2000(2) Charged device model (CDM), per AEC Q100-011 Corner pins (1, 8, 9, 17, 25 and 32) ±750(3) Other pins ±750(3) IEC 61000-4-2 contact discharge DP_IN, DM_IN, CC1 and CC2 pins ±8000(4) IEC 61000-4-2 air-gap discharge DP_IN, DM_IN, CC1 and CC2 pins ±15000(4) V AEC Q100-002 indicates that HBM stressing shall be in accordance with the ANSI/ESDA/JEDEC JS-001 specification. The passing level per AEC-Q100 Classification H2. The passing level per AEC-Q100 Classification C5. Surges per IEC61000-4-2, 1999 applied between DP_IN, DM_IN, CC1, CC2 and output ground of the TPS2583x-Q1 evaluation module. Addition 0.22u cap is needed on CCx pins. 8.3 Recommended Operating Conditions Voltages are with respect to GND (unless otherwise noted) MIN IN to PGND VI Input voltage VPU Pull up voltage VO Output voltage IO Output current EN 0 VIN VCC when driven from external regulator 0 5.5 DP_IN, DM_IN 0 3.6 DP_OUT, DM_OUT (TPS25832-Q1 only) 0 3.6 NTC (TPS25833-Q1 only) 0 VCC CTRL1, CTRL2 0 VCC RT/SYNC when driven by external clock 0 VCC FAULT, LD_DET, POL 0 VCC THERM_WARN (TPS25833-Q1 only) 0 VCC CSN/OUT 0 6.5 Buck regulator output current 0 3.5 DP_IN to DP_OUT or DM_IN to DM_OUT Continuous current in SDP, CDP (TPS25832-Q1 only) –30 30 DP_IN to DM_IN Continuous current in BC1.2 DCP Mode (TPS25833-Q1 only) –15 15 Source current ISNK Sink current II Input current Continuous current into the CSP pin REXT External resistnace RIMON, RILIMIT (1) MAX 36 ISRC TJ NOM 4.5 V A mA CC1 or CC2 source current when supplying VCONN 250 FAULT, LD_DET, POL 10 THERM_WARN (TPS25833-Q1 only) Operating junction temperature UNIT 10 200 µA 0 100 kΩ –40 125(1) °C Operating at junction temperatures greater than 125°C is possible, however lifetime will be degraded. Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 7 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 8.4 Thermal Information TPS2583x-Q1 THERMAL METRIC(1) RHB0032R (VQFN) RHB0032AA (VQFN) 32 PINS 32 PINS UNIT RθJA Junction-to-ambient thermal resistance 28.7 29.4 °C/W RθJC(top) Junction-to-case (top) thermal resistance 17.6 18.6 °C/W RθJB Junction-to-board thermal resistance 7.2 9.7 °C/W ΨJT Junction-to-top characterization parameter 0.2 0.2 °C/W ΨJB Junction-to-board characterization parameter 7.2 9.7 °C/W RθJC(bot) Junction-to-case (bottom) thermal resistance 1 2.3 °C/W (1) For more information about traditional and new thermal metrics, see the Semiconductor and IC Package Thermal Metrics application report. 8.5 Electrical Characteristics Limits apply over the junction temperature (TJ) range of -40°C to +150°C; VIN = 13.5 V, fSW =400 kHz, CVCC = 2.2 µF, RSNS = 15 mΩ, RIMON = 13 kΩ, RILIMIT= 13 kΩ, RSET= 300 Ω 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. PARAMETER TEST CONDITIONS MIN TYP MAX UNIT SUPPLY VOLTATE (IN PIN) VIN Operating input voltage range 4.5 IQ Operating quiescent current (non switching) VEN/UVLO = VIN, CTRL1 = CTRL2 = VCC, VCSN = 8V, CC1 or CC2 = RD, CC2 or CC1 = open IQ-SB Standby quiescent current VEN/UVLO = VIN, CTRL1 = CTRL2 = VCC, CC1 and CC2 = open ISD Shutdown quiescent current; measured at IN pin. EN= 0 700 10 36 V 990 µA 290 µA 16 µA 1.14 V ENABLE and UVLO (EN/UVLO PIN) VEN/UVLO_VCC_H EN/UVLO input level required to turn on internal LDO VEN/UVLO rising threshold VEN/UVLO_VCC_L EN/UVLO input level required to turn off internal LDO VEN/UVLO falling threshold 0.3 VEN/UVLO_H EN/UVLO input level required to turn on state machine VEN/UVLO rising threshold 1.140 VEN/UVLO_HYS Hysteresis VEN/UVLO falling threshold 90 mV ILKG_EN/UVLO Enable input leakage current VEN/UVLO = 3.3 V 0.5 uA 2.2 V V 1.200 1.260 V INTERNAL LDO VBOOT_UVLO Bootstrap voltage UVLO threshold VCC Internal LDO output voltage appearing 6 V ≤ VIN ≤ 36 V on VCC pin VCC_UVLO_R Rising UVLO threshold VCC_UVLO_HYS Hysteresis 4.75 5 5.25 V 3.4 3.6 3.8 V 600 mV CURRENT LIMIT VOLTAGE (CSP - CSN/OUT PINS) TO ACTIVATE BUCK AVG CURRENT LIMITING 8 (VCSP – VCSN/OUT) Current limit voltage buck regulator control loop VCSN = 5 V, RSET = 300 Ω, RILIMIT = 13 kΩ, RIMON = 13 kΩ, -40°C ≤ TJ ≤ 125°C 43.5 46 48.5 mV (VCSP – VCSN/OUT) Current limit voltage buck regulator control loop VCSN = 5 V, RSET = 300 Ω, RILIMIT = 13 kΩ, RIMON = 13 kΩ, -40°C ≤ TJ ≤ 150°C 42.5 46 49.5 mV Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 8.5 Electrical Characteristics (continued) Limits apply over the junction temperature (TJ) range of -40°C to +150°C; VIN = 13.5 V, fSW =400 kHz, CVCC = 2.2 µF, RSNS = 15 mΩ, RIMON = 13 kΩ, RILIMIT= 13 kΩ, RSET= 300 Ω 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. PARAMETER TEST CONDITIONS (VCSP – VCSN/OUT) Current limit voltage buck regulator control loop VCSN = 5 V, RSET = 300 Ω, RILIMIT = 26.1 kΩ, RIMON = 13 kΩ, -40°C ≤ TJ ≤ 125°C (VCSP – VCSN/OUT) Current limit voltage buck regulator control loop VCSN = 5 V, RSET = 300 Ω, RILIMIT = 26.1 kΩ, RIMON = 13 kΩ, -40°C ≤ TJ ≤ 150°C MIN TYP MAX UNIT 20 22.5 25 mV 19 22.5 26 mV CURRENT LIMIT VOLTAGE (CSP - CSN/OUT PINS) TO ACTIVATE EXTERNAL NFET CURRENT LIMITING VCSN = 5 V, RSET = 300 Ω, RILIMIT = (VCSP – VCSN/OUT) Current limit voltage NFET control loop 6.8 kΩ, RIMON = 13 kΩ, -40°C ≤ TJ ≤ 125°C 40 43 46 mV VCSN = 5 V, RSET = 300 Ω, RILIMIT = (VCSP – VCSN/OUT) Current limit voltage NFET control loop 6.8 kΩ, RIMON = 13 kΩ, -40°C ≤ TJ ≤ 150°C 38.5 43 47.5 mV VCSN = 5 V, RSET = 300 Ω, RILIMIT = (VCSP – VCSN/OUT) Current limit voltage NFET control loop 13.7 kΩ, RIMON = 13 kΩ, -40°C ≤ TJ ≤ 125°C 18 21 24 mV VCSN = 5 V, RSET = 300 Ω, RILIMIT = (VCSP – VCSN/OUT) Current limit voltage NFET control loop 13.7 kΩ, RIMON = 13 kΩ, -40°C ≤ TJ ≤ 150°C 17 21 25 mV 4.6 5.4 6.2 A CURRENT LIMIT - BUCK REGULATOR PEAK CURRENT LIMIT IL-SC-HS High-side current limit IL-SC-LS Low-side current limit IL-NEG-LS Low-side negative current limit 3.5 4 4.5 A –3.1 –2.1 –1.3 A CABLE COMPENSATION VOLTAGE VIMON Cable compensation voltage (VCSP – VCSN) = 46 mV, RSET = 300 Ω, RILIMIT = 13 kΩ, RIMON = 13 kΩ 0.935 1 1.065 V VIMON Cable compensation voltage (VCSP – VCSN) = 23 mV, RSET = 300 Ω, RILIMIT = 13 kΩ, RIMON = 13 kΩ 0.435 0.5 0.565 V VIMON Cable compensation voltage (internal clamp) (VCSP –VCSN) = 46 mV, RSET = 300 Ω, RILIMIT = 13 kΩ, RIMON = open 1.8 V BUCK OUTPUT VOLTAGE (CSN/OUT PIN) VCSN/OUT Output voltage CC1 or CC2 pulldown resistance = Rd, RIMON = 0 Ω, RILIMIT = 0 Ω 5.05 VCSN/OUT Output voltage accuracy CC1 or CC2 pulldown resistance = Rd, RIMON = 0 Ω, RILIMIT = 0 Ω –1 VCSN/OUT_OV Overvoltage level on CSN/OUT pin which buck regulator stops switching VCSN/OUT rising 7.1 VCSN/OUT_OV_HYS Hysteresis VHC CSN / OUT pin voltage required to trigger short circuit hiccup mode VDROP Dropout voltage ( VIN-VOUT ) 5.10 7.5 5.15 V 1 % 7.9 V 500 mV 2 VIN = VOUT + VDROP, VOUT = 5.1V, IOUT = 3A V 150 mV BUCK REGULATOR INTERNAL RESISTANCE RDS-ON-HS High-side MOSFET ON-resistance Load = 3 A, TJ = 25°C 40 45 mΩ RDS-ON-HS High-side MOSFET ON-resistance Load = 3 A, -40°C ≤ TJ ≤ 125°C 40 68 mΩ RDS-ON-HS High-side MOSFET ON-resistance Load = 3 A, -40°C ≤ TJ ≤ 150°C 40 75 mΩ RDS-ON-LS Low-side MOSFET ON-resistance Load = 3 A, TJ = 25C 35 41 mΩ RDS-ON-LS Low-side MOSFET ON-resistance Load = 3 A, -40°C ≤ TJ ≤ 125°C 35 60 mΩ Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 9 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 8.5 Electrical Characteristics (continued) Limits apply over the junction temperature (TJ) range of -40°C to +150°C; VIN = 13.5 V, fSW =400 kHz, CVCC = 2.2 µF, RSNS = 15 mΩ, RIMON = 13 kΩ, RILIMIT= 13 kΩ, RSET= 300 Ω 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. PARAMETER RDS-ON-LS TEST CONDITIONS Low-side MOSFET ON-resistance MIN TYP MAX 35 68 9.5 11 12.5 V 2 3 4 µA 20 35 50 µA 2.85 3 3.15 V Load = 3 A, -40°C ≤ TJ ≤ 150°C UNIT mΩ NFET GATE DRIVE (LS_GD PIN) VCSN/OUT = 5.1 V, CG = 1000 pF (see Figure 9-4) VLS_GD NFET gate drive output voltage ILS_DR_SRC NFET gate drive output source current VCSN/OUT = 5.1 V, CG = 1000 pF ILS_DR_SNK NFET gate drive output sink current VCSN/OUT = 5.1 V, CG = 1000 pF VLS_GD_UVLO_R VCSN/OUT rising threshold for LS_GD operation VCSN/OUT rising VLS_GD_UVLO_HYS Hysteresis 80 mV BUS DISCHARGE (BUS PIN) RBUS_DCHG BUS discharge resistance VBUS_NO_DCHG Falling threshold for VBUS not discharged RBUS_DCHG_BLEED BUS bleed resistance VBUS = 4 V, No sink termination on CC lines, Time > tW_BUS_DCHG 100 VBUS_OV Rising threshold for BUS pin overvoltage protection VBUS rising 6.6 VBUS_OV_HYS Hysteresis RBUS_DCHG_18V Discharge resistance for BUS RBUS_DCHG_8V Discharge resistance for BUS RDS-ON On-state resistance ICCn = 250 mA, TJ = 25°C 500 540 mΩ RDS-ON On-state resistance ICCn = 250 mA, –40°C ≤ TJ ≤ 125°C, 500 830 mΩ RDS-ON On-state resistance ICCn = 250 mA, –40°C ≤ TJ ≤ 150°C, 500 920 mΩ IOS_CCn VCONN short circuit current limit Short circuit current limit 350 430 550 mA RVCONN_DCHG Discharge resistance CC pin that was providing VCONN before detach: VCCX = 4V 650 850 1100 Ω VTH Falling threshold for discharged CC pin that was providing VCONN before detach 570 600 630 mV VTH Discharged threshold hysteresis VCCx_OV Rising threshold for CCn pin overvoltage protection VCCx_OV_HYS Hysteresis ISRC_CCn Sourcing current on the passthrough CC line CC pin voltage 0 V ≤ VCCn ≤ 1.5 V 64 80 96 µA ISRC_CCn Sourcing current on the Ra CC line CC pin voltage 0 V ≤ VCCn ≤ 1.5 V 64 80 96 µA ISRC_CCn Sourcing current VCTRL1 = VCC and VCTRL2 = VCC, CC pin voltage: 0 V ≤ VCCn ≤ 1.5 V (with CDP mode) 308 330 354 µA ISRC_CCn Sourcing current VCTRL1 = VCC and VCTRL2 = GND, CC pin voltage: 0 V ≤ VCCn ≤ 1.5 V (with SDP mode) 168 180 192 µA ISRC_CCn Sourcing current VCTRL1 = VCC and VCTRL2 = VCC, CC pin voltage: 0 V ≤ VCCn ≤ 1.5 V (with CDP mode) 308 330 354 µA ISRC_CCn Sourcing current VCTRL1 = VCC and VCTRL2 = GND, CC pin voltage: 0 V ≤ VCCn ≤ 1.5 V (with SDP mode) 168 180 192 µA 10 VBUS = 4 V 250 320 550 Ω 0.8 V 130 200 kΩ 7 7.3 V 180 mV VBUS = 18V, measure leakage current 29 kΩ VBUS = 8V, measure leakage current 35 kΩ 100 CC pin voltage VCCn rising 5.8 6.1 mV 6.4 150 Submit Document Feedback V mV Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 8.5 Electrical Characteristics (continued) Limits apply over the junction temperature (TJ) range of -40°C to +150°C; VIN = 13.5 V, fSW =400 kHz, CVCC = 2.2 µF, RSNS = 15 mΩ, RIMON = 13 kΩ, RILIMIT= 13 kΩ, RSET= 300 Ω 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. PARAMETER TEST CONDITIONS MIN TYP MAX UNIT 308 330 354 µA ISRC_CCn Sourcing current VCTRL1 = GND and VCTRL2 = VCC, CC pin voltage: 0 V ≤ VCCn ≤ 1.5 V (with DCP auto mode) IREV Reverse leakage current CCx is the CC pin under test, CCy is the other CC pin. CC pin voltage VCCx = 5.5 V, CCy = 0V or floating, VEN = 0 V, IREV is current into CCx pin 0 5 µA Reverse leakage current CCx is the CC pin under test, CCy is the other CC pin. CC pin voltage VCCx = 5.5 V, CCy = 0, VEN = VIN, IREV is current into CCx pin under test 6 10 µA 250 mV 1 µA 250 mV 1 µA 250 mV 1 µA 2 V IREV FAULT, LD_DET, POL VOL FAULT Output low voltage ISNK_PIN = 0.5 mA IOFF FAULT Off-state leakage VPIN = 5.5 V VOL LD_DET, POL Output low voltage ISNK_PIN = 0.5 mA IOFF LD_DET, POL Off-state leakage VPIN = 5.5 V THERM_WARN (TPS25833-Q1) VOL THERM_WARN Output low voltage ISNK_PIN = 0.5 mA IOFF THERM_WARN Off-state leakage VPIN = 5.5 V CTRL1, CTRL2 - LOGIC INPUTS VIH Rising threshold voltage VIL Falling threshold voltage VHYS Hysteresis IIN Input current 1.48 0.85 1.30 V 180 mV –1 1 µA 4.15 V DP_IN AND DM_IN OVERVOLTAGE PROTECTION VDx_IN_OV Rising threshold for Dx_IN overvoltage DP_IN or DM_IN rising protection Hysteresis 3.7 3.9 100 mV HIGH-BANDWIDTH ANALOG SWITCH (TPS25832-Q1) RDS_ON DP and DM switch on-resistance VDP_OUT = VDM_OUT = 0 V, IDP_IN = IDM_IN = 30 mA 3.4 6.3 Ω RDS_ON DP and DM switch on-resistance VDP_OUT = VDM_OUT = 2.4 V, IDP_IN = IDM_IN = –15 mA 4.3 7.7 Ω |ΔRDS_ON| Switch resistance mismatch between DP and DM channels VDP_OUT = VDM_OUT = 0 V, IDP_IN = IDM_IN = 30 mA 0.05 0.15 Ω |ΔRDS_ON| Switch resistance mismatch between DP and DM channels VDP_OUT = VDM_OUT = 2.4 V, IDP_IN = IDM_IN = –15 mA 0.05 0.15 Ω CIO_OFF DP/DM switch off-state capacitance VEN = 0 V, VDP_IN = VDM_IN = 0.3 V, Vac = 0.03 VPP , f = 1 MHz 6.7 pF CIO_ON DP/DM switch on-state capacitance VDP_IN = VDM_IN = 0.3 V, Vac = 0.03 VPP, f = 1 MHz 10 pF OIRR Off-state isolation VEN = 0 V, f = 250 MHz 9 dB XTALK On-state cross-channel isolation f = 250 MHz 29 dB Ilkg(OFF) Off-state leakage current, DP_OUT and DM_OUT VEN = 0 V, VDP_IN = VDM_IN = 3.6 V, VDP_OUT = VDM_OUT = 0 V, measure IDP_OUT and IDM_OUT 0.1 BW Bandwidth (–3 dB) RL = 50 Ω 800 1.5 µA MHz Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 11 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 8.5 Electrical Characteristics (continued) Limits apply over the junction temperature (TJ) range of -40°C to +150°C; VIN = 13.5 V, fSW =400 kHz, CVCC = 2.2 µF, RSNS = 15 mΩ, RIMON = 13 kΩ, RILIMIT= 13 kΩ, RSET= 300 Ω 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. PARAMETER TEST CONDITIONS MIN TYP MAX UNIT 0.5 0.6 0.7 V 0.36 0.38 0.4 V CHARGING DOWNSTREAM PORT (CDP) DETECT VDM_SRC DM_IN CDP output voltage VDAT_REF DP_IN rising lower window threshold for VDM_SRC activation VDAT_REF Hysteresis VLGC_SRC DP_IN rising upper window threshold for VDM_SRC deactivation VLGC_SRC_HYS Hysteresis IDP_SINK DP_IN sink current VDP_IN = 0.6 V, –250 µA < IDM_IN < 0 µA 50 0.8 0.84 mV 0.88 100 VDP_IN = 0.6 V 40 V mV 70 100 µA 135 200 Ω BC 1.2 DOWNSTREAM CHARGING PORT (TPS25833-Q1) RDPM_SHORT DP_IN and DM_IN shorting resistance DIVIDER3 MODE (TPS25833-Q1) VDP_DIV3 DP_IN output voltage 2.57 2.7 2.84 V VDM_DIV3 DM_IN output voltage 2.57 2.7 2.84 V RDP_DIV3 DP_IN output impedance IDP_IN = –5 µA 24 30 36 kΩ RDM_DIV3 DM_IN output impedance IDM_IN = –5 µA 24 30 36 kΩ 1.2-V MODE (TPS25833-Q1) VDP_1.2V DP_IN output voltage 1.12 1.2 1.26 V VDM_1.2V DM_IN output voltage 1.12 1.2 1.26 V RDP_1.2V DP_IN output impedance IDP_IN = –5 µA 84 100 126 kΩ RDM_1.2V DM_IN output impedance IDM_IN = –5 µA 84 100 126 kΩ 3.5 RT/SYNC THRESHOLD (RT/SYNC PIN) VIH_RT/SYNC RT/SYNC high threshold for external clock synchronization Amplitude of SYNC clock AC signal (measured at SYNC pin) VIL_RT/SYNC RT/SYNC low threshold for external clock synchronization Amplitude of SYNC clock AC signal (measured at SYNC pin) V 0.8 V VCC × 0.525 V NTC TEMPERATURE SENSING (TPS25833-Q1) VWARN_HIGH Temperature warning threshold rising VWARN_HYS Hysteresis VSD_HIGH Temperature shutdown threshold rising VSD_HYS Hysteresis VCC × 0.475 VCC × 0.5 VCC x 0.1 VCC × 0.618 VCC × 0.65 V VCC × 0.683 V VCC x 0.1 V Shutdown threshold 160 °C Recovery threshold 140 °C THERMAL SHUTDOWN TSD 12 Thermal shutdown Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 8.6 Timing Requirements Limits apply over the junction temperature (TJ) range of -40°C to +150°C; VIN = 13.5 V, fSW =400 kHz, CVCC = 2.2 µF, RSNS = 15 mΩ, RIMON = 13 kΩ, RILIMIT= 13 kΩ, RSET= 300 Ω 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. MIN NOM MAX UNIT SYNC (RT/SYNC PIN) WITH EXTERNAL CLOCK fSYNC Switching frequency using external clock on RT/SYNC pin TSYNC_MIN Minimum SYNC input pulse width TLOCK_IN PLL lock time 300 2300 fSYNC = 400 kHz, VRT/SYNC > VIH_RT/SYNC, VRT/SYNC < VIL_RT/SYNC kHz 100 ns 100 µs 8.7 Switching Characteristics Limits apply over the junction temperature (TJ) range of -40°C to +150°C; VIN = 13.5 V, fSW =400 kHz, CVCC = 2.2 µF, RSNS = 15 mΩ, RIMON = 13 kΩ, RILIMIT= 13 kΩ, RSET= 300 Ω 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. PARAMETER TEST CONDITIONS MIN TYP MAX 3 5 7 UNIT SOFT START TSS The time of internal reference to increase from 0 V to 1.0 V Internal soft-start time ms HICCUP MODE NOC Number of cycles that LS current limit is tripped to enter Hiccup mode 128 Cycles TOC Hiccup retry delay time 118 ms TON_MIN Minimum turnon-time 105 ns TON_MAX Maximum turnon-time, HS timeout in dropout 7.5 µs TOFF_MIN Minimum turnoff time 80 ns Dmax Maximum switch duty cycle 98 % SW (SW PIN) TIMING RESISTOR AND INTERNAL CLOCK fSW_RANGE fSW FSSS Switching frequency range using RT mode 300 2300 kHz Switching frequency RT = 49.9 kΩ 360 400 440 kHz Switching frequency RT = 8.87 kΩ 1953 2100 2247 kHz Frequency span of spread spectrum operation ±6 % BUS DISCHARGE tDEGA_OUT_DCHG Discharge asserting deglitch tW_BUS_DCHG VBUS discharge time after sink termination removed from CC lines VBUS = 1 V, time ISNK_OUT > 1 mA after sink termination removed from CC lines 5.0 12.5 23.4 ms 150 266 400 ms 0.78 1.1 1.95 0.18 0.32 0.37 4.1 6.2 8.5 0.5 1 1.6 CC1/CC2 - VCONN POWER SWITCH 5.1 kΩ on one CC pin and 1 kΩ on the other tr Output voltage rise time tf Output voltage fall time ton Output voltage turnon-time toff Output voltage turnoff time CL = 1 µF, RL = 100 Ω (measured from 10% to 90% of final value) CL = 1 µF, RL = 100 Ω ms ms CC1/CC2 VCONN POWER SWITCH: CURRENT LIMIT tIOS Short circuit response time 15 µs Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 13 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 8.7 Switching Characteristics (continued) Limits apply over the junction temperature (TJ) range of -40°C to +150°C; VIN = 13.5 V, fSW =400 kHz, CVCC = 2.2 µF, RSNS = 15 mΩ, RIMON = 13 kΩ, RILIMIT= 13 kΩ, RSET= 300 Ω 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. PARAMETER TEST CONDITIONS MIN TYP MAX UNIT 1.1 2.08 3.29 ms 6.98 12.7 19.4 ms CC1/CC2 - CONNECT MANAGEMENT - ATTACH AND DETACH DEGLITCH tDEGA_CC_ATT Attach asserting deglitch tDEGD_CC_DET Detach asserting deglitch for exiting UFP state CC1/CC2 - CONNECT MANAGEMENT - ATTACHED MODE 5.1-kΩ or 1-kΩ termination on at least one CC pin tDEGA_CC_SHORT Detach, Rd and Ra asserting deglitch 78 195 366 µs tDEGA_CC_LONG Long deglitch 87 150 217 ms 37 66 99 ms CC1/CC2 - CONNECT MANAGEMENT - VCONN DISCHARGED MODE tW_CC_DCHG Discharge wait time NFET DRIVER tr VLS_DR rise time VOUT = 5.1 V, NFET = CSD87502Q2, time from LS_GD 10% to 90% 1000 µs tf VLS_DR fall time VOUT = 5.1 V, NFET = CSD87502Q2, time from LS_GD time 90% to 10% 100 µs CURRENT LIMIT - EXTERNAL NFET CONNECTED BETWEEN CSN/OUT AND BUS, LS_GD CONNECTED TO FET GATE tOC_HIC_ON ON-time during hiccup mode tOC_HIC_OFF OFF-time during hiccup mode 2 ms 263 ms FAULT DUE TO VBUS OC, VBUS OV, DP OV, DM OV, CC OV, CC OC tDEGLA Asserting deglitch time 5.5 8.2 11.5 ms tDEGLD De-asserting deglitch time 5.5 8.2 11.5 ms tDEGLA Asserting deglitch time 88 150 220 ms tDEGLD De-asserting deglitch time 7.0 12.7 19.4 ms LD_DET, POL THERM_WARN (TPS25833-Q1) tDEGLA Asserting deglitch time 0 ms tDEGLD De-asserting deglitch time 0 ms HIGH-BANDWIDTH ANALOG SWITCH (TPS25832-Q1) tpd Analog switch propagation delay 0.14 ns tSK Analog switch skew between opposite transitions of the same port (tPHL – tPLH) 0.02 ns tOV_Dn DP_IN and DM_IN overvoltage protection response time 2 µs 14 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 8.8 Typical Characteristics 717 230 714 225 Standby Queiscent Current (uA) Non-switching Quiescent Current (uA) Unless otherwise specified the following conditions apply: VIN = 13.5 V, fSW = 400 kHz, L = 10 µH, COUT_CSP = 66 µF, COUT_CSN = 0.1 µF, CBUS = 1 µF, TA = 25 °C. 711 708 705 702 -40C 25C 150C 699 696 220 215 210 205 -40C 25C 125C 150C 200 195 0 4 8 12 VCSN = 8 V 16 20 24 Input Voltage (V) 28 32 36 40 0 CC1= Rd 28 1.2 24 20 16 12 -40C 25C 125C 150C 8 12 16 20 24 Input Voltage (V) 28 32 36 16 20 24 Input Voltage (V) 28 32 36 40 D002 CC2 = OPEN UP DN 1.175 1.15 1.125 1.1 1.075 4 8 12 Figure 8-2. Standby Quiescent Current 1.225 EN Threshold Votlage (V) Shutdown Queiscent Current (uA) Figure 8-1. Non-Switching Quiescent Current 4 8 CC1 = OPEN 32 0 4 D001 1.05 -50 40 -25 0 25 50 75 Temperature (C) D003 100 125 150 D004 Figure 8-4. Precision Enable Threshold EN = 0 V Figure 8-3. Shutdown Quiescent Current 3.9 5.1 UP DN 5.04 3.6 3.45 3.3 5.01 4.98 3.15 4.95 3 4.92 2.85 -60 -40C 25C 125C 150C 5.07 Vcc Voltage (V) VIN UVLO Voltage (V) 3.75 4.89 -30 0 30 60 90 Temperature (C) 120 Figure 8-5. VIN UVLO Threshold 150 180 D005 0 4 8 12 16 20 24 Input Voltage (V) 28 32 36 40 D005 Figure 8-6. VCC vs Input Voltage Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 15 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 8.8 Typical Characteristics (continued) Unless otherwise specified the following conditions apply: VIN = 13.5 V, fSW = 400 kHz, L = 10 µH, COUT_CSP = 66 µF, COUT_CSN = 0.1 µF, CBUS = 1 µF, TA = 25 °C. 6.2 5.16 VCSN/OUT Voltage (V) 5.14 High-side MOS Current Limit (A) Vin = 6V Vin = 13.5V Vin = 36V 5.12 5.1 5.08 5.06 5.04 -50 -25 0 25 50 75 Temperature (C) 100 125 -40C 25C 150C 6 5.8 5.6 5.4 5.2 5 4.8 150 0 4 8 12 D006 RIMON = 0 Ω 16 20 24 Input Voltage (V) 28 32 36 40 D006 Figure 8-8. High-side Current Limit vs Input Voltage 80 60 72 55 64 50 On Resistance (m?) On Resistance (m?) Figure 8-7. VCSN/OUT Voltage vs Junction Temperature 56 48 40 Vin = 6V Vin = 13.5V Vin = 36V 32 24 -50 -25 0 25 50 75 Temperature (C) 100 125 35 -25 0 D008 2400 414 2100 408 402 396 390 384 25 50 75 Temperature (C) 100 125 150 D009 Figure 8-10. Low-side MOSFET on Resistance vs Junction Temperature 420 378 -50 Vin = 6V Vin = 13.5V Vin = 36V 25 -50 150 Switching Frequency (kHz) Switching Frequency (kHz) 40 30 Figure 8-9. High-side MOSFET on Resistance vs Junction Temperature 1A 2A 3A 1800 1500 1200 900 600 300 -25 0 25 50 75 Temperature (C) 100 125 150 0 5 10 D010 RT = 49.9 kΩ 15 20 25 Input voltage (V) 30 35 40 D011 RT = 8.87 kΩ Figure 8-11. Switching Frequency vs Junction Temperature 16 45 Figure 8-12. Switching Frequency vs VIN Voltage Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 8.8 Typical Characteristics (continued) Unless otherwise specified the following conditions apply: VIN = 13.5 V, fSW = 400 kHz, L = 10 µH, COUT_CSP = 66 µF, COUT_CSN = 0.1 µF, CBUS = 1 µF, TA = 25 °C. 4.2 4.2 Rlimit = 13k: Rlimit = 26.1k: 3 2.4 1.8 1.2 0.6 -25 0 RSNS = 15 mΩ 25 50 75 Temperature (C) 100 125 2.4 1.8 1.2 0 -50 150 -25 0 25 50 75 Temperature (C) D012 RSET = 300 Ω RSNS = 15 mΩ Figure 8-13. Buck Average Current Limit vs Junction Temperature 100 125 150 D013 RSET = 300 Ω Figure 8-14. External FET Current Limit vs Junction Temperature 4.8 13 Vin = 6V Vin = 13.5V Vin = 36V 4.4 Vin = 6V Vin = 13.5V Vin = 36V 12.5 LS_GD Gate Voltage (V) LS_GD Gate Source Current (uA) 3 0.6 0 -50 4 3.6 3.2 2.8 12 11.5 11 10.5 10 2.4 2 -50 -25 0 25 50 75 Temperature (C) 100 125 9.5 -50 150 -25 0 25 50 75 Temperature (C) 100 125 VCSN/OUT = 5.1 V 150 D013 D013 Figure 8-15. LS_GD Gate Source Current vs Junction Temperature RIMON = 0 kΩ Figure 8-16. LS_GD Gate Voltage vs Junction Temperature 1.35 1 Load Current = 3 A Load Current = 1.5 A 0.9 Cable Comp Voltage (V) 1.2 Cable Comp Voltage (V) Rlimit = 6.8k: Rlimit = 13.7k: 3.6 Ext FET Current Limit (A) Buck Avg Current limit (A) 3.6 1.05 0.9 0.75 0.6 0.45 0.8 0.7 0.6 0.5 0.4 0.3 0.2 0.1 0.3 -50 0 -25 0 RSNS = 15 mΩ 25 50 75 Temperature (C) RSET = 300 Ω 100 125 150 0 0.3 0.6 0.9 D014 RIMON = 13 kΩ Figure 8-17. Cable Compensation Voltage vs Junction Temperature RSNS = 15 mΩ 1.2 1.5 1.8 Load Current (A) 2.1 RSET = 300 Ω 2.4 2.7 3 D014 RIMON = 13 kΩ Figure 8-18. Cable Compensation Voltage vs Load Current Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 17 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 8.8 Typical Characteristics (continued) 450 7.5 420 7.35 VBUS OVP Threshold (V) Vbus Discharge Resistance (ohm) Unless otherwise specified the following conditions apply: VIN = 13.5 V, fSW = 400 kHz, L = 10 µH, COUT_CSP = 66 µF, COUT_CSN = 0.1 µF, CBUS = 1 µF, TA = 25 °C. 390 360 330 300 7.05 6.9 6.75 270 240 -50 6.6 -25 0 25 50 75 Temperature (C) 100 125 6.45 -50 150 4.2 4.2 DM_IN OVP Threshold (V) 4.3 4.1 4 3.9 3.8 3.7 -25 0 25 50 75 Temperature (C) 100 125 125 150 D016 4 3.9 3.8 700 800 600 720 640 560 480 400 0 25 50 75 Temperature (C) 0 100 125 150 25 50 75 Temperature (C) 100 125 150 D018 Figure 8-22. DM_IN Overvoltage Protection Threshold vs Junction Temperature 880 -25 -25 D017 Vconn Switch Limit Current (mA) Vconn Switch On Resistance (mohm) 100 4.1 3.6 -50 150 500 400 300 200 100 0 -50 -25 0 D019 VCONN = 5 V 25 50 75 Temperature (C) 100 125 150 D020 VCONN = 5 V Figure 8-23. VCONN Current Limiting Switch On Resistance vs Junction Temperature 18 25 50 75 Temperature (C) 3.7 Figure 8-21. DP_IN Overvoltage Protection Threshold vs Junction Temperature 320 -50 0 Figure 8-20. VBUS Overvoltage Protection Threshold vs Junction Temperature 4.3 3.6 -50 -25 D015 Figure 8-19. VBUS Discharge Resistance vs Junction Temperature DP_IN OVP Threshold (V) 7.2 Figure 8-24. VCONN Switch Current Limit vs Junction Temperature Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 8.8 Typical Characteristics (continued) Unless otherwise specified the following conditions apply: VIN = 13.5 V, fSW = 400 kHz, L = 10 µH, COUT_CSP = 66 µF, COUT_CSN = 0.1 µF, CBUS = 1 µF, TA = 25 °C. 400 6.8 Sourcing Current (uA) 360 CC1 OVP Threshold Voltage (V) UFP 1.5A UFP 3A 320 280 240 200 160 120 -50 -25 0 25 50 75 Temperature (C) 100 125 6.2 6 5.8 5.6 -25 0 25 50 75 Temperature (C) D021 100 125 150 D022 Figure 8-26. CC1 Overvoltage Protection Threshold vs Junction Temperature 0.54 0.705 NTC Temp Shutdown Threshold (%) NTC Temp Warning Threshold (%) 6.4 5.4 -50 150 Figure 8-25. CC Sourcing Current vs Junction Temperature 0.53 0.52 0.51 0.5 0.49 0.48 0.47 -50 6.6 -25 0 25 50 75 Temperature (C) 100 125 150 D025 Figure 8-27. NTC Temperature Warning Threshold (TPS25833Q1) 0.69 0.675 0.66 0.645 0.63 0.615 0.6 -50 -25 0 25 50 75 Temperature (C) 100 125 150 D025 Figure 8-28. NTC Temperature Shutdown Threshold (TPS25833Q1) Measured on TPS25830-Q1 EVM with 10-cm cable Measured Source with 10-cm cable Figure 8-29. Bypassing The TPS25832-Q1 Data Switch Figure 8-30. Through the TPS25832-Q1 Data Switch Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 19 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 8.8 Typical Characteristics (continued) Unless otherwise specified the following conditions apply: VIN = 13.5 V, fSW = 400 kHz, L = 10 µH, COUT_CSP = 66 µF, COUT_CSN = 0.1 µF, CBUS = 1 µF, TA = 25 °C. Figure 8-31. Data Transmission Characteristics vs Frequency (TPS25832-Q1) Figure 8-32. Off-State Data-Switch Isolation vs Frequency (TPS25832-Q1) Figure 8-33. On-State Cross-Channel Isolation vs Frequency (TPS25832-Q1) 20 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 9 Parameter Measurement Information OUT R(L) C(L) V(OUT) tr 90% tf 10% Figure 9-1. VCONN Switch Rise-Fall Test Load Figure Figure 9-2. VCONN Switch Rise-Fall Timing IOS 90% tr tf VLS_GD I(OUT) 10% t(IO S) Figure 9-4. NFET Gate Drive Rise and Fall Time Figure 9-3. Short-Circuit Parameters Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 21 TPS25832-Q1, TPS25833-Q1 SLVSEH7D – JULY 2019 – REVISED MARCH 2022 www.ti.com 10 Detailed Description 10.1 Overview The TPS25832-Q1 and TPS25833-Q1 are full-featured solutions for implementing a compact USB charging port with support for both Type-C and BC1.2 standards. Both devices contain an efficient 36-V buck regulator power source capable of providing up to 3.5 A of output current at 5.10 V (nominal). System designers can optimize efficiency or solution size through careful selection of switching frequency over the range of 300–2200 kHz with sufficient margin to operate above or below the AM radio frequency band. In devices, the buck regulator operates in forced PWM mode ensuring fixed switching frequency regardless of load current. Spread-spectrum frequency dithering reduces harmonic peaks of the switching frequency potentially simplifying EMI filter design and easing compliance. Current sensing through a precision high-side current sense amplifier enables an accurate, user programmable over-current limit setting; and programmable linear cable compensation to overcome IR losses when powering remote USB ports. The TPS25832-Q1 integrates high band-width (800 MHz) USB switches and includes short-to-VBUS protection as well as IEC61000-4-2 electrostatic discharge clamps to protect the host from potentially damaging overvoltage conditions. The CTRL1 and CTRL2 pins set the operating mode for the TPS25832-Q1 implementing Type-C, CDP and SDP USB port configurations. TPS25833-Q1 includes an NTC input and THERM_WARN flag for user programmable thermal protection using a negative temperature coefficient resistor. The CTRL1 and CTRL2 pins set the operating mode for the TPS25833-Q1 implementing Type-C, DCP, CDP and SDP USB ports. 22 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 10.2 Functional Block Diagram R SNS R SET BOOT (32) (14) CSN /OUT (13) (11) (1,2,3) (21) INT. REG. BIAS LS C urren t Sen se HS C urren t Sen se 1V + VCC (25, 26, 27) ± IN CSP PGND SW (28, 29, 30, 31) IMON Outpu t Vol ta ge R egu la ti on, Ca bl e Comp en sation a nd Cu rren t Li mit R IMON (12) Dri ver ILIMIT R ILIMIT RT/ SYNC (9) OSC&PLL OV Co ntrol L ogi c PWM Co mpa rator Slo pe C omp + + ± EN/ UVL O Optional Softstart VRE F (4) Ena bl e Log ic CTRL1 (5) CTRL 2 (6) AGND (16) Co mpe nsatio n Ne tw ork Shu tdow n Ch arg e Pump an d Gate Driv ers /LD_DET (10) LS_GD (15) BUS BUS C ontrol (23) Co ntrol a nd Faul t L ogi c / POL / FAUL T (22) Faul t con di ti ons /THER M_WARN VCC CC a nd VCON N Co ntrol (20) CC1 (19) CC2 (24) CD P, DC P, Di vid er 3, 1.2V / THER M_ WARN (TPS25 83 3) (7) DP_ OUT ( TPS25 83 2) (7) DM_ OUT ( TPS25 83 2) (8) NTC ( TPS25 83 3) (8) (18) DP_IN (17) DM_IN VCC Ther mal Man ag emen t THER M_WARN THER M_WARN NOTE: x TPS25832: includes DP and DM HS USB Switches x TPS25833: includes NTC inpu t, / THERM_ WARN flag 10.3 Feature Description 10.3.1 Buck Regulator The following operating description of the TPS2583x-Q1 will refer to the and the waveforms in Figure 10-1. TPS2583x-Q1 is a step-down synchronous buck regulator with integrated high-side (HS) and low-side (LS) switches (synchronous rectifier). The TPS2583x-Q1 supplies a regulated output voltage by turning on the HS and LS NMOS switches with controlled duty cycle. During high-side switch ON time, the SW pin voltage swings up to approximately VIN, and the inductor current iL increase with linear slope (VIN – VOUT) / L. When the HS switch is turned off by the control logic, the LS switch is turned on after an anti-shoot-through dead time. Inductor current discharges through the LS switch with a slope of –VOUT / L. The control parameter of a buck converter is defined as Duty Cycle D = tON / TSW, where tON is the high-side switch ON time and TSW is the switching period. The regulator control loop maintains a constant output voltage by adjusting the duty cycle D. In an ideal buck converter, where losses are ignored, D is proportional to the output voltage and inversely proportional to the input voltage: D = VOUT / VIN. Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 23 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 VSW SW Voltage D = tON/ TSW VIN tON tOFF t 0 -VD Inductor Current iL TSW ILPK IOUT 'iL t 0 Figure 10-1. SW Node and Inductor Current Waveforms in Continuous Conduction Mode (CCM) The TPS2583x-Q1 employs fixed frequency peak current mode control. A voltage feedback loop is used to get accurate DC voltage regulation by adjusting the peak current command based on voltage offset. The peak inductor current is sensed from the high-side switch and compared to the peak current threshold to control the ON time of the high-side switch. The voltage feedback loop is internally compensated, which allows for fewer external components, makes it easy to design, and provides stable operation with a reasonable combination of output capacitors. TPS2583x-Q1 operates in FPWM mode for low output voltage ripple, tight output voltage regulation, and constant switching frequency. 10.3.2 Enable/UVLO and Start-up The voltage on the EN/UVLO pin controls the ON or OFF operation of TPS2583x-Q1. An EN/UVLO pin voltage higher than VEN/UVLO-VOUT-H is required to start the internal regulator and begin monitoring the CCn lines for a valid Type-C connection. The internal USB monitoring circuitry is on when VIN is within the operation range and the EN/UVLO threshold is cleared; however, the buck regulator does not begin operation until a valid USB Type-C detection has been made. This feature ensures the "cold socket" (0 V) USB Type-C VBUS requirement is met. The EN/UVLO pin is an input and can not be left open or floating. The simplest way to enable the operation of the TPS2583x-Q1 is to connect the EN to VIN. This allows self-start-up of the TPS2583x-Q1 when VIN is within the operation range. 24 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 EN VEN/UVLO-H VEN/UVLO-H ± VEN/UVLO-HYS VEN-VCC-H VEN-VCC-L VCC 5V 0 VCSN/OUT VCSN/OUT 0 Figure 10-2. Precision Enable Behavior Many applications will benefit from the employment of an enable divider RENT and RENB (Figure 10-3) to establish a precision system UVLO level for the TPS2583x-Q1. The system UVLO can be used for sequencing, ensuring reliable operation, or supply protection, such as a battery discharge level. To ensure the USB port VBUS is within the 5-V operating range as required for USB compliance (for the latest USB specifications and requirements, refer to USB.org), TI suggests that the RENT and RENB resistors be chosen such that the TPS2583x-Q1 enables when VIN is approximately 6 V. Considering the drop out voltage of the buck regulator and IR loses in the system, 6 V provides adequate margin to maintain VBUS within USB specifications. If system requirements such as a warm crank (start) automotive scenario require operation with VIN < 6 V, the values of RENT and RENB can be calculated assuming a lower VIN. An external logic signal can also be used to drive EN/UVLO input when a microcontroller is present and it is desirable to enable or disable the USB port remotely for other reasons. IN RENT EN RENB Figure 10-3. System UVLO by Enable Divider UVLO configuration using external resistors is governed by the following equations: Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 25 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 (1) (2) Example: VIN(ON) = 6 V (user choice) RENB = 5 kΩ (user choice) RENT = [(VIN(ON) / VEN/UVLO_H) – 1] × RENB= 19.6 kΩ. Choose standard 20 kΩ. Therefore VIN(OFF) = 6 V × [1 - (0.09 V / 1.2 V)] = 5.55 V A typical start-up waveform is shown in Figure 10-4, indicating typical timings when Rd connected to CC line. The rise time of DCDC VBUS voltage is about 5 ms. EN, 5V/Div VIN 5V/Div VBUS, 5V/Div VCC, 5V/Div 40ms/Div Figure 10-4. Typical Start-up Behavior, VIN = 13.5 V, CC1 = Rd, RIMON = 12.6 kΩ For TPS25832-Q1, the pin voltage must meet the requirement below during 150-ms (typ) Rd assert deglitch time, see Figure 10-5: • VBUS < 0.8 V (typical), per Type-C requirement • VDx_OUT < 2.2 V (typical) • VDx_IN < 1.5 V (typical) After the TPS25832-Q1 Rd assert deglitch time, no additional requirement on these pins. In real application, LD_DET pin can be used to configure the timing sequence. 26 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 VIN/EN Rd assert here CC1/CC2 Dx_OUT VBUS Must < 2.2V }v[š Œ VBUS must < 0.8V deglitch time 150ms (typ) DP/DM Date Switch ON OFF LD_DET Figure 10-5. TPS25832-Q1 Pin Voltage Requirement During Rd Assert 10.3.3 RT/SYNC The switching frequency of the TPS2583x-Q1 can be programmed by the resistor RT from the RT/SYNC pin and GND pin. To determine the RT resistance, for a given switching frequency, use the equation below Equation 3: 26660 u ¦SW 1.0483 FREQ Resistance (k:) RFREQ k: 70 65 60 55 50 45 40 35 30 25 20 15 10 5 200 kHz 400 (3) 600 800 1000 1200 1400 1600 1800 2000 2200 Switching Frequency (kHz) D024 Figure 10-6. RT Set Resistor vs Switching Frequency Table 10-1 lists typical RT resistors value. Table 10-1. Setting the Switching Frequency with RT RT (kΩ) SWITCHING FREQUENCY (kHz) 68.1 300 49.9 400 39.2 500 19.1 1000 12.4 1500 9.31 2000 8.87 2100 8.45 2200 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 27 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 TPS2583x-Q1 switching action can be synchronized to an external clock from 300 kHz to 2.3 MHz. The RT/ SYNC pin can be used to synchronize the internal oscillator to an external clock. The internal oscillator can be synchronized by AC coupling a positive edge into the RT/SYNC pin. The AC coupled peak-to-peak voltage at the RT/SYNC pin must exceed the SYNC amplitude threshold of 3.5 V (typical) to trip the internal synchronization pulse detector, and the minimum SYNC clock ON and OFF time must be longer than 100 ns (typical). When using a low impedance signal source, the frequency setting resistor RT is connected in parallel with an AC coupling capacitor CCOUP to a termination resistor RTERM (for example: 50 Ω). The two resistors in series provide the default frequency setting resistance when the signal source is turned off. A 10-pF ceramic capacitor can be used for CCOUP. Figure 10-7 show the device synchronized to an external clock. CCOUP RT PLL Lo-Z Clock Source RTERM PLL Hi-Z Clock Source RT/SYNC RT RT/SYNC Figure 10-7. Synchronize to External Clock In order to avoid AM radio frequency brand and maintain proper regulation when minimum ON-time or minimum OFF-time is reached, the TPS2583x-Q1 implement frequency foldback scheme depends on VIN voltage, refer to Figure 8-11. • When 8 V < VIN ≤ 19V, the switching frequency of TPS2583x-Q1 is determined by RT resistor or external sync clock. • When VIN ≤ 8 V, the switching frequency of TPS2583x-Q1 is set to default 420 kHz, regardless of RT resistor setting or external sync clock. • When VIN > 19 V, the switching frequency of TPS2583x-Q1 is set to default 420 kHz, regardless of RT resistor setting or external sync clock Figure 10-8, Figure 10-9 and figure 10-10 show the device switching frequency and behavior under different VIN voltage and RT = 8.87 kΩ. Figure 10-11, Figure 10-12 and Figure 10-13 show the device switching frequency and behavior under different VIN voltage and synchronized to an external 2.1-M system clock. VIN, 10V/Div VIN, 10V/Div SW, 10V/Div SW, 10V/Div Inductor Current, 5A/Div VIN = 7.5 V 1us/Div L = 2.2 uH ILOAD = 3 A Figure 10-8. Switching Frequency when RT = 8.87 kΩ 28 Inductor Current, 5A/Div VIN = 13.5 V 1us/Div L = 2.2 uH ILOAD = 3 A Figure 10-9. Switching Frequency when RT = 8.87 kΩ Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 VIN, 5V/Div VIN, 10V/Div SW, 10V/Div Sync, 2V/Div SW, 5V/Div Inductor Current, 5A/Div VIN = 20 V 1us/Div L = 2.2 uH ILOAD = 3 A Figure 10-10. Switching Frequency when RT = 8.87 kΩ Inductor Current, 2A/Div VIN = 7.5 V 1us/Div L = 2.2 uH ILOAD = 3 A Figure 10-11. Synchronizing to External 2.1-MHz Clock VIN, 10V/Div VIN, 5V/Div Sync, 2V/Div Sync, 2V/Div SW, 10V/Div SW, 10V/Div Inductor Current, 2A/Div VIN = 13.5 V 1us/Div L = 2.2 uH ILOAD = 3 A Figure 10-12. Synchronizing to External 2.1-MHz Clock Inductor Current, 2A/Div VIN = 20 V 1us/Div L = 2.2 uH ILOAD = 3 A Figure 10-13. Synchronizing to External 2.1-MHz Clock 10.3.4 Spread-Spectrum Operation In order to reduce EMI, The TPS2583x-Q1 introduce frequency spread spectrum. The spread spectrum is used to eliminate peak emissions at specific frequencies by spreading emissions across a wider range of frequencies than a part with fixed frequency operation. In most systems, low frequency conducted emissions from the first few harmonics of the switching frequency can be easily filtered. A more difficult design criterion is reduction of emissions at higher harmonics which fall in the FM band. These harmonics often couple to the environment through electric fields around the switch node. The TPS2583x-Q1 devices use ±6% spread of switching frequencies with 1/256 swing frequency. The spread spectrum function is only available when using the TPS2583x-Q1 internal oscillator. If the RT/SYNC pin is synchronized to an external clock, the spread spectrum function will be turn off. 10.3.5 VCC, VCC_UVLO The TPS2583x-Q1 integrates an internal LDO to generate VCC for control circuitry and MOSFET drivers. The nominal voltage for VCC is 5 V. The VCC pin is the output of an LDO and must be properly bypassed. A high quality ceramic capacitor with a value of 2.2 µF to 4.7 µF, 10 V or higher rated voltage should be placed as close as possible to VCC and grounded to the PGND ground pin. The VCC output pin should not be loaded with more than 5 mA, or shorted to ground during operation. Shorting VCC to ground during operation may cause damage to the TPS2583x-Q1. Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 29 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 In applications where VCONN support is required, the VCC pin can be over-driven with an external 5-V LDO capable of sourcing at least 300 mA. In this operating mode the external LDO is the source for the buck low-side switch gate drive as well as power to the internal VCONN mux. Note if using external 5-V LDO for VCONN power, the timing sequence below must be required. External VCONN power can not be enabled before the TPS2583x-Q1 is enabled, external VCONN must be disabled before the TPS2583x-Q1 is disabled. In real application, customer can tie the EN of external 5-V LDO and EN of TPS2583x-Q1 together to meet the timing requirement. Figure 10-14. VCONN Source Using External LDO 10.3.6 Minimum ON-time, Minimum OFF-time Minimum ON-time, TON_MIN, is the smallest duration of time that the HS switch can be on. TON_MIN is typically 105 ns in the TPS2583x-Q1. Minimum OFF-time, TOFF_MIN, is the smallest duration that the HS switch can be off. TOFF_MIN is typically 80 ns in the TPS2583x-Q1. In CCM (FPWM) operation, TON_MIN and TOFF_MIN limit the voltage conversion range given a selected switching frequency. The minimum duty cycle allowed is: (4) And the maximum duty cycle allowed is: (5) Given fixed TON_MIN and TOFF_MIN, the higher the switching frequency the narrower the range of the allowed duty cycle. 10.3.7 Internal Compensation The TPS2583x-Q1 is internally compensated as shown in Functional Block Diagram. The internal compensation is designed such that the loop response is stable over the specified operating frequency and output voltage range. The TPS2583x-Q1 is optimized for transient response over the range 300 kHz ≤ fsw ≤ 2300 kHz. 10.3.8 Bootstrap Voltage (BOOT) The TPS2583x-Q1 provides an integrated bootstrap voltage regulator. A small capacitor between the BOOT and SW pins provides the gate drive voltage for the high-side MOSFET. The BOOT capacitor is refreshed when the high-side MOSFET is off and the low-side switch conducts. The recommended value of the BOOT capacitor is 0.1 μF. A ceramic capacitor with an X7R or X5R grade dielectric with a voltage rating of 10 V or higher is recommended for stable performance over temperature and voltage. 10.3.9 RSNS, RSET, RILIMIT, and RIMON The programmable current limit threshold and full-scale cable compensation voltage are determined by the values of the RSNS, RSET, RILIMIT, and RIMON resistors. Refer to Figure 10-15. 30 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 TPS25832-Q1, TPS25833-Q1 www.ti.com • • • • SLVSEH7D – JULY 2019 – REVISED MARCH 2022 RSNS is the current sense resistor. The recommended voltage across RSNS under current limit should be approximately 50 mV as a compromise between accuracy and power dissipation. For example, if current limiting is desired for IOUT(MAX) ≥ 3.3 A, then RSNS = 0.05 V / 3.3 A = 0.01515 Ω. Choose a standard value of 15 mΩ. RSET determines the input current to the transconductance amplifier and current mirror. The amplifier balances the voltage to be equal to that across RSNS. Choose a RSET value to produce an ISET current between 75 - 180 µA at the desired IOUT(MAX). Considering 50 mV across RSET, a value of 300 Ω will provide approximately 166 µA of ISET current to the amplifier and mirror circuit. Care should be taken to limit the ISET current below 200 µA to avoid saturating the internal amplifier circuit. RILIMIT in conjuction with the 0.5 × ISET current produces a voltage on the ILIMIT pin which is proportional to the load current flowing in RSNS. See Current Limit Sensing using RILIMIT for details on setting the current limit. RIMON in conjuction with the 0.5 ISET current produces a voltage on the IMON pin which is proportional to the load current flowing in RSNS. See Cable Compensation for details on setting the current limit. (1): VSNS = ILOAD x RSNS (2): VSNS ~= VSET (by op amp) (3): ISET = VSET / RSET = VSNS / RSET ILOAD RSNS + 50mV - RSET CSP CSN/OUT RT Low Offset Amp RM RB + IMON ± IIMON = 0.5 x ISET ISET + RIMON ± RS = RT ILIMIT IILIMIT = 0.5 x ISET RILIMIT ± + 1V Soft Start + + ± VCOMP 1V VILIMIT = 1V (current limit by Buck) VILIMIT = 0.49V (current limit by NFET) LS_GD ± + 0.49V BUS Figure 10-15. Current Limit and Cable Compensation Circuit 10.3.10 Overcurrent and Short Circuit Protection For maximum versatility, TPS2583x-Q1 includes both a precision, programmable current limit as well cycle-bycycle current limit to protect the USB port from extreme overload conditions. In most applications the RILIMIT resistor in conjunction with the selection of RSNS and RSET will determine the overload threshold. The cycle-bycycle current limit will serve as a backup means of protection in the event RILMITis shorted to ground disabling the programmable current limit function. In some application, the setting of TPS2583x-Q1 over-current need meet MFi requirement, please refer to the How to Pass MFi Overcurrent Protection Test With USB Charger and Switch Device application report for more details. 10.3.10.1 Current Limit Setting using RILIMIT Refer to Figure 10-15. The TPS2583x-Q1 can establish current limit by two methods. • Using external a single or back-to-back N-Channel MOFETs between CSN/OUT and BUS: A voltage of 0.49 V on the ILIMIT pin initiates current limiting using the external MOSFET by decreasing the LS_GD voltage Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 31 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 • causing the FET to operate in the saturation region. To protect the MOSFETs from damage a hiccup timer limits the duty cycle to prevent thermal runaway. Refer to the Switching Characteristics for MOSFET hiccup timing. Buck average current limit: No MOSFET, CSN/OUT connected to BUS. For TPS25833-Q1, the LS_GD pin can be left floating. For TPS25832-Q1, the LS_GD pin must be pulled up through a 2.2-kΩ resistor. In this configuration a voltage of 1 V across RILIMIT on the ILIMIT pin initiates average current limiting of the buck regulator. The two level current limit is described below: • With external MOSFET Figure 10-16, Figure 10-17: – Isolating a fault on the USB port from other loads connected to the CSP output of the TPS2583x-Q1. In some applications, it may be useful to power additional circuitry (example USB HUB) from the output of the TPS2583x-Q1 and maintain operation of these circuits in the event of a short circuit downstream of the BUS pin. To prevent triggering the MOSFET current limit below the programmed ILIMIT threshold, external circuits should be supplied after the inductor and before the current sense resistor, RSNS. – After RSNS and RSET are determined and the full load ISET current is known, the resistor value RILIMIT can be determined by: (6) – In most case, the recommended voltage across RSNS under current limit should be approximately 50 mV as a compromise between accuracy and power dissipation. While in some application, RILIMIT is the only resistor that can be changed to achieve different current limit. Typical RILIMIT resistors value are listed in Table 10-2 given the condition RSNS= 15 mΩ and RSET= 300 Ω Table 10-2. Setting the Current Limit with RILIMIT Current-Limit Threshold (mA) • RILIMIT (kΩ) With External MOSFET Buck Average 700 26.1 53.6 1500 12.7 26.1 1700 11.3 22.6 2700 7.15 14.7 3000 6.49 13 3400 5.62 11.5 3800 5.11 10.5 Buck Average Current Limit Figure 10-18, Figure 10-19: 1. CSN/OUT connected directly to BUS. For TPS25833-Q1, LS_GD pin can be floating. For TPS25832-Q1, LS_GD pin must be pulled up through 2.2-kΩ resistor. The TPS2583x-Q1 can operate as a stand-alone USB charging port. In this configuration, the internal buck regulator operates with average current limiting as programmed by the ILIMIT pin, potentially producing less heat compared to N-channel MOSFET current limiting 2. After RSNS and RSET are determined and the full load ISET current is known, the resistor value RILIMIT can be determined by: (7) 3. Typical RILIMIT resistors value are listed in Table 10-2 given the condition RSNS = 15 mΩ and RSET = 300 Ω 32 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 CBOOT VIN BOOT IN CBOOT To auxiliary loads VIN L RSNS BOOT IN SW L RSNS SW RSET EN/UVLO To auxiliary loads RSET EN/UVLO CSP RT/SYNC CSP RT/SYNC CSN/OUT CSN/OUT VCC VCC TPS25832-Q1 TPS25833-Q1 LS_GD FAULT LS_GD FAULT LD_DET LD_DET CC1 CTRL2 CC2 DP_OUT DP_IN DM_OUT DM_IN IMON ILIMIT POL BUS CTRL1 CC1 CTRL2 CC2 DP_IN /THERM_WARN DM_IN NTC AGND PGND IMON Figure 10-16. TPS25832-Q1 Current Limit with External MOSFET ILIMIT AGND PGND Figure 10-17. TPS25833-Q1 Current Limit with External MOSFET CBOOT CBOOT VIN BOOT IN VIN L RSNS BOOT IN SW EN/UVLO L RSNS SW RSET EN/UVLO RSET CSP RT/SYNC Type-C Connector BUS Type-C Connector POL CTRL1 CSP RT/SYNC CSN/OUT CSN/OUT VCC VCC TPS25832-Q1 FAULT TPS25833-Q1 2.2kohm LS_GD FAULT LS_GD BUS CC1 CTRL2 CC2 DP_OUT DP_IN DM_OUT DM_IN IMON ILIMIT POL Type-C Connector POL CTRL1 AGND PGND BUS CTRL1 CC1 CTRL2 CC2 /THERM_WARN DP_IN NTC DM_IN IMON Figure 10-18. TPS25832-Q1 Buck Average Current Limit ILIMIT Type-C Connector LD_DET LD_DET AGND PGND Figure 10-19. TPS25833-Q1 Buck Average Current Limit 10.3.10.2 Buck Average Current Limit Design Example To start the procedure, the ILOAD(MAX), RSNS, RSET, must to be known. 1. Determine ILIMIT, usually chose ILIMIT= ILOAD(MAX) / (1 – 10%). 2. Determine RSNS to achieve 50 mV at current limit. For 3-A Type-C load current, choose ILIMIT = 3.3A. RSNS = (0.05 V / 3.3 A) = 15 mΩ. 3. Choose RSET = 300 Ω 4. According to Equation 7, RLIMIT = 300 / (0.5 × ( 3.3 × 0.015 + 0.0007)) = 11.95 kΩ. 5. Choose standard 11.8 kΩ. 10.3.10.3 External MOSFET Gate Drivers The TPS2583x-Q1 has integrated NFET gate drivers, and can support current limit with external NFET. Refer to Figure 10-16. The LS_GD pin of TPS2583x-Q1 can source 3 uA (typical) current to enhance the external MOSFET. A 6.2-V clamp between LS_GD and CSN/OUT pin limits the gate-to-source voltage. During DCDC start up, the LS_GD gate drivers begin to source current after VCSN/OUT reach 3 V. If the VCSN/OUT > 7.5 V or VBUS > 7 V under overvoltage condition, the LS_GD will turn off immediately with 35 uA (typical) sink current. If load current above NFET current limit threshold, LS_GD will also turn off the NFET after 2 ms (Typical) and enter hiccup mode to protect NFET from thermal issue. Refer to Figure 11-26 for application waveform. Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 33 TPS25832-Q1, TPS25833-Q1 SLVSEH7D – JULY 2019 – REVISED MARCH 2022 www.ti.com 10.3.10.4 Cycle-by-Cycle Buck Current Limit The buck regulator cycle-by-cycle current limit on both the peak and valley of the inductor current. Hiccup mode will be activated if a fault condition persists to prevent over-heating. High-side MOSFET overcurrent protection is implemented by the nature of the Peak Current Mode control. The HS switch current is sensed when the HS is turned on after a set blanking time. The HS switch current is compared to the output of the Error Amplifier (EA) minus slope compensation every switching cycle. Refer to the Functional Block Diagram for more details. The peak current of HS switch is limited by a clamped maximum peak current threshold IHS_LIMIT which is constant. So the peak current limit of the high-side switch is not affected by the slope compensation and remains constant over the full duty cycle range. The current going through LS MOSFET is also sensed and monitored. When the LS switch turns on, the inductor current begins to ramp down. The LS switch will not be turned OFF at the end of a switching cycle if its current is above the LS current limit ILS_LIMIT. The LS switch will be kept ON so that inductor current keeps ramping down, until the inductor current ramps below the LS current limit ILS_LIMIT. Then the LS switch will be turned OFF and the HS switch will be turned on after a dead time. This is somewhat different than the more typical peak current limit, and results in Equation 8 for the maximum load current. (8) If VCSN/OUT < 2-V typical due to a short circuit for 128 consecutive cycles, hiccup current protection mode will be activated. In hiccup mode, the regulator will be shut down and kept off for 118 ms typically, then TPS2583x-Q1 go through a normal re-start with soft start again. If the short-circuit condition remains, hiccup will repeat until the fault condition is removed. Hiccup mode reduces power dissipation under severe overcurrent conditions, prevents over-heating and potential damage to the device and serves as a backup to the programmable current limit see Current Limit Sensing using RILIMIT. Once the output short is removed, the hiccup delay is passed and the output voltage recovers normally as shown in Figure 11-23. 10.3.11 IEC and Overvoltage Protection The TPS2583x-Q1 integrates overvoltage protection on VBUS, CC1, CC2, DM_IN and DP_IN pins. Once overvoltage is detected on these pins, the TPS2583x-Q1 can response accordingly. The TPS2583x-Q1 also integrates IEC ESD cell on CC1, CC2, DP_IN and DM_IN pins. 10.3.11.1 VBUS and VCSN/OUT Overvoltage Protection The TPS2583x-Q1 integrates overvoltage protection on both BUS and CSN/OUT pin, to meet different application requirement. OVP threshold of BUS pin is 7-V typical. Once overvoltage is detected on BUS pin, the LS_GD will turn off immediately, also FAULT asserts after 8-ms deglitch time. Once the excessive voltage is removed, the LS_GD will turn on again and FAULT deasserts. OVP threshold of CSN/OUT pin is 7.5-V typical. Once overvoltage is detected on CSN/OUT pin, the buck converter will stop regulation, also LS_GD will turn off immediately. Once the excessive voltage is removed, the buck converter will resume and LS_GD turn on again. 34 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 CBOOT VIN BOOT IN CBOOT To auxiliary loads L VIN RSNS BOOT L IN SW RSNS RSET EN/UVLO CSP EN/UVLO RT/SYNC RSET CSP RT/SYNC CSN/OUT VCC CSN/OUT VCC TPS25832-Q1 TPS25832-Q1 LS_GD 2.2kŸ LS_GD FAULT 0.22uF LD_DET LD_DET RBUS= 10Ÿ BUS CTRL1 CC1 CC2 CTRL2 DP_OUT DP_IN DM_OUT DM_IN IMON ILIMIT RBUS= 100Ÿ Type-C Connector POL 0.22uF POL BUS CTRL1 CC1 CC2 CTRL2 DP_OUT DP_IN DM_OUT AGND PGND DM_IN IMON Figure 10-20. Current Limit with External MOSFET ILIMIT Type-C Connector FAULT AGND PGND Figure 10-21. Buck Average Current Limit As Figure 10-20, TPS25832-Q1 is configured in external FET current limit mode. When overvoltage occurs on BUS_Connector, the external MOSFET will be turn off immediately after BUS pin detect overvoltage. The FAULT signal will assert after 8-ms deglitch time. A 10-Ω 0805 resistor is recommended between BUS pin and BUS_Connector. As Figure 10-21, TPS25832-Q1 is configured in buck average current limit mode. When overvoltage occurs on BUS_Connector, the buck regulator will stop switching after CSN/OUT pin detect overvoltage. The FAULT signal will also assert after 8-ms deglitch time. A 100-Ω 0805 resistor is recommended between BUS pin and BUS_Connector in buck average current limit mode. 10.3.11.2 DP_IN and DM_IN Protection DP_IN and DM_IN protection consists of IEC ESD and overvoltage protection. The DP_IN and DM_IN pins integrate an IEC ESD cell to provide ESD protection up to ±15-kV air discharge and ±8-kV contact discharge per IEC 61000-4-2 (See the ESD Ratings section for test conditions). The IEC ESD performance of the TPS2583x-Q1 device depends on the capacitance connected from BUS pin to GND. A 0.22-µF capacitor placed close to the BUS pin is recommended. The ESD stress seen at DP_IN and DM_IN is impacted by many external factors like the parasitic resistance and inductance between ESD test points and the DP_IN and DM_IN pins. For air discharge, the temperature and humidity of the environment can cause some difference, so the IEC performance should always be verified in the end-application circuit. Overvoltage protection (OVP) is provided for short-to-VBUS conditions in the vehicle harness, preventing damage to the upstream USB transceiver or hub. When the voltage on DP_IN or DM_IN exceeds 3.9 V (typical), the TPS2583x-Q1 device immediately turn off DP/DM switch, and responds to block the high-voltage reverse connection to DP_OUT and DM_OUT. FAULT signal will assert after 8ms deglitch time. For DP_IN and DM_IN, when overvoltage is triggered, the device turns on an internal discharge path with 416-kΩ resistance to ground. On removal of the overvoltage condition, the pin automatically turns off this discharge path and returns to normal operation by turning on the previously affected analog switch. 10.3.11.3 CC IEC and Overvoltage Protection CCx protection consists of IEC ESD and Overvoltage protection. The CC pins integrate an IEC ESD cell to provide ESD protection up to ±15-kV air discharge and ±8-kV contact discharge per IEC 61000-4-2 (See the ESD Ratings section for test conditions). Additional 0.22-uF capacitor placed close to the CC pin is recommended in real application. Overvoltage protection (OVP) is provided for short-to-VBUS conditions in the vehicle harness. When the voltage on CC1 or CC2 exceeds 6.1 V (typical), the TPS2583x-Q1 device immediately shut off CC line. FAULT signal will assert after 8-ms deglitch time. Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 35 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 For CC1 and CC2, when OVP is triggered, the device turns on an internal discharge path with 55-kΩ resistance to ground. On removal of the overvoltage condition, the pin automatically turns off this discharge path and returns to normal operation. 10.3.12 Cable Compensation When a load draws current through a long or thin wire, there is an IR drop that reduces the voltage delivered to the load. Cable droop compensation linearly increases the voltage at the CSN/OUT pin of TPS2583x-Q1 as load current increases with the objective of maintaining VBUS_CON (the bus voltage at the USB connector) at 5 V, regardless of load conditions. Most portable devices charge at maximum current when 5 V is present at the USB connector. Figure 10-22 provides an example of resistor drops encountered when designing an automotive USB system with a remote USB connector location. Rdson (NFET) R(pcb1_VBUS) R(conn1_VBUS) R(cable_VBUS) R(conn2_VBUS) R(pcb2_VBUS) R(USBconn_VBUS) PCB 1 TPS2583x-Q1 LS_GD BOOT RSNS L SW + RSET + USB Connector R(wire) Automative Connector VBUS TPS25832-Q1 Automative Connector CSP CSN/OUT VBUS_CON BUS ± ± PGND R(pcb1_VBUS) R(conn1_VBUS) R(cable_VBUS) R(conn2_VBUS) R(pcb2_VBUS) R(USBconn_VBUS) R(wire) = R(pcb1_VBUS) + R(conn1_VBUS) + R(cable_VBUS) + R(conn2_VBUS) + R(pcb2_VBUS) + R(USBconn_VBUS) + R(USBconn_GND) + R (pcb2_GND) + R(conn2_GND) + R(cable_GND) + R(conn1_GND) + R(pcb1_GND) Output Voltage (V) Figure 10-22. Automotive USB Resistances 5.x V(DROP) VOUT with compensation VBUS with compensation VBUS without compensation 1 2 3 Output Current (A) Figure 10-23. Voltage Drop 36 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 The TPS2583x-Q1 detects the load current and increases the voltage at the CSN/OUT pin to compensate the IR drop in the charging path according to the gain set by the RSNS, RSET, and RIMON resistors as described in RSNS, RSET, RILIMIT, and RIMON. The amount of cable droop compensation required can be estimated by the following equation ΔVOUT = (RSNS + RDSON_NFET + RWIRE) × IBUS . RIMON is then chosen by RIMON = (ΔVOUT × RSET × 2) / (IBUS × RSNS), Where ΔVOUT is the desired cable droop compensation voltage at full load. Per RSNS, RSET, RILIMIT, and RIMON, in most cases, the recommended voltage across RSNS should be 50 mV. In type-C application, typical RIMON resistors value are listed in Table 10-3 given the condition full load current = 3 A, RSNS = 15 mΩ and RSET = 300 Ω. Table 10-3. Setting the Cable Compensation Voltage with RIMON Cable Compensation Voltage at 3-A Full Load (V) RIMON (kΩ) 0.3 4.02 0.6 8.06 0.9 12.1 1.2 16.2 1.5 20 Note that the maximum cable compensation voltage in TPS2583x-Q1 is 1.5 V. 10.3.12.1 Cable Compensation Design Example To start the procedure, the RSNS, RDSON_NFET and wire resistance RWIRE, must to be known. 1. Determine RSNS to achieve 50 mV at full current. For 3.3 A (3-A Type-C load current plus at approximately 10% for overcurrent threshold). RSNS = (0.05 V / 3.3 A) = 15 mΩ. 2. RDSON_NFET = 50 mΩ 3. RWIRE = 200 mΩ 4. ΔVOUT = (RSNS + RDSON_NFET + RWIRE) × IBUS = (0.015 + 0.05 + 0.2) × 3 = 0.795 V 5. Choose RSET = 300 Ω 6. RIMON = (ΔVOUT × RSET × 2) / (IBUS × RSNS) = (0.795 × 300 × 2) / (3 × 0.015) = 10.6 kΩ 10.3.13 USB Port Control The TPS25832-Q1 and TPS25833-Q1 include DP_IN, DM_IN, CC1 and CC2 pins for automatic or host facilitated USB port power management of either a Type-A or Type-C downstream facing connector. See Device Functional Modes for details on configuring the TPS2583x-Q1. 10.3.14 FAULT Response The device features an active-low, open-drain fault output. Connect a 100-kΩ pullup resistor from FAULT to VCC or other suitable I/O voltage. FAULT can be left open or tied to GND when not used. Table 10-4 summarizes the conditions that generate a fault and actions taken by the device. Table 10-4. Fault and Warning Conditions EVENT Overcurrent on OUT CONDITION ACTION The device regulates current at ISNS either by external NFET or by the buck regulator control loop. When current limiting by external NFET, there is NO fault NFET or Buck average current limit indicator assertion under minor overload conditions. implemented per Current Limit Sensing using When current limiting by buck average current, there is NO RILIMIT. fault indicator assertion under minor overload conditions. ICSN/OUT > programmed ISNS. Hard shorts during average buck current limiting may trigger buck hiccup operation. The FAULT indicator asserts immediately after NOC cycles in and persists for TOC as specified in Cycle-by-Cycle Current Buck Limit. Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 37 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 Table 10-4. Fault and Warning Conditions (continued) EVENT Overvoltage on BUS CONDITION VBUS > VBUS_OV ACTION The device turns on the BUS discharge path in the event of an overvoltage conditions, and turn off the LS_GD immediately. The FAULT indicator asserts and de-asserts with a 8-ms deglitch. Overvoltage on the data lines DP_IN or DM_IN > VDx_IN_OV The device immediately shuts off the USB data switches. The FAULT indicator asserts and de-asserts with a 8-ms deglitch. Overvoltage on CC lines CC1 or CC2 > VCCx_OV The device immediately shuts off the CC lines. The FAULT indicator asserts and de-asserts with a 8-ms deglitch. ILOAD_CCn > IOS_CCn The FAULT indicator asserts and de-asserts with a 8-ms deglitch. The FAULT indicator remains asserted during the VCONN overload condition and the VCONN path is not disabled. Overcurrent on CC lines when supplying VCONN TPS25833-Q1 External overVNTC ≥ VWARN_HIGH temperature detection (NTC) Thermal warning flag THERM_WARN asserts immediately. Also the Type-C advertise current will change to 1.5 A if operating with 3A originally. The FAULT flag is not asserted for this condition, but will assert for conditions stated in this table. TPS25833-Q1 External overVNTC ≥ VSD_HIGH temperature detection (NTC) The device immediately shuts off the buck regulator, opens the USB data switches, while simultaneously pulling LS_GD and BUS low. The THERM_WARN indicator remains asserted. 10.3.15 USB Specification Overview Universal Serial Bus specifications provide critical physical and electrical requirements to electronics manufacturers of USB capable equipment. Adherence to these specifications during product development coupled with standardized compliance testing assures very high degrees of interoperability amongst USB products in the market. Since its inception in the mid 1990s, USB has undergone a number of revisions to enhance utility and extend functionality. For the most up to date standards, please consult the USB Implementers Forum (USB-IF). All USB ports are capable of providing a 5-V output making them a convenient power source for operating and charging portable devices. USB specification documents outline specific power requirements to ensure interoperability. In general, a USB 2.0 port host port is required to provide up to 500 mA; a USB 3.0 or USB 3.1 port is required to provide up to 900 mA; ports adhering to the USB Battery Charging 1.2 Specification provide up to 1500 mA; and newer Type-C ports can provide up to 3000 mA. Even though USB standards governing power requirements exist, some manufacturers of popular portable devices created their own proprietary mechanisms to extend allowed available current beyond the 1500-mA maximum per BC 1.2. While not officially part of the standards maintained by the USB-IF, these proprietary mechanisms are recognized and implemented by manufacturers of USB charging ports. The TPS2583x-Q1 device supports five of the most-common USB-charging schemes found in popular hand-held media and cellular devices. • USB Type-C (1.5-A and 3-A advertisement) • USB Battery Charging Specification BC1.2 • Chinese Telecommunications Industry Standard YD/T 1591-2009 • Divider 3 mode • 1.2-V mode The BC1.2 specification includes three different port types: • Standard downstream port (SDP) • Charging downstream port (CDP) • Dedicated charging port (DCP) BC1.2 defines a charging port as a downstream-facing USB port that provides power for charging portable equipment. Under this definition, CDP and DCP are defined as charging ports. 38 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 Table 10-5 lists the difference between these port types. Table 10-5. USB Operating Modes Table PORT TYPE SUPPORTS USB2.0 COMMUNICATION MAXIMUM ALLOWABLE CURRENT DRAWN BY PORTABLE EQUIPMENT (A) SDP (USB 2.0) YES 0.5 SDP (USB 3.0 and 3.1) YES 0.9 CDP YES 1.5 DCP NO 1.5 TYPE-C YES 3.0 10.3.16 USB Type-C® Basics For a detailed description of the Type-C specifications refer to the USB-IF website to download the latest information. Understanding the basic concepts of the USB Type-C specification will aid in understanding the operation of the TPS2583x-Q1 (a DFP device). USB Type-C removes the need for different plug and receptacle types for host and device functionality. The Type-C receptacle replaces both Type-A and Type-B receptacle since the Type-C cable is plug-able in either direction between host and device. A host-to-device logical relationship is maintained via the configuration channel (CC). Optionally hosts and devices can be either providers or consumers of power when USB Power Delivery (PD) communication is used to swap roles. All USB Type-C ports operate in one of below three data modes: • Host mode: the port can only be host (provider of power) • Device mode: the port can only be device (consumer of power) • Dual-Role mode: the port can be either host or device Port types: • DFP (Downstream Facing Port): Host • UFP (Upstream Facing Port): Device • DRP (Dual-Role Port): Host or Device Valid DFP-to-UFP connections: • Table 10-6 describes valid DFP-to-UFP connections • Host to Host or Device to Device have no functions Table 10-6. DFP-to-UFP Connections HOST-MODE PORT DEVICE-MODE PORT DUAL-ROLE PORT Host-Mode Port No Function Works Works Device-Mode Port Works No Function Works Dual-Role Port Works Works Works(1) (1) This may be automatic or manually driven. 10.3.16.1 Configuration Channel The function of the configuration channel is to detect connections and configure the interface across the USB Type-C cables and connectors. Functionally the Configuration Channel (CC) is used to serve the following purposes: • Detect connect to the USB ports • Resolve cable orientation and twist connections to establish USB data bus routing • Establish DFP and UFP roles between two connected ports • Discover and configure power: USB Type-C current modes or USB Power Delivery • Discovery and configure optional Alternate and Accessory modes • Enhances flexibility and ease of use Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 39 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 Typical flow of DFP to UFP configuration is shown in Figure 10-24: Figure 10-24. Flow of DFP to UFP Configuration 10.3.16.2 Detecting a Connection DFPs and DRPs fulfill the role of detecting a valid connection over USB Type-C. Figure 10-25 shows a DFP to UFP connection made with Type C cable. As shown in Figure 10-25, the detection concept is based on being able to detect terminations in the product which has been attached. A pull-up and pull-down termination model is used. A pull-up termination can be replaced by a current source. TPS2583x-Q1 devices use current sources in lieu of RP as allowed by the Type-C specification. • In the DFP-UFP connection the DFP monitors both CC pins for a voltage lower than the unterminated voltage. • An UFP advertises Rd on both its CC pins (CC1 and CC2). • A powered cable advertises Ra on only one of CC pins of the plug. Ra is used to inform the source to apply VCONN. • An analog audio device advertises Ra on both CC pins of the plug, which identifies it as an analog audio device. VCONN is not applied on either CC pin in this case. UFP monitors for connection DFP monitors for connection Cable CC Rp Rp Ra Rds Ra DFP monitors for connection Rds UFP monitors for connection Figure 10-25. DFP-UFP Connection 40 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 10.3.16.3 Configuration Channel Pins CC1 and CC2 The TPS2583x-Q1 has two pins, CC1 and CC2 that serve to detect an attachment to the port and resolve cable orientation. These pins are also used to establish current broadcast to a valid UFP and configure VCONN. Table 10-7 lists TPS2583x-Q1 response to various attachments to its port. Table 10-7. TPS2583x-Q1 Response TPS2583x-Q1 RESPONSE(1) TPS2583x-Q1 TYPE C PORT CC1 CC2 BUCK REGULATOR LS_GD VCONN On CC1 or CC2(2) POL LD_DET Nothing Attached OPEN OPEN OFF OFF NO Hi-Z Hi-Z UFP Connected Rd OPEN ON ON NO Hi-Z LOW UFP Connected OPEN Rd ON ON NO LOW LOW Powered Cable/No UFP Connected OPEN Ra OFF OFF NO Hi-Z Hi-Z Powered Cable/No UFP Connected Ra OPEN OFF OFF NO Hi-Z Hi-Z Powered Cable/UFP Connected Rd Ra ON ON CC2 Hi-Z LOW Powered Cable/UFP Connected Ra Rd ON ON CC1 LOW LOW Debug Accessory Connected(3) Rd Rd OFF OFF NO Hi-Z Hi-Z Audio Adapter Accessory Connected(3) Ra Ra OFF OFF NO Hi-Z Hi-Z (1) (2) (3) POL and LD_DET are open drain outputs; pull high with 100 kΩ to VCC when used. Tie to GND or leave open when not used. To supply VCONN a 5-V external LDO with at least 500-mA output current should be connected to the VCC pin. The TPS2583x-Q1 don't support debug mode or audio mode. 10.3.16.4 Current Capability Advertisement and VCONN Overload Protection The TPS2583x-Q1 supports all three Type-C current advertisements as defined by the USB Type C standard. Current broadcast to a connected UFP is controlled by the CTRL1 and CTRL2 pins. For each broadcast level the device protects itself from a UFP that draws current in excess of the port’s USB Type-C Current advertisement by setting the current limit as shown in Table 10-8. Table 10-8. USB Type-C Current Advertisement DEVICE '832-Q1 '833-Q1 CC CAPABILITY BROADCAST CTRL2 0 0 RESERVED, DO NOT USE 0 1 RESERVED, DO NOT USE 1 0 1.5 A 3A MODE SUPPORT USB 2.0 COMMUNICATION CTRL1 SDP YES: DP_IN to DP_OUT and DM_IN to DM_OUT CDP YES: DP_IN to DP_OUT and DM_IN to DM_OUT 1 1 0 0 0 1 3A DCP auto NOT SUPPORT 1 0 1.5 A SDP Stub Connection Only 1 1 3A CDP Stub Connection Only CURRENT LIMIT (typ) BY RSNS, RSET, RILIMIT RESERVED, DO NOT USE BY RSNS, RSET, RILIMIT Under overload conditions, a precision current-limit circuit limits the VCONN output current. When a VCONN overload condition is present, the TPS2583x-Q1 maintains a constant output current, with the output voltage determined by (iOS_CCn x RLOAD). VCONN functionality is supported only with an external 5-V supply connected to VCC. Failure to connect an external supply may cause TPS2583x-Q1 Vcc reset. The device turns off when the junction temperature exceeds the thermal shutdown threshold, TSD and remains off until the junction Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 41 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 temperature cools approximately 20°C and then restarts. The TPS2583x-Q1 current limit profile is shown in Figure 10-26. VCC Slope = -rDS-ON VCONN 0V 0A ICCn IOS_CCn Figure 10-26. VCONN Current Limit Profile 10.3.16.5 Plug Polarity Detection Reversible Type-C plug orientation is reported by the POL pin when a UFP is connected. However when no UFP is attached, POL remains de-asserted irrespective of cable plug orientation. Table 10-9 describes the POL state based on which device CC pin detects VRD from an attached UFP pull-down. Table 10-9. Plug Polarity Detection CC1 CC2 POL STATE Rd Open Hi-Z UFP connected Open Rd Asserted (pulled low) UFP connected with reverse plug orientation Figure 10-27 shows an example implementation which uses the POL terminal to control the SEL terminal on the HD3SS3212. The HD3SS3212 provides switching on the differential channels between Port B and Port C to Port A depending on cable orientation. 42 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 LDO USB Host 3.3 V 5.05 ± 6 V (cable compensated) OUT IN GND 12 V BOOT IN RSNS SW RSET CSP EN/UVLO CSN/OUT RT/SYNC LS_GD TPS25832-Q1 VCC BUS /FAULT_IN /EN CC1 FAULT CC2 LD_DET POL A0+ A0A1+ A1GND DP_IN Type-C Connector USB 3.0 MUX OEn SEL VCC PGND ILIMIT IMON DP_OUT AGND DM_OUT CTRL2 CTRL1 DM DP DM_IN B0+ B0C0+ C0B1+ B1C1+ C1- SSRXp2 SSRXn2 SSRXp1 SSRXn1 SSTXp2 SSTXn2 SSTXp1 SSTXn1 Figure 10-27. Example Implementation 10.3.17 Device Power Pins (IN, CSN/OUT, and PGND) The IN pins are the input power path to the TPS25832-Q1, TPS25833-Q1 devices. The internal LDO and buck regulator high side switch are supplied from the IN pins. The CSN/OUT pin connects to the negative terminal of the current sense amplifier and the internal voltage feedback network. This pin must be connected to the output LC filter for proper operation. PGND is the power ground return. For optimum performance, ensure the IN pin is properly bypassed to PGND with adequate bulk and high-frequency bypass capacitance located as close to these pins as possible. 10.3.18 Thermal Shutdown The device has an internal overtemperature shutdown threshold, TSD to protect the device from damage and overall safety of the system. When device temperature exceeds TSD, the LD_GD pin is pulled low, and the buck regulator stops switching. The device attempts to power-up when die temperature decreases by approximately 20°C. 10.3.19 Power Wake Legacy Type-A ports source 5 V on VBUS regardless of a load connection or not. In contrast, Type-C ports are "cold," 0 V, until a UFP connection has been detected via the CC lines. This fundamental change in VBUS operation enables a Type-C port to save power when no load is connected. The TPS2583x-Q1 devices monitor the CC lines for a UFP connection and enable the internal buck regulator to source VBUS after a UFP is detected. As a result idle port power consumption is reduced compared to Type-A port systems where the buck regulator operates continuously to supply VBUS, even when no load is connected. Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 43 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 10.3.20 Thermal Sensing with NTC (TPS25833-Q1) The NTC input pin allows for user programmable thermal protection. See Electrical Characteristics for NTC pin thresholds. The NTC input pin threshold is ratiometric with VCC. The external resistor divider setting VNTC must be connected to the TPS25833-Q1 VCC pin to achieve accurate results. See Figure 10-28 and Figure 10-29. When VNTC = 0.5 × VCC (approximately 2.5 V typically), the TPS25833-Q1 performs two actions: 1. If operating with 3-A Type-C advertisement, the CC1 and CC2 pin automatically reduces advertisement to the 1.5-A level. 2. The THERM_WARN flag is asserted to provide an indication of the overtemperature condition. FAULT is NOT asserted at this time. TPS25833-Q1 /THERM_WARN /THERM_WARN VCC VCC RSER RPARA RNTC NTC CC override (3A -> 1.5A) RB Vth9 § VCC 2 Turn off Buck regulator Vth9 § 0.65 x VCC Figure 10-28. NTC Input Pin 44 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 Ambient Temp TNTC_TSD ûTSD TNTC_WARN ûTWARN 25C time CCx adv. current 330uA 180uA 80uA ûtWN2SD ûtSD2WN time Therm_Warn High Low time Buck Regulator ON OFF time Figure 10-29. TPS25833-Q1 Behavior when Trigger NTC Threshold If the overtemprature condition persists causing VNTC = VCC × 0.65 (3.25-V typical), the TPS25833-Q1 turns off the buck regulator and pulls the LS_GD pin low. The THERM_WARN flag remains asserted; however, the FAULT pin is NOT asserted for this condition. Tuning the VNTC threshold levels of VWARN_HIGH and VSD_HIGH is achieved by adding RSER, RPARA, or both RSER and RPARA in conjunction with RNTC. Figure 10-30 is an example illustrating how to set the THERM_WARN threshold between 75°C and 90°C with a ΔT between THERM_WARN assertion and device shutdown of 17°C to 28°C. Consult the chosen NTC manufacturer's specification for the value of β. It may take some iteration to establish the desired warning and shutdown thresholds. Below is NTC spec and resistor value used in Figure 10-30 example. • • • • R0 = 470 kΩ. β = 4750. RNTC=R0 × exp β × (1/T-1/T0) RPARA = 100 kΩ. RSER = 5 kΩ. RB = RNTC(at T_ THERM_WARN) = 32 kΩ Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 45 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 5 4.5 4 VNTC (V) NTC pin voltage 3.5 VNTC w/top ser (V) 3 VNTC w/top || (V) 2.5 VNTC w para + ser (V) 2 1.5 Vth WARN 1 Vth S/D 0.5 0 0 50 100 150 Temperature (°C) Example Figure 10-30. VNTC Threshold Examples The NTC resistor should be placed near the hottest point on the PCB. In most cases, this will be close to the SW node of the TPS25833-Q1, near the buck inductor, RSNS sense resistor and external MOSFETs (if used). EMI Filter VIN CFILT PGND CIN EN 7 6 5 4 USB Connector IN THERMAL_WARN CTRL1 8 CTRL2 NTC CFILT A4 3 2 1 RT 9 A1 32 BT 31 IMON 11 30 CIN LS_GD 10 SW ILIM 12 29 CSN/OUT 13 CFILT 28 CSP 14 27 BUS 15 26 PGND AGND 16 22 23 FAULT CC_2 21 LD_DET DP_IN 20 POL 19 VCC 18 CC_1 17 DM_IN A3 25 24 A2 RSET CFILT COUT CFILT RB RNTC CFILT COUT RSNS RBUS COUT NTC Top Trace/Plane Inner GND Plane VIA to Signal Layer VIA to GND Planes VIA to Strap Top Inner GND Plane Signal Layers Power and GND Figure 10-31. NTC Placement Example 46 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 10.4 Device Functional Modes 10.4.1 Shutdown Mode The EN pin provides electrical ON and OFF control for the TPS2583x-Q1. When VEN is below 1.2 V (typical), the device is in shutdown mode. The TPS2583x-Q1 also employs VIN and VCC under voltage lock out protection. If VIN or VCC voltage is below their respective UVLO level, the regulator will be turned off. 10.4.2 Standby Mode If the EN pin is pulled above the EN threshold, and there is no active connection on the CC lines, TPS2583x-Q1 remains in a low-power state with the buck converter off until a valid UFP (sink) is detected with a valid RD on either CC1 or CC2. This mode ensures the Type-C 0-V VBUS requirement is met and saves system power when no device is connected. 10.4.3 Active Mode The TPS2583x-Q1 is in Active Mode when VEN is above the precision enable threshold, VIN and VCC are above their respective UVLO levels and a valid detection has been made on the CC lines. The simplest way to enable the TPS2583x-Q1 is to connect the EN pin to VIN pin. This allows self startup when the input voltage is in the operating range: 3.8 V to 36 V and a UFP detection is made. For details on setting these operating levels. please refer to VCC, VCC_UVLO and Enable/UVLO and Start-up. In Active Mode, the TPS2583x-Q1 buck regulator operates with forced pulse width modulation (FPWM), also referred to as forced continuous conduction mode (FCCM). This ensures the buck regulator switching frequency remains constant under all load conditions. FPWM operation provides low output voltage ripple, tight output voltage regulation, and constant switching frequency. Built-in spread-spectrum modulation aids in distributing spectral energy across a narrow band around the switching frequency programmed by the RT/SYNC pin. Under light load conditions the inductor current is allowed to go negative. A negative current limit of IL_NEG is imposed to prevent damage to the regulator's low side FET. During operation the TPS2583x-Q1 will synchronize to any valid clock signal on the RT/SYNC input. 10.4.4 Device Truth Table (TT) The device truth table (Table 10-10) lists all valid combinations for the two control pins (CTRL1 and CTRL2). The TPS2583x-Q1 devices monitor the CTRL inputs and transitions to whichever charging mode it is commanded. Table 10-10. Truth Table DEVICE TPS25832 -Q1 TPS25833 -Q1 CTR L1 CTR L2 0 0 0 1 1 0 1 1 0 0 0 1 1 0 1 1 CURRENT LIMIT SETTING USB MODES BUCK REGULATO R LS_GD LD_DET (OUTPUT) POL (OUTPUT) FAULT (OUTPUT) NTC (ANALOG INPUT) RESERVED, DO NOT USE RESERVED, DO NOT USE See Current Limit Sensing using RILIMIT Type-C (1.5 A) + SDP Mode Type-C (3 A) + CDP Mode functional, see Table 10-7 functional, see Table 10-4 n/a n/a RESERVED, DO NOT USE Type-C (3 A) + DCP Auto Mode Current Limit Type-C (1.5 A) + Sensing SDP Mode using RILIMIT Type-C (3 A) + CDP Mode functional functional, see Table 10-7 functional, see Table 10-4 functional functional 10.4.5 USB Port Operating Modes 10.4.5.1 USB Type-C® Mode The TPS2583x-Q1 is a Type-C controller that supports all Type-C functions in a downstream facing port. It is also used to manage current advertisement and protection to a connected UFP and active cable. When VIN Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 47 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 exceeds the undervoltage lockout threshold, the device samples the EN pin. A high level on this pin enables the device and normal operation begins. Having successfully completed its start-up sequence, the device now actively monitors its CC1 and CC2 pins for attachment to a UFP. When a UFP is detected on either the CC1 or CC2 pin the buck regulator turn-ons after the required de-bounce time is met. If connected, the LS_GD pin sources current into the external MOSFET allowing current to flow from CSN/OUT to BUS. If Ra is detected on the other CC pin (not connected to UFP), VCONN is applied to allow current to flow from VCC to the CC pin connected to Ra. For a complete listing of various device operational modes refer to Table 10-7. The TPS2583x-Q1 always starts in Type-C mode, then transitions to DCP, CDP, or SDP as determined by the CTRL1 and CTRL2 pins and signaling by the connected portable device on the DP_IN and DM_IN pins. 10.4.5.2 Standard Downstream Port (SDP) Mode — USB 2.0, USB 3.0, and USB 3.1 An SDP is a traditional USB port that follows USB 2.0, USB 3.0 or USB 3.1 protocol. A USB 2.0 SDP supplies a minimum of 500 mA per port and supports USB 2.0 communications. A USB 3.x SDP supplies a minimum of 900 mA per port and supports USB 3.0 or USB 3.1 communications. For both types, the host controller must be active to allow charging. 10.4.5.3 Charging Downstream Port (CDP) Mode A CDP is a USB port that follows USB BC1.2 and supplies a minimum of 1.5 A per port. A CDP provides power and meets the USB 2.0 requirements for device enumeration. USB-2.0 communication is supported, and the host controller must be active to allow charging. The difference between CDP and SDP is the host-charge handshaking logic that identifies this port as a CDP. A CDP is identifiable by a compliant BC1.2 client device and allows for additional current draw by the client device. The CDP handshaking process occurs in two steps. During step one, the portable equipment outputs a nominal 0.6-V output on the D+ line and reads the voltage input on the D– line. The portable device detects the connection to an SDP if the voltage is less than the nominal data-detect voltage of 0.3 V. The portable device detects the connection to a CDP if the D– voltage is greater than the nominal data detect voltage of 0.3 V and optionally less than 0.8 V. The second step is necessary for portable equipment to determine whether the equipment is connected to a CDP or a DCP. The portable device outputs a nominal 0.6-V output on the D– line and reads the voltage input on the D+ line. The portable device concludes the equipment is connected to a CDP if the data line being read remains less than the nominal data detects voltage of 0.3 V. The portable device concludes it is connected to a DCP if the data line being read is greater than the nominal data detect voltage of 0.3 V. 10.4.5.4 Dedicated Charging Port (DCP) Mode (TPS25833-Q1 Only) A DCP only provides power and does not support data connection to an upstream port. As shown in the following sections, a DCP is identified by the electrical characteristics of the data lines. The TPS25833-Q1 only emulates one state, DCP-auto state. In the DCP-auto state, the device charge-detection state machine is activated to selectively implement charging schemes involved with the shorted, divider 3 and 1.2-V modes. The shorted DCP mode complies with BC1.2 and Chinese Telecommunications Industry Standard YD/T 1591-2009, whereas the divider 3 and 1.2-V modes are employed to charge devices that do not comply with the BC1.2 DCP standard. 10.4.5.4.1 DCP BC1.2 and YD/T 1591-2009 Both standards specify that the D+ and D– data lines must be connected together with a maximum series impedance of 200 Ω, as shown in Figure 10-32. 48 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 D– 200 Ω (m a x.) D+ GND USB Connector VBUS 5V Figure 10-32. DCP Supporting BC1.2 and YD/T 1591-2009 10.4.5.4.2 DCP Divider-Charging Scheme The device supports divider 3, as shown in Figure 10-33. In the divider 3 charging scheme the device applies 2.7 V and 2.7 V to D+ and D– data lines. VBUS USB Connector 5V D– 2.7 V 2.7 V D+ GND Figure 10-33. Divider 3 Mode 10.4.5.4.3 DCP 1.2-V Charging Scheme The DCP 1.2-V charging scheme is used by some hand-held devices to enable fast charging at 2 A. The TPS25833-Q1 device supports this scheme in DCP-auto state before the device enters BC1.2 shorted mode. To simulate this charging scheme, the D+ and D– lines are shorted and pulled up to 1.2 V for a fixed duration. Then the device moves to DCP shorted mode as defined in the BC1.2 specification and as shown in Figure 10-34. 200 Ω (m a x.) D– D+ 1.2 V GND USB Connector VBUS 5V Figure 10-34. 1.2-V Mode 10.4.5.5 DCP Auto Mode (TPS25833-Q1 Only) The TPS25833-Q1 device integrates an auto-detect state machine that supports all DCP charging schemes. The auto-detect state machine starts in the divider 3 scheme. If a BC1.2 or YD/T 1591-2009 compliant device is attached, the TPS25833-Q1 device briefly transitions to the 1.2 V mode before entering BC1.2 DCP mode. The auto-detect state machine stays in the 1.2 V or DCP mode until the connected device releases the data line, in which case the auto-detect state machine goes back to the divider 3 scheme. When a divider 3-compliant device is attached, the TPS25833-Q1 device stays in the Divider 3 state. Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 49 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 5V S1 S2 S3 2.7 V 2.7 V S4 DM_IN D– DP_IN D+ GND GND USB Connector VBUS 1.2 V Divider 3 Mode S1, S2: ON S3, S4: OFF Shorted Mode S4 ON S1, S2, S3: OFF 1.2-V Mode S1, S2: OFF S3, S4: ON Figure 10-35. DCP Auto Mode 10.4.6 High-Bandwidth Data-Line Switches (TPS25832-Q1 Only) The TPS25832-Q1 device passes the DP and DM data lines through the device to enable monitoring and handshaking while supporting the charging operation. A wide-bandwidth signal switch allows data to pass through the device without corrupting signal integrity. The data-line switches are turned on in any of the CDP, SDP modes. The EN/UVLO input must be at logic high and UFP must be entered for the data line switches to be enabled. For more detailed USB2.0 data line consideration and eye diagram test report, please refer to the How to Improve USB2.0 Eye Diagram using Long USB Cable application report. • • • • • • 50 Note While in CDP mode, the data switches are ON, even during CDP handshaking. The data line switches are OFF if EN/UVLO is low. The data line switches are OFF during External FET current limit conditions. The data line switches are not turned off during VCONN current-limit conditions. The data line switches are OFF if UFP mode is not entered. The data switches are only for a USB-2.0 differential pair. In the case of a USB-3.0 or 3.1 host, the super-speed differential pairs must be routed directly to the USB connector without passing through the TPS25832-Q1 device. Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 11 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. 11.1 Application Information The TPS2583x-Q1 is a step down DC-to-DC regulator and USB charge port controller. The TPS2583x-Q1is typically used in automotive systems to convert a DC voltage from the vehicle battery to 5-V DC with a maximum output current of 3.5 A. The following design procedure can be used to select components for the TPS2583x-Q1. 11.2 Typical Application The TPS2583x-Q1 only requires a few external components to convert from a wide voltage range supply to a 5-V output for powering USB devices. Figure 11-1 shows a basic schematic. CBOOT CSNS 0.1 F 0.1 F VIN 6 V to 18 V CIN(HF) + CIN(BULK) CIN 10 F 0.1 F RENT 20 k RENB 5k IN (1, 2, 3) BOOT (32) SW (28, 29, 30, 31) EN/UVLO (4) L RSNS 10 H RSET CCSP 0.015 5*22 F CSP (14) 300 CSN/OUT (13) 0.22 F 0.22 F 0.22 F 2.2 F CVCC(HF) CC1 (20) RPU CTRL1 (5) CTRL2 (6) RPU 100 k 100 k RPU RPU 100 k 100 k RPU FAULT (24) LD_DET (23) POL (22) NTC 100 BUS (15) 0.1 F RPU 100 k VCC (21) CCSN/OUT 0.1 F Type-C Connector CVCC LS_GD (10) THERM_WARN (7) 100 k CC2 (19) DM_IN (17) DP_IN (18) RT/SYNC (9) IMON (11) RIMON ILIMIT (12) 12.7 k AGND (16) NTC (8) PGND (25, 26, 27) RILIMIT 11.8 k CBUS 1 F RRT 49.9 k Figure 11-1. Application Circuit The integrated buck regulator of TPS2583x-Q1 is internally compensated and optimized for a reasonable selection of external inductance and capacitance. The external components have to fulfill the needs of the application, but also the stability criteria of the device control loop. Table 11-2 can be used to simplify the output filter component selection. 11.2.1 Design Requirements To begin the design process, a few parameters must be known: • • Cable compensation: Total resistance including cable resistance, contact resistance of connectors, TPS2583x-Q1 current sense resistor and external NFET rDS(on) (if used). Refer to Figure 10-22 for examples of resistances in an automotive application. The maximum continuous output current for the charging port. The minimum current-limit setting of TPS2583x-Q1 device must be higher than this current. Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 51 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 For this example, use the parameters listed in Table 11-1 as the input parameters. Table 11-1. Design Example Parameters PARAMETER VALUE Input Voltage, VIN 13.5 V-typical, range from 6 V to 18 V Output Voltage, VOUT 5.1 V Maximum Output Current IOUT(MAX) 3.0 A Transient Response 0.3 A to 3 A 5% Output Voltage Ripple 50 mV Input Voltage Ripple 400 mV Switching Frequency fSW 400 kHz Cable Resistance for Cable Compensation 300 mΩ Current Limit by Buck Average 3.3 A Table 11-2. L, and COUT Typical Values fSW VOUT WITHOUT CABLE COMPENSATION CIN + CHF L CURRENT LIMIT CCSP CCSN/OUT CBUS 400 kHz 5.10 V 1 × 10 µF + 1 × 100 nF 10 µH Buck Avg 5 × 22 µF 100 nF 1 to 4.7 µF 400 kHz 5.10 V 1 × 10 µF + 1 × 100 nF 10 µH Ext. NFET 5 × 22 µF 100 nF 1 to 4.7 µF 2100 kHz 5.10 V 1 × 10 µF + 1 × 100 nF 2.2 µH Buck Avg 2 × 22 µF 100 nF 1 to 4.7 µF 1. Inductance value is calculated based on VIN = 18 V. 2. All the COUT values are after derating. 11.2.2 Detailed Design Procedure 11.2.2.1 Output Voltage The output voltage of TPS2583x-Q1 is internally fixed at 5.10 V. Cable compensation can be used to increase the voltage on the CSN/OUT pin linearly with increasing load current. Refer to Cable Compensation for more details on output voltage variation versus load current. If cable compensation is not desired, use a 0 Ω RIMON resistor. 11.2.2.2 Switching Frequency The recommended switching frequency of the TPS2583x-Q1 is in the range of 300-400 kHz for best efficiency. Choose RRT = 49.9 kΩ for 400 kHz operation. To choose a different switching frequency, refer to Table 10-1. 11.2.2.3 Inductor Selection The most critical parameters for the inductor are the inductance, saturation current and the rated current. The inductance is based on the desired peak-to-peak ripple current ΔiL. Since the ripple current increases with the input voltage, the maximum input voltage is always used to calculate the minimum inductance LMIN. Use Equation 10 to calculate the minimum value of the output inductor. KIND is a coefficient that represents the amount of inductor ripple current relative to the maximum output current of the device. A reasonable value of KIND should be 20% to 40%. During an instantaneous short or overcurrent operation event, the RMS and peak inductor current can be high. The inductor current rating should be higher than the current limit of the device. 'iL LMIN VOUT u VIN _ MAX VOUT VIN _ MAX u L u fSW VIN _ MAX VOUT IOUT u KIND u (9) VOUT VIN _ MAX u fSW (10) In general, it is preferable to choose lower inductance in switching power supplies, because it usually corresponds to faster transient response, smaller DCR, and reduced size for more compact designs. But too 52 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 low of an inductance can generate too large of an inductor current ripple such that overcurrent protection at the full load could be falsely triggered. It also generates more conduction loss and inductor core loss. Larger inductor current ripple also implies larger output voltage ripple with same output capacitors. With peak current mode control, it is not recommended to have too small of an inductor current ripple. A larger peak current ripple improves the comparator signal to noise ratio. For this design example, choose KIND = 0.3, the minimum inductor value is calculated to be 8.7 µH. Choose the nearest standard 10 μH ferrite inductor with a capability of 4-A RMS current and 6-A saturation current. 11.2.2.4 Output Capacitor Selection The value of the output capacitor, and its ESR, 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 11 can be used to estimate a lower bound on the total output capacitance, and an upper bound on the ESR, required to meet a specified load transient. COUT t ESR d D fSW 'IOUT ˜ 'VOUT ˜ K ª ˜«1 D ˜ 1 K ¬« º K2 ˜ 2 D» 12 ¼» 2 K ˜ 'VOUT ª K2 § 1 ·º ¸» ˜ ¨¨1 2 ˜ 'IOUT «1 K 12 © (1 D) ¸¹¼» ¬« VOUT VIN (11) where • • • ΔVOUT = output voltage transient ΔIOUT = output current transient K = Ripple factor from Inductor Selection Once the output capacitor and ESR have been calculated, Equation 12 can be used to check the peak-to-peak output voltage ripple; Vr. Vr # 'IL ˜ ESR 2 1 8 ˜ fSW ˜ COUT 2 (12) The output capacitor and ESR can then be adjusted to meet both the load transient and output ripple requirements. For this example we require a ΔVOUT of ≤ 250 mV for an output current step of ΔIOUT = 2.7 A. Equation 11 gives a minimum value of 86 µF and a maximum ESR of 0.08 Ω. Assuming a 20% tolerance and a 10% bias de-rating, we arrive at a minimum capacitance of 110 µF. This can be achieved with a bank of 5 × 22-µF, 10-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 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 should 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 to reduce high frequency noise. Small case size ceramic capacitors in the range of 1 nF to 100 nF can be very helpful in reducing voltage spikes on the output caused by inductor and board parasitics. Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 53 TPS25832-Q1, TPS25833-Q1 SLVSEH7D – JULY 2019 – REVISED MARCH 2022 www.ti.com The maximum value of total output capacitance should 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. 11.2.2.5 Input Capacitor Selection The TPS2583x-Q1 device requires high frequency input decoupling capacitor(s) and a bulk input capacitor, depending on the application. A high-quality ceramic capacitor type X5R or X7R with sufficient voltage ratings are recommended. To compensate the derating of ceramic capacitors, a voltage rating of twice the maximum input voltage is recommended. The bulk capacitance selection depends upon a number of factors: long leads from the automotive battery to the IN pin of TPS2583x-Q1, cold or warm engine crank requirements, and so forth. The bulk capacitor is used to dampen voltage spike due to the lead inductance of the cable or the trace. For this design, one 10-μF, 50-V, X7R ceramic capacitor is used. A 0.1 μF for high-frequency filtering and place it as close as possible to the device pins. Consider adding additional bulk capacitance for operation through low VIN warm-crank profiles is required by the vehicle OEM. 11.2.2.6 Bootstrap Capacitor Selection Every TPS2583x-Q1 design requires a bootstrap capacitor (CBOOT). The recommended capacitor is 0.1 μF and rated 10 V or higher. The bootstrap capacitor is located between the SW pin and the BOOT pin. The bootstrap capacitor must be a high-quality ceramic type with an X7R or X5R grade dielectric for temperature stability. 11.2.2.7 VCC Capacitor Selection The VCC pin is the output of an internal LDO for TPS2583x-Q1. The LDO supplies gate charge to the LS buck switch and is the supply to the digital state-machine and analog USB circuitry. To insure stability of the device, place a minimum of 2.2 μF, 10 V, X7R capacitor from this pin to ground. In addition a 0.1 μF high frequency decoupling capacitor is highly recommended. 11.2.2.8 Enable and Under Voltage Lockout Set-Point The system enable and undervoltage lockout (UVLO) is adjusted using the external voltage divider network of RENT and RENB. The EN/UVLO has two thresholds, one for power up when the input voltage is rising and one for power down or brown outs when the input voltage is falling. The following equations can be used to determine the VIN(ON) and VIN(OFF) levels. (13) (14) VIN(ON) = 6 V (user choice) RENB = 5 kΩ (user choice) RENT = [(VIN(ON) / VEN/UVLO_H) – 1] × RENB RENT = [(6 V / 1.2 V) – 1] × 5 kΩ = 20 kΩ. Choose standard 20 kΩ. Therefore VIN(OFF) = 6 V × [1 – (0.09 V / 1.2 V)] = 5.55 V 11.2.2.9 Current Limit Set-Point The TPS2583x-Q1 provides an accurate current limit to protect the USB port from overload based upon the values of RSNS, RSET and RILIMIT. The design process is the same regardless of whether buck average current limiting or external NFET current limiting is chosen. The only difference is the current limit threshold voltage on the ILIMIT pin. 54 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 TPS25832-Q1, TPS25833-Q1 www.ti.com • • • SLVSEH7D – JULY 2019 – REVISED MARCH 2022 RSNS is the current sense resistor. The recommended voltage across RSNS under current limit should be approximately 50 mV as a compromise between accuracy and power dissipation. For example, if current limiting is desired for IOUT(MAX) ≥ 3.3 A, then RSNS = 0.05 V / 3.3 A = 0.01515 Ω. Choose a standard value of 15 mΩ. RSET determines the input current to the transconductance amplifier and current mirror. The amplifier balances the voltage to be equal to that across RSNS. Choose a RSET value to produce an ISET current between 75 - 180 µA at the desired IOUT(MAX). Considering 50 mV across RSET, a value of 300 Ω will provide approximately 166 µA of ISET current to the amplifier and mirror circuit. Care should be taken to limit the ISET current below 200 µA to avoid saturating the internal amplifier circuit. Buck average current limiting occurs when VILIMIT = 1 V. RILIMIT is calculated as 1 V x 300 Ω / [ 0.5 x (3.3 A x 15 mΩ + 0.7 mV) ] = 11.95 kΩ. A standard 11.8 kΩ value is chosen. 11.2.2.10 Cable Compensation Set-Point From Table 11-1 the total cable resistance to be accounted for is 300 mΩ. 1. 2. 3. 4. From Current Limit Set-Point RSNS and RSET have been determined as 15 mΩ and 300 Ω, respectively. RWIRE = 300 mΩ ΔVOUT = (RSNS + RWIRE) × IBUS = (0.015 + 0.3) × 3 = 1.0395 V RIMON = (ΔVOUT × RSET × 2) / (IBUS × RSNS) = (1.0395 × 300 × 2) / (3.3 × 0.015) = 12.6 kΩ. A standard value of 12.7 kΩ is selected. 11.2.2.11 LD_DET, POL, and FAULT Resistor Selection The LD_DET, POL, and FAULT pins are open-drain output flags. They can be connected to the TPS2583x-Q1 VCC pin with 100 kΩ resistors, or connected to another suitable I/O voltage supply if actively monitored by a USB HUB or MCU. They can be left floating if unused. Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 55 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 11.2.3 Application Curves 100 100 95 90 90 80 Efficiency (%) Efficiency (%) Unless otherwise specified the following conditions apply: VIN = 13.5 V, fSW = 400 kHz, L = 10 µH, COUT_CSP = 66 µF, COUT_CSN = 0.1 µF, CBUS = 1 µF, TA = 25 °C. 85 80 75 70 60 0.1 1 OUT Current (A) VOUT = 5.1 V 60 50 40 VIN = 6V VIN = 13.5V VIN = 18V VIN = 36V 65 70 20 0.1 4 VOUT = 5.1 V 100 100 95 90 90 80 85 80 75 70 1 OUT Current (A) 50 VIN = 8.5V VIN = 13.5V VIN = 18V 20 0.1 RSENS = 15 mΩ 1 OUT Current (A) VOUT = 5.1 V 4 A004 fSW = 2100 kHz RSENS = 15 mΩ Figure 11-5. Efficiency with Sense Resistor 0.4 0.1 VIN = 6V VIN = 13.5V VIN = 18V Load = 1A Load = 2A Load = 3A 0.08 Line Regulation (%) 0.3 Load Regulation (%) 60 A003 Figure 11-4. Efficiency with Sense Resistor 0.2 0.1 0 -0.1 0.06 0.04 0.02 0 -0.02 -0.2 -0.04 0 0.5 VOUT = 5.1 V 1 1.5 2 OUT Current (A) 2.5 fSW = 400 kHz Figure 11-6. Load Regulation 56 70 30 4 fSW = 400 kHz A002 fSW = 2100 kHz 40 VIN = 6V VIN = 13.5V VIN = 18V VIN = 36V 65 4 Figure 11-3. Buck Only Efficiency Efficiency (%) Efficiency (%) Figure 11-2. Buck Only Efficiency VOUT = 5.1 V 1 OUT Current (A) A001 fSW = 400 kHz 60 0.1 VIN = 8.5V VIN = 13.5V VIN = 18V 30 3 6 9 12 A005 VOUT = 5.1 V 15 18 21 24 VIN Voltage (V) 27 30 33 36 A006 fSW = 400 kHz Figure 11-7. Line Regulation Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 VBUS, 200mV/Div VBUS, 200mV/Div Load Current, 2A/Div Load Current, 2A/Div 200us/Div ILOAD = 0 A to 3.5A 200us/Div RIMON = 0 Ω Figure 11-8. Load Transient Without Cable Compensation ILOAD = 0.75 A to 2.25A RIMON = 0 Ω Figure 11-9. Load Transient Without Cable Compensation VBUS, 500mV/Div VBUS, 500mV/Div Load Current, 2A/Div Load Current, 2A/Div 2ms/Div 2ms/Div ILOAD = 0 A to 3.5A RIMON = 13 kΩ Figure 11-10. Load Transient With Cable Compensation ILOAD = 0.75 A to 2.25A RIMON = 13 kΩ Figure 11-11. Load Transient With Cable Compensation 6 SW, 5V/Div VBUS Voltage (V) 5.5 5 4.5 4 VBUS, 10mV/Div (AC coupled) Load = 0A Load = 1A Load = 2A Load = 3A Load = 3.5A 3.5 3 4 4.5 5 5.5 6 Input Voltage (V) 6.5 7 Figure 11-12. Dropout Characteristic 7.5 A007 2us/Div RIMON = 13 kΩ Figure 11-13. 3.5-A Output Ripple Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 57 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 SW, 5V/Div SW, 5V/Div VBUS, 10mV/Div (AC coupled) VBUS, 10mV/Div (AC coupled) 2us/Div 2us/Div RIMON = 13 kΩ RIMON = 13 kΩ Figure 11-14. 100-mA Output Ripple EN, 5V/Div Figure 11-15. No Load Output Ripple EN, 5V/Div VIN 5V/Div VIN 5V/Div VBUS, 5V/Div VBUS, 5V/Div VCC, 5V/Div VCC, 5V/Div 10ms/Div 40ms/Div VIN = 0 V to 13.5 V CC1 = Rd ILOAD = 3A Figure 11-16. Startup Relate to VIN VIN = 13.5 V to 0 V CC1 = Rd ILOAD = 3A Figure 11-17. Shutdown Relate to VIN EN, 5V/Div EN, 5V/Div VIN 5V/Div VIN, 5V/Div VBUS, 2V/Div VBUS, 2V/Div VCC, 2V/Div VCC, 5V/Div 40ms/Div EN = 0V to 5V CC1 = Rd Figure 11-18. Startup Relate to EN 58 ILOAD = 3A 40ms/Div EN = 5V to 0V CC1 = Rd ILOAD = 3A Figure 11-19. Shutdown Relate to EN Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 VIN, 10V/Div VIN, 10V/Div VBUS, 2V/Div Rd assert Rd desert VBUS, 2V/Div CC1, 2V/Div CC1, 2V/Div CC2, 2V/Div CC2, 2V/Div 40ms/Div CC1 = Open to Rd CC2 = Open ILOAD = 3A 20ms/Div CC1 = Rd to Open Figure 11-20. Rd Assert CC2 = Open ILOAD = 3A Figure 11-21. Rd Desert EN, 10V/Div EN, 10V/Div FAULT, 2V/Div Short removed FAULT, 2V/Div VBUS, 2V/Div VBUS, 2V/Div Load Current, 5A/Div 100ms/Div EN to High VBUS = GND Load Current, 5A/Div RLIMIT = 13 kΩ Figure 11-22. Enable into Short Without External FET 40ms/Div RLIMIT = 13 kΩ Figure 11-23. Short Circuit Recovery Without External FET EN, 10V/Div EN, 10V/Div FAULT, 2V/Div FAULT, 2V/Div VBUS, 1V/Div 1Ÿ load removed Load Current, 2A/Div VBUS, 1V/Div Load Current, 2A/Div EN to High VBUS = GND 100ms/Div 100ms/Div RLIMIT = 13 kΩ RLIMIT = 13 kΩ Figure 11-24. Enable into 1-Ω Load Without External FET Figure 11-25. 1-Ω Load Recovery Without External FET Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 59 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 EN, 10V/Div EN, 10V/Div FAULT, 2V/Div Short removed FAULT, 2V/Div VBUS, 2V/Div VBUS, 2V/Div Load Current, 2A/Div Load Current, 2A/Div 100ms/Div 100ms/Div RLIMIT = 6.8 kΩ RLIMIT = 6.8 kΩ Figure 11-26. Enable into Short With External FET Figure 11-27. Short Circuit Recovery With External FET EN to High VBUS = GND EN, 10V/Div EN, 10V/Div FAULT, 2V/Div FAULT, 2V/Div VBUS, 2V/Div VBUS hot short to GND VBUS, 2V/Div VBUS hot short to GND Load Current, 2A/Div Load Current, 5A/Div 1ms/Div 2ms/Div RLIMIT = 13 kΩ RLIMIT = 6.8 kΩ Figure 11-28. VBUS Hot Short to GND Without External FET Figure 11-29. VBUS Hot Short to GND With External FET FAULT, 5V/Div VNTC, 2V/Div CC2, 2V/Div VNTC > VWARN_HIGH VBUS, 2V/Div THERM_WARN, 5V/Div CC2 hot short to GND CC1, 2V/Div SW, 10V/Div CC2 Current, 200mA/Div 2ms/Div 100ms/Div CC1 = Rd CC2 = Ra Figure 11-30. CC2 Hot Short to GND 60 VNTC = 0V to 3V CC1 = Rd CC2 = OPEN Figure 11-31. Thermal Sensing with NTC Behavior 1 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 VNTC, 2V/Div VNTC > VSD_HIGH THERM_WARN, 5V/Div CC1, 2V/Div SW, 10V/Div 100ms/Div VNTC = 0 V to 4 V CC1 = Rd CC2 = OPEN Figure 11-32. Thermal Sensing with NTC Behavior 2 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 61 TPS25832-Q1, TPS25833-Q1 SLVSEH7D – JULY 2019 – REVISED MARCH 2022 www.ti.com 12 Power Supply Recommendations The TPS2583x-Q1 is designed to operate from an input voltage supply range between 6 V and 36 V. This input supply should be able to withstand the maximum input current and maintain a stable voltage. The resistance of the input supply rail should be low enough that an input current transient does not cause a high enough drop at the TPS2583x-Q1 supply voltage that can cause a false UVLO fault triggering and system reset. If the input supply is located more than a few inches from the TPS2583x-Q1, additional bulk capacitance may be required in addition to the ceramic input capacitors. The amount of bulk capacitance is not critical, but a 47-μF or 100-μF electrolytic capacitor is a typical choice. 13 Layout 13.1 Layout Guidelines Layout is a critical portion of good power supply design. The following guidelines will help users design a PCB with the best power conversion performance, thermal performance, and minimized generation of unwanted EMI. For more detailed EMC design consideration and test report, please refer to PCB Layout and Parameters Recommendation for TPS2583X EMC Performance application report 1. Input capacitor: The input bypass capacitor CIN must be placed as close as possible to the IN and PGND pins. Grounding for both the input and output capacitors should consist of localized top side planes that connect to the PGND pin and PAD. A combination of different values and packages of capacitors can help improve the EMC performance (for example: 10μF + 0.1 μF + 2.2nF). Besides, the distance between the input filter section and the output power section must be at least 15mm to prevent the output high-frequency signal from coupling into the input filter. A 10uF cap cross VIN and PGND pin on top of SW is suggested for TPS2583x-Q1. 2. VCC bypass capacitor: Place bypass capacitors for VCC close to the VCC pin and ground the bypass capacitor to device ground. 3. Use a ground plane in one of the middle layers as noise shielding and heat dissipation path. 4. Connect the thermal pad to the ground plane. The QFN package has a thermal pad (PAD) connection that must be soldered down to the PCB ground plane. This pad acts as a heat-sink connection. The integrity of this solder connection has a direct bearing on the total effective RθJA of the application. 5. Make VIN, VOUT and ground bus connections as wide as possible. This reduces any voltage drops on the input or output paths of the converter and maximizes efficiency. 6. Provide enough PCB area for proper heat sinking. As stated in the section, 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. Use an array of heat-sinking vias to connect the thermal pad (PAD) to the ground plane on the bottom PCB layer. If the PCB design uses multiple copper layers (recommended), thermal vias can also be connected to the inner layer heat-spreading ground planes. 7. The SW pin connecting to the inductor should be as short as possible, and just wide enough to carry the load current without excessive heating. Short, thick traces or copper pours (shapes) will bring a high current conduction capacity to minimize parasitic resistance, but it will also cause a larger parasitic capacitance. Thus a balance should be found between smaller parasitic resistance and larger parasitic capacitance. And the current path should be kept straight forward to the inductor, otherwise the L-shaped or T-shaped path will make a sudden change of the impedance which causes signal reflection and impacts the performance of EMC. The output capacitors should be placed close to the VOUT end of the inductor and closely grounded to PGND pin and exposed PAD. Besides, do not punch vias on SW lines. Using shielded inductors or molded inductors to reduce high-frequency radiation. 8. Sense and Set Resistors: The RSNS and RSET resistors connect to the current sense amplifier inputs at the CSP and CSN/OUT pins. For best current limit and cable compensation accuracy; short, parallel traces give the best performance. If it is not possible to place RSNS and RSET near the CSP and CSN/OUT pins, it is recommended that the traces from sense resistor be routed in parallel and of similar lengths. A small filter capacitor in parallel with RSNS and a small filter capacitor from CSN/OUT to AGND help decouple noise. 9. RILIMIT and RIMON resistors should be placed as close as possible to the ILIMIT and IMON pins and connected to AGND. If needed, these components can be placed on the bottom side of the PCB with signals routed through small vias. 62 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 10. Trace routing of DP_IN, DM_IN, DP_OUT, and DM_OUT: Route these traces as micro-strips with nominal differential impedance of 90 Ω. Minimize the use of vias in the high-speed data lines. Keep the reference GND plane devoid from cuts or splits above the differential pairs to prevent impedance discontinuities. 11. Keep the CC lines close to the same length. Do not create stubs or test points on the CC lines. 12. POL, LD_DET, FAULT and THERM_WARN (TPS25831-Q1) are open-drain outputs. They can be connected to the VCC pin via pull-up resistors. Suggested resistor value is 100 kΩ. 13. The area enclosed by current loop of input side and output side should be as small as possible; the area enclosed by the BOOT circuit should be as small as possible. 14. Power ground PGND and the signal ground AGND should be separated in the actual PCB layout. 13.2 Ground Plane and Thermal Considerations It is recommended to use one of the middle layers as a solid ground plane. Ground plane provides shielding for sensitive circuits and traces. It also provides a quiet reference potential for the control circuitry. The PGND pins should be connected to the ground plane using vias right next to the bypass capacitors. PGND pin is connected to the source of the internal LS switch. The PGND net contains noise at switching frequency and may bounce due to load variations. PGND trace, as well as VIN and SW traces, should be constrained to one side of the ground plane. The other side of the ground plane contains much less noise and should be used for sensitive routes. AGND and PGND should be connected under the QFN package PAD. It is recommended to provide adequate device heat sinking by utilizing the PAD of the IC as the primary thermal path. Use a minimum 2 row, 2 column "+" array of 12 mil thermal vias to connect the PAD to the system ground plane heat sink. The vias should be evenly distributed under the PAD. 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 of, 2 oz / 1 oz / 1 oz / 2 oz. Four layer boards with enough copper thickness provide low current conduction impedance, proper shielding and lower thermal resistance. The thermal characteristics of the TPS2583x-Q1 are specified using the parameter θJA, which characterize the junction temperature of silicon to the ambient temperature in a specific system. Although the value of θJA is dependent on many variables, it still can be used to approximate the operating junction temperature of the device. To obtain an estimate of the device junction temperature, one may use the following relationship: TJ = PD × θJA + TA (15) where TJ = Junction temperature in °C PD = VIN × IIN × (1 - Efficiency) – 1.1 × IOUT 2 × DCR in Watt DCR = Inductor DC parasitic resistance in Ω θJA = Junction to ambient thermal resistance of the device in °C/W TA = Ambient temperature in °C θJA is highly related to PCB size and layout, as well as environmental factors such as heat sinking and air flow. Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 63 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 13.3 Layout Example EMI Filter VIN CHF PGND CIN 6 5 4 USB Connector IN 7 EN DP_OUT 8 CTRL1 DM_OUT CTRL2 CHF A4 3 2 1 RT 9 A1 32 BT 31 IMON 11 30 CIN LS_GD 10 SW CFILT ILIM 12 29 CSN/OUT 13 28 CSP 14 27 BUS 15 26 PGND AGND 16 20 21 22 CC_2 CC_1 VCC POL 23 FAULT 19 LD_DET 18 DP_IN 25 17 DM_IN A3 24 A2 RSET CFILT COUT CFILT CFILT COUT RSNS RBUS COUT Top Trace/Plane Inner GND Plane VIA to Signal Layer VIA to GND Planes VIA to Strap Top Inner GND Plane Signal Layers Power and GND Figure 13-1. Layout 64 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: TPS25832-Q1 TPS25833-Q1 TPS25832-Q1, TPS25833-Q1 www.ti.com SLVSEH7D – JULY 2019 – REVISED MARCH 2022 14 Device and Documentation Support 14.1 Documentation Support 14.1.1 Related Documentation • • • Texas Instruments, How to Pass MFi Overcurrent Protection Test With USB Charger and Switch Device application report Texas Instruments, How to Improve USB2.0 Eye Diagram using Long USB Cable application report Texas Instruments, PCB Layout and Parameters Recommendation for TPS2583X EMC Performance application report 14.2 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. 14.3 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. 14.4 Trademarks TI E2E™ is a trademark of Texas Instruments. USB Type-C® is a registered trademark of USB Implementers Forum. All trademarks are the property of their respective owners. 14.5 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. 14.6 Glossary TI Glossary This glossary lists and explains terms, acronyms, and definitions. 15 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: TPS25832-Q1 TPS25833-Q1 65 PACKAGE OPTION ADDENDUM www.ti.com 31-Mar-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) TPS25832QCWRHBRQ1 ACTIVE VQFN RHB 32 5000 RoHS & Green NIPDAU Level-2-260C-1 YEAR -40 to 125 T25832 TPS25832QWRHBRQ1 ACTIVE VQFN RHB 32 3000 RoHS & Green SN Level-2-260C-1 YEAR -40 to 125 T25832 TPS25832QWRHBTQ1 ACTIVE VQFN RHB 32 250 RoHS & Green SN Level-2-260C-1 YEAR -40 to 125 T25832 TPS25833QCWRHBRQ1 ACTIVE VQFN RHB 32 5000 RoHS & Green NIPDAU Level-2-260C-1 YEAR -40 to 125 T25833 TPS25833QWRHBRQ1 ACTIVE VQFN RHB 32 3000 RoHS & Green SN Level-2-260C-1 YEAR -40 to 125 T25833 TPS25833QWRHBTQ1 ACTIVE VQFN RHB 32 250 RoHS & Green SN Level-2-260C-1 YEAR -40 to 125 T25833 (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