DRV8300UDRGER

DRV8300U SLVSGY3A – JULY 2022 – REVISED OCTOBER 2022 DRV8300U: 100-V Three-Phase BLDC Gate Driver 1 Features 3 Description • DRV8300U is 100-V three half-bridge gate drivers, capable of driving high-side and low-side N-channel power MOSFETs. The DRV8300UD generates the correct gate drive voltages using an integrated bootstrap diode and external capacitor for the highside MOSFETs. GVDD is used to generate gate drive voltage for the low-side MOSFETs. The Gate Drive architecture supports peak up to 750-mA source and 1.5-A sink currents. • • • • • • • • • • • • • • • • 100-V Three Phase Half-Bridge Gate driver – Drives N-Channel MOSFETs (NMOS) – Gate Driver Supply (GVDD): 5-20 V – MOSFET supply (SHx) support upto 100 V Integrated Bootstrap Diodes (DRV8300UD devices) Supports Inverting and Non-Inverting INLx inputs Bootstrap gate drive architecture – 750-mA source current – 1.5-A sink current Supports up to 15S battery powered applications Higher BSTUV (8V typ) and GVDDUV (7.6V typ) threshold to support standard MOSFETs Low leakage current on SHx pins ( 1µF Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: DRV8300U DRV8300U www.ti.com SLVSGY3A – JULY 2022 – REVISED OCTOBER 2022 7.4 Thermal Information DRV8300U THERMAL RθJA METRIC(1) PW (TSSOP) RGE (VQFN) 20 PINS 24 PINS 97.4 49.3 °C/W RθJC(top) Junction-to-case (top) thermal resistance 38.3 42.5 °C/W RθJB Junction-to-board thermal resistance 48.8 26.5 °C/W ΨJT Junction-to-top characterization parameter 4.3 2.2 °C/W ΨJB Junction-to-board characterization parameter 48.4 26.4 °C/W RθJC(bot) Junction-to-case (bottom) thermal resistance N/A 11.5 °C/W (1) Junction-to-ambient thermal resistance UNIT For more information about traditional and new thermal metrics, see the Semiconductor and IC Package Thermal Metrics application report. 7.5 Electrical Characteristics 8.7 V ≤ VGVDD ≤ 20 V, –40°C ≤ TJ ≤ 150°C (unless otherwise noted) PARAMETER TEST CONDITIONS MIN TYP MAX UNIT POWER SUPPLIES (GVDD, BSTx) GVDD standby mode current INHx = INLX = 0; VBSTx = VGVDD 400 800 1400 µA GVDD active mode current INHx = INLX = Switching @20kHz; VBSTx = VGVDD; NO FETs connected 400 825 1400 µA ILBSx Bootstrap pin leakage current VBSTx = VSHx = 85V; VGVDD = 0V 2 4 7 µA ILBS_TRAN Bootstrap pin active mode transient leakage current INHx = Switching@20kHz 30 105 220 µA ILBS_DC Bootstrap pin active mode leakage static current INHx = High 30 85 150 µA ILSHx High-side source pin leakage current INHx = INLX = 0; VBSTx - VSHx = 12V; VSHx = 0 to 85V 30 55 80 µA IGVDD LOGIC-LEVEL INPUTS (INHx, INLx, MODE) VIL_MODE Input logic low voltage Mode pin 0.6 V VIL Input logic low voltage INLx, INHx pins 0.8 V VIH_MODE Input logic high voltage Mode pin 3.7 V VIH Input logic high voltage INLx, INHx pins 2.0 V VHYS_MODE Input hysteresis Mode pin 1600 2000 2400 mV VHYS Input hysteresis INLx, INHx pins 40 100 260 mV VPIN (Pin Voltage) = 0 V; INLx in noninverting mode -1 0 1 µA VPIN (Pin Voltage) = 0 V; INLx in inverting mode 5 20 30 µA VPIN (Pin Voltage) = 5 V; INLx in noninverting mode 5 20 30 µA VPIN (Pin Voltage) = 5 V; INLx in inverting mode 0 0.5 1.5 µA -1 0 1 µA IIL_INLx IIH_INLx INLx Input logic low current INLx Input logic high current IIL INHx, MODE Input logic low current VPIN (Pin Voltage) = 0 V; IIH INHx, MODE Input logic high current VPIN (Pin Voltage) = 5 V; 5 20 30 µA RPD_INHx INHx Input pulldown resistance To GND 120 200 280 kΩ RPD_INLx INLx Input pulldown resistance To GND, INLx in non-inverting mode 120 200 280 kΩ RPU_INLx INLx Input pullup resistance To INT_5V, INLx in inverting mode 120 200 280 kΩ RPD_MODE MODE Input pulldown resistance To GND 120 200 280 kΩ GATE DRIVERS (GHx, GLx, SHx, SLx) Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: DRV8300U 7 DRV8300U www.ti.com SLVSGY3A – JULY 2022 – REVISED OCTOBER 2022 8.7 V ≤ VGVDD ≤ 20 V, –40°C ≤ TJ ≤ 150°C (unless otherwise noted) PARAMETER TEST CONDITIONS MIN TYP MAX UNIT 0 0.15 0.35 V VGHx_LO I = -100 mA; VGVDD = 12V; No FETs High-side gate drive low level voltage GLx connected VGHx_HI High-side gate drive high level voltage (VBSTx - VGHx) IGHx = 100 mA; VGVDD = 12V; No FETs connected 0.3 0.6 1.2 V VGLx_LO Low-side gate drive low level voltage IGLx = -100 mA; VGVDD = 12V; No FETs connected 0 0.15 0.35 V VGLx_HI Low-side gate drive high level voltage IGHx = 100 mA; VGVDD = 12V; No FETs (VGVDD - VGHx) connected 0.3 0.6 1.2 V IDRIVEP_HS High-side peak source gate current GHx-SHx = 12V 400 750 1200 mA IDRIVEN_HS High-side peak sink gate current GHx-SHx = 0V 850 1500 2100 mA IDRIVEP_LS Low-side peak source gate current GLx = 12V 400 750 1200 mA IDRIVEN_LS Low-side peak sink gate current GLx = 0V 850 1500 2100 mA tPD Input to output propagation delay INHx, INLx to GHx, GLx; VGVDD = VBSTx - VSHx > 8V; SHx = 0V, No load on GHx and GLx 70 125 180 ns tPD_match Matching propagation delay per phase GHx turning OFF to GLx turning ON, GLx turning OFF to GHx turning ON; VGVDD = VBSTx - VSHx > 8V; SHx = 0V, No load on GHx and GLx -30 ±4 30 ns tPD_match GHx/GLx turning ON to GHy/GLy turning Matching propagation delay phase to ON, GHx/GLx turning OFF to GHy/GLy phase turning OFF; VGVDD = VBSTx - VSHx > 8V; SHx = 0V, No load on GHx and GLx -30 ±4 30 ns tR_GLx GLx rise time (10% to 90%) CLOAD = 1000 pF; VGVDD = VBSTx - VSHx > 8V; SHx = 0V 10 24 50 ns tR_GHx GHx rise time (10% to 90%) CLOAD = 1000 pF; VGVDD = VBSTx - VSHx > 8V; SHx = 0V 10 24 50 ns tF_GLx GLx fall time (90% to 10%) CLOAD = 1000 pF; VGVDD = VBSTx - VSHx > 8V; SHx = 0V 5 12 30 ns tF_GHx GHx fall time (90% to 10%) CLOAD = 1000 pF; VGVDD = VBSTx - VSHx > 8V; SHx = 0V 5 12 30 ns DT pin floating 150 215 280 ns DT pin connected to GND 150 215 280 ns tDEAD Gate drive dead time tPW_MIN 40 kΩ between DT pin and GND 150 200 260 ns 400 kΩ between DT pin and GND 1500 2000 2600 ns 40 70 150 ns IBOOT = 100 µA 0.45 0.7 0.85 V IBOOT = 100 mA 2 2.3 3.1 V 11 15 25 Ω Supply rising 8 8.3 8.6 V Supply falling 7.8 8 8.25 V Rising to falling threshold 295 330 360 mV 5 10 13 µs Minimum input pulse width on INHx, INLx that changes the output on GHx, GLx BOOTSTRAP DIODES(DRV8300UD, DRV8300UDI) VBOOTD Bootstrap diode forward voltage RBOOTD Bootstrap dynamic resistance (ΔVBOOTD/ΔIBOOT) IBOOT = 100 mA and 80 mA PROTECTION CIRCUITS VGVDDUV Gate Driver Supply undervoltage lockout (GVDDUV) VGVDDUV_HYS Gate Driver Supply UV hysteresis tGVDDUV 8 Gate Driver Supply undervoltage deglitch time Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: DRV8300U DRV8300U www.ti.com SLVSGY3A – JULY 2022 – REVISED OCTOBER 2022 8.7 V ≤ VGVDD ≤ 20 V, –40°C ≤ TJ ≤ 150°C (unless otherwise noted) PARAMETER MIN TYP MAX Supply rising 7.5 8 8.7 V Boot Strap undervoltage lockout (VBSTx - VSHx) Supply falling 6.9 7.6 8.4 V VBSTUV_HYS Bootstrap UV hysteresis Rising to falling threshold 250 400 850 mV tBSTUV Bootstrap undervoltage deglitch time 5.5 10 22 µs VBSTUV TEST CONDITIONS Boot Strap undervoltage lockout (VBSTx - VSHx) UNIT 7.6 Timing Diagrams INHx/INLx 50% 50% GHx/GLx tPD tPD Figure 7-1. Propagation Delay(tPD) INHx INLx GHx GLx tPD_match tPD_match Figure 7-2. Propagation Delay Match (tPD_match) 7.7 Typical Characteristics 1150 1150 1100 1100 1050 Active Current (uA) Active Current (uA) 1050 1000 950 900 850 TJ = -40C TJ = 25C TJ = 150C 800 750 4 6 8 10 12 14 GVDD Voltage (V) 16 18 20 Figure 7-3. Supply Current Over GVDD Voltage 1000 VGVDD = 5 V VGVDD = 12 V VGVDD = 20 V 950 900 850 800 750 700 -40 -20 0 20 40 60 80 100 Junction Temperature (C) 120 140 160 Figure 7-4. Supply Current Over Temperature Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: DRV8300U 9 DRV8300U www.ti.com SLVSGY3A – JULY 2022 – REVISED OCTOBER 2022 Figure 7-5. Bootstrap Resistance Over GVDD Voltage 10 Figure 7-6. Bootstrap Diode Forward Voltage over GVDD Voltage Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: DRV8300U DRV8300U www.ti.com SLVSGY3A – JULY 2022 – REVISED OCTOBER 2022 8 Detailed Description 8.1 Overview The DRV8300U family of devices is a gate driver for three-phase motor drive applications. These devices decrease system component count, saves PCB space and cost by integrating three independent half-bridge gate drivers and optional bootstrap diodes. DRV8300U supports external N-channel high-side and low-side power MOSFETs and can drive 750-mA source, 1.5-A sink peak currents with total combined 30-mA average output current. The DRV8300U family of devices are available in 0.5-mm pitch QFN and 0.65-mm pitch TSSOP surface-mount packages. The QFN size is 4 × 4 mm (0.5-mm pin pitch) for the 24-pin package, and TSSOP body size is 6.5 × 4.4 mm (0.65-mm pin pitch) for the 20-pin package. Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: DRV8300U 11 DRV8300U www.ti.com SLVSGY3A – JULY 2022 – REVISED OCTOBER 2022 8.2 Functional Block Diagram GVDD CGVDD PVDD GVDD INHA HS INT_5V BSTA HS GHA CBSTA RGHA SHA GVDD INLA/INLA LS LS RGLA GLA MODE** Gate Driver GVDD BSTB PVDD CBSTB HS INHB INT_5V Input logic control HS MODE** SHB LS LS GLB RGLB Gate Driver GVDD INHC RGHB GVDD INLB/INLB ShootThrough Prevention GHB HS INT_5V PVDD BSTC HS GHC CBSTC RGHC SHC GVDD INLC/INLC LS LS GLC RGLC MODE** DT** Gate Driver MODE** GND PowerPAD ** QFN-24 Package Figure 8-1. Block Diagram for DRV8300UD 12 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: DRV8300U DRV8300U www.ti.com SLVSGY3A – JULY 2022 – REVISED OCTOBER 2022 8.3 Feature Description 8.3.1 Three BLDC Gate Drivers The DRV8300U integrates three half-bridge gate drivers, each capable of driving high-side and low-side Nchannel power MOSFETs. Input on GVDD provides the gate bias voltage for the low-side MOSFETs. The high voltage is generated using bootstrap capacitor and GVDD supply. The half-bridge gate drivers can be used in combination to drive a three-phase motor or separately to drive other types of loads. 8.3.1.1 Gate Drive Timings 8.3.1.1.1 Propagation Delay The propagation delay time (tpd) is measured as the time between an input logic edge to a detected output change. This time has two parts consisting of the input deglitcher delay and the delay through the analog gate drivers. The input deglitcher prevents high-frequency noise on the input pins from affecting the output state of the gate drivers. The analog gate drivers have a small delay that contributes to the overall propagation delay of the device. 8.3.1.1.2 Deadtime and Cross-Conduction Prevention In the DRV8300U, high-side and low-side inputs operate independently, with an exception to prevent cross conduction when high and low side are turned ON at same time. The DRV8300U turns OFF high-side and low-side output to prevent shoot through when the both high-side and low-side inputs are at logic HIGH at same time. The DRV8300U also provides option to insert additional deadtime to prevent the external high-side and low-side MOSFET from switching on at the same time. In the devices with DT pin (QFN package), deadtime can be linearly adjusted between 200 ns to 2000 ns by configuring resistor value between DT and GND. When the DT pin is left floating, fixed deadtime of 200 nS (typical value) is inserted. The value of resistor can be calculated using Equation 1. 4&6 (GÀ) = &A=@PEIA (J5) 5 (1) In the devices without DT pin (TSSOP package), fixed deadtime of 200 ns (typical value) is inserted to prevent high and low side gate output turning ON at same time. INHx/INLx Inputs INHx INLx GHx/GLx outputs GHx GLx DT DT Cross Conduction Prevention Figure 8-2. Cross Conduction Prevention and Deadtime Insertion Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: DRV8300U 13 DRV8300U www.ti.com SLVSGY3A – JULY 2022 – REVISED OCTOBER 2022 8.3.1.2 Mode (Inverting and non inverting INLx) The DRV8300U has flexibility of accepting different kind of inputs on INLx. In the devices with MODE pin (QFN package), the DRV8300U provides option of configuring the GLx outputs to be inverted or non-inverted compared to polarity of signal on INLx pins. When the MODE pin is left floating, the INLx is configured to be in non-inverting mode and GLx output is in phase with respect to INLx (see Figure 8-3), whereas when the MODE pin is connected to GVDD, GLx output is out of phase with respect to INLx (see Figure 8-4). In devices without MODE pin (TSSOP package device), there are different device option available for inverting and non inverting inputs (see Section 5). INHx INLx GHx GLx DT DT DT Figure 8-3. Non-Inverted INLx inputs INHx INLx GHx GLx DT DT DT Figure 8-4. Inverted INLx inputs 14 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: DRV8300U DRV8300U www.ti.com SLVSGY3A – JULY 2022 – REVISED OCTOBER 2022 8.3.2 Pin Diagrams Figure 8-5 shows the input structure for the logic level pins INHx, INLx. INHx and non-inverted INLx has passive pull down, so when inputs are floating the output the gate driver will be pulled low. Figure 8-6 shows the input structure for the inverted INLx pins. The inverted INLx has passive pull up, so when inputs are floating the output of the low-side gate driver will be pulled low. INT_5V INPUT INPUT 200 k Logic High Logic High INHx INLx INLx Logic Low Logic Low 200 k Figure 8-5. INHx and non-inverted INLx Logic-Level Input Pin Structure Figure 8-6. Inverted INLx Logic-Level Input Pin Structure 8.3.3 Gate Driver Protective Circuits The DRV8300U is protected against BSTx undervoltage and GVDD undervoltage events. Table 8-1. Fault Action and Response FAULT CONDITION GATE DRIVER RECOVERY VBSTx undervoltage (BSTUV) VBSTx < VBSTUV GHx - Hi-Z Automatic: VBSTx > VBSTUV and low to high PWM edge detected on INHx pin GVDD undervoltage (GVDDUV) VGVDD < VGVDDUV Hi-Z Automatic: VGVDD > VGVDDUV 8.3.3.1 VBSTx Undervoltage Lockout (BSTUV) The DRV8300U has separate voltage comparator to detect undervoltage condition for each phases. If at any time the voltage on the BSTx pin falls lower than the VBSTUV threshold, high side external MOSFETs of that particular phase is disabled by disabling (Hi-Z) GHx pin. Normal operation starts again when the BSTUV condition clears and low to high PWM edge is detected on INHx input of the same phase that BSTUV condition was detected. BSTUV protection ensures that high-side MOSFETs are not driven when the BSTx pins has lower value. 8.3.3.2 GVDD Undervoltage Lockout (GVDDUV) If at any time the voltage on the GVDD pin falls lower than the VGVDDUV threshold voltage, all of the external MOSFETs are disabled. Normal operation starts again when the GVDDUV condition clears. GVDDUV protection ensures that external MOSFETs are not driven when the GVDD input is at lower value. 8.4 Device Functional Modes The DRV8300U is in operating (active) mode, whenever the GVDD and BST pins are higher than the UV threshold (GVDD > VGVDDUVand VBSTX > VBSTUV). In active mode, the gate driver output GHx and GLX will follow respective inputs INHx and INLx. Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: DRV8300U 15 DRV8300U www.ti.com SLVSGY3A – JULY 2022 – REVISED OCTOBER 2022 9 Application and Implementation Note Information in the following applications sections is not part of the TI component specification, and TI does not warrant its accuracy or completeness. TI’s customers are responsible for determining suitability of components for their purposes. Customers should validate and test their design implementation to confirm system functionality. 9.1 Application Information The DRV8300U family of devices is primarily used in applications for three-phase brushless DC motor control. The design procedures in the Section 9.2 section highlight how to use and configure the DRV8300U. 16 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: DRV8300U DRV8300U www.ti.com SLVSGY3A – JULY 2022 – REVISED OCTOBER 2022 9.2 Typical Application GVDD GVDD CGVDD PVDD GND External Supply GND BSTA CBSTA RGHA GHA SHA RGLA INHA GLA INLA INHB PWM MCU INLB PVDD BSTB INHC INLC CBSTB RGHB GHB ADC SHB RGLB DRV8300D GLB GVDD MODE** PVDD BSTC BSTC CBSTC RGHC GHC GND or Floating GHC SHC SHC RDT DT** RGLC GLC ** QFN-24 Package GLC RSENSE INC+ RSENSE R INB+ RSENSE INA+ INA- INB- INC- R R R OUT ± OUT OUT Reference Voltage ± + VREF VREF IN- INx+ IN-IN+ RR IN-IN+ R IN+ INx- R R VREF R ± + R + R R R + Current Sense Amplifier 1x or 3x ± Figure 9-1. Application Schematic Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: DRV8300U 17 DRV8300U www.ti.com SLVSGY3A – JULY 2022 – REVISED OCTOBER 2022 9.2.1 Design Requirements Table 9-1 lists the example design input parameters for system design. Table 9-1. Design Parameters EXAMPLE DESIGN PARAMETER MOSFET Gate Supply Voltage Gate Charge REFERENCE EXAMPLE VALUE - CSD19532Q5B VGVDD 12 V QG 48 nC 9.2.2 Bootstrap Capacitor and GVDD Capacitor Selection The bootstrap capacitor must be sized to maintain the bootstrap voltage above the undervoltage lockout for normal operation. Equation 2 calculates the maximum allowable voltage drop across the bootstrap capacitor: ¿8$56: = 8)8&& F 8$116& F 8$5678 (2) =12 V – 0.85 V – 4.5 V = 6.65 V where • VGVDD is the supply voltage of the gate drive • VBOOTD is the forward voltage drop of the bootstrap diode • VBSTUV is the threshold of the bootstrap undervoltage lockout In this example the allowed voltage drop across bootstrap capacitor is 6.65 V. It is generally recommended that ripple voltage on both the bootstrap capacitor and GVDD capacitor should be minimized as much as possible. Many of commercial, industrial, and automotive applications use ripple value between 0.5 V to 1 V. The total charge needed per switching cycle can be estimated with Equation 3: 3616 = 3) + +.$5_64#05 B59 (3) =48 nC + 220 μA/20 kHz = 50 nC + 11 nC = 59 nC where • QG is the total MOSFET gate charge • ILBS_TRAN is the bootstrap pin leakage current • fSW is the is the PWM frequency The minimum bootstrap capacitor an then be estimated as below assuming 1V ΔVBSTx: %$56_/+0 = 3616W¿8 (4) $56: = 59 nC / 1 V = 59 nF The calculated value of minimum bootstrap capacitor is 59 nF. It should be noted that, this value of capacitance is needed at full bias voltage. In practice, the value of the bootstrap capacitor must be greater than calculated value to allow for situations where the power stage may skip pulse due to various transient conditions. It is recommended to use a 100 nF bootstrap capacitor in this example. It is also recommenced to include enough margin and place the bootstrap capacitor as close to the BSTx and SHx pins as possible. %)8&& R 10 × %$56: (5) = 10*100 nF= 1 μF 18 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: DRV8300U DRV8300U www.ti.com SLVSGY3A – JULY 2022 – REVISED OCTOBER 2022 For this example application choose 1 µF CGVDD capacitor. Choose a capacitor with a voltage rating at least twice the maximum voltage that it will be exposed to because most ceramic capacitors lose significant capacitance when biased. This value also improves the long term reliability of the system. 9.2.3 Application Curves GHA GHA SHA SHA GLA GLA Figure 9-2. Gate voltages, SHx rising with 15 ohm gate resistor and CSD19532Q5B MOSFET Figure 9-3. Gate voltages, SHx falling with 15 ohm gate resistor and CSD19532Q5B MOSFET Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: DRV8300U 19 DRV8300U www.ti.com SLVSGY3A – JULY 2022 – REVISED OCTOBER 2022 10 Power Supply Recommendations The DRV8300U is designed to operate from an input voltage supply (GVDD) range from 4.8 V to 20 V. A local bypass capacitor should be placed between the GVDD and GND pins. This capacitor should be located as close to the device as possible. A low ESR, ceramic surface mount capacitor is recommended. It is recommended to use two capacitors across GVDD and GND: a low capacitance ceramic surface-mount capacitor for high frequency filtering placed very close to GVDD and GND pin, and another high capacitance value surfacemount capacitor for device bias requirements. In a similar manner, the current pulses delivered by the GHx pins are sourced from the BSTx pins. Therefore, capacitor across the BSTx to SHx is recommended, it should be high enough capacitance value capacitor to deliver GHx pulses 20 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: DRV8300U DRV8300U www.ti.com SLVSGY3A – JULY 2022 – REVISED OCTOBER 2022 11 Layout 11.1 Layout Guidelines • • • • • • • • Low ESR/ESL capacitors must be connected close to the device between GVDD and GND and between BSTx and SHx pins to support high peak currents drawn from GVDD and BSTx pins during the turn-on of the external MOSFETs. To prevent large voltage transients at the drain of the top MOSFET, a low ESR electrolytic capacitor and a good quality ceramic capacitor must be connected between the high side MOSFET drain and ground. In order to avoid large negative transients on the switch node (SHx) pin, the parasitic inductances between the source of the high-side MOSFET and the source of the low-side MOSFET must be minimized. In order to avoid unexpected transients, the parasitic inductance of the GHx, SHx, and GLx connections must be minimized. Minimize the trace length and number of vias wherever possible. Minimum 10 mil and typical 15 mil trace width is recommended. Resistance between DT and GND must be place as close as possible to device Place the gate driver as close to the MOSFETs as possible. Confine the high peak currents that charge and discharge the MOSFET gates to a minimal physical area by reducing trace length. This confinement decreases the loop inductance and minimize noise issues on the gate terminals of the MOSFETs. In QFN package device variants, NC pins can be connected to GND to increase ground conenction between thermal pad and external ground plane. Refer to sections General Routing Techniques and MOSFET Placement and Power Stage Routing in Application Report 11.2 Layout Example DT resistor close to device BSTx capacitor close to device GVDD capacitor close to device Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: DRV8300U 21 DRV8300U www.ti.com SLVSGY3A – JULY 2022 – REVISED OCTOBER 2022 12 Device and Documentation Support 12.1 Receiving Notification of Documentation Updates To receive notification of documentation updates, navigate to the device product folder on ti.com. Click on Subscribe to updates to register and receive a weekly digest of any product information that has changed. For change details, review the revision history included in any revised document. 12.2 Support Resources TI E2E™ support forums are an engineer's go-to source for fast, verified answers and design help — straight from the experts. Search existing answers or ask your own question to get the quick design help you need. Linked content is provided "AS IS" by the respective contributors. They do not constitute TI specifications and do not necessarily reflect TI's views; see TI's Terms of Use. 12.3 Trademarks TI E2E™ is a trademark of Texas Instruments. All trademarks are the property of their respective owners. 12.4 Electrostatic Discharge Caution This integrated circuit can be damaged by ESD. Texas Instruments recommends that all integrated circuits be handled with appropriate precautions. Failure to observe proper handling and installation procedures can cause damage. ESD damage can range from subtle performance degradation to complete device failure. Precision integrated circuits may be more susceptible to damage because very small parametric changes could cause the device not to meet its published specifications. 12.5 Glossary TI Glossary This glossary lists and explains terms, acronyms, and definitions. 13 Mechanical, Packaging, and Orderable Information The following pages include mechanical, packaging, and orderable information. This information is the most current data available for the designated devices. This data is subject to change without notice and revision of this document. For browser-based versions of this data sheet, refer to the left-hand navigation. 22 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: DRV8300U PACKAGE OPTION ADDENDUM www.ti.com 2-Nov-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) Samples (4/5) (6) DRV8300UDIPWR ACTIVE TSSOP PW 20 3000 RoHS & Green NIPDAU Level-2-260C-1 YEAR -40 to 125 8300UDI Samples DRV8300UDPWR ACTIVE TSSOP PW 20 3000 RoHS & Green NIPDAU Level-2-260C-1 YEAR -40 to 125 8300UD Samples DRV8300UDRGER ACTIVE VQFN RGE 24 3000 RoHS & Green NIPDAU Level-1-260C-UNLIM -40 to 125 8300UD Samples (1) The marketing status values are defined as follows: ACTIVE: Product device recommended for new designs. LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect. NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design. PREVIEW: Device has been announced but is not in production. Samples may or may not be available. OBSOLETE: TI has discontinued the production of the device. (2) RoHS: TI defines "RoHS" to mean semiconductor products that are compliant with the current EU RoHS requirements for all 10 RoHS substances, including the requirement that RoHS substance do not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, "RoHS" products are suitable for use in specified lead-free processes. TI may reference these types of products as "Pb-Free". RoHS Exempt: TI defines "RoHS Exempt" to mean products that contain lead but are compliant with EU RoHS pursuant to a specific EU RoHS exemption. Green: TI defines "Green" to mean the content of Chlorine (Cl) and Bromine (Br) based flame retardants meet JS709B low halogen requirements of