DRV8834PWP

Product Folder Sample & Buy Support & Community Tools & Software Technical Documents DRV8834 SLVSB19D – FEBRUARY 2012 – REVISED MARCH 2015 DRV8834 Dual-Bridge Stepper or DC Motor Driver 1 Features 3 Description • The DRV8834 provides a flexible motor driver solution for toys, printers, cameras, and other mechatronic applications. The device has two Hbridge drivers, and is intended to drive a bipolar stepper motor or two DC motors. 1 • • • • • • • Dual-H-Bridge Current-Control Motor Driver – Capable of Driving Two DC Motors or One Stepper Motor Two Control Modes: – Built-In Indexer Logic With Simple STEP/DIRECTION Control and Up to 1/32-Step Microstepping – PHASE/ENABLE Control, With the Ability to Drive External References for > 1/32-Step Microstepping Output Current 1.5-A Continuous, 2.2-A Peak per H-Bridge (at VM = 5 V, 25°C) Low RDS(ON): 305-mΩ HS + LS (at VM = 5 V, 25°C) Wide Power Supply Voltage Range: 2.5 V to 10.8 V Dynamic tBLANK and Mixed Decay Modes for Smooth Microstepping PWM Winding Current Regulation and Limiting Thermally Enhanced Surface-Mount Package 2 Applications • • • • • • Battery-Powered Toys POS Printers Video Security Cameras Office Automation Machines Gaming Machines Robotics The output driver block of each H-bridge consists of N-channel power MOSFETs configured as an Hbridge to drive the motor windings. Each H-bridge includes circuitry to regulate or limit the winding current. With proper PCB design, each H-bridge of the DRV8834 can driving up to 1.5-A RMS (or DC) continuously, at 25°C with a VM supply of 5 V. The device can support peak currents of up to 2.2 A per bridge. Current capability is reduced slightly at lower VM voltages. Internal shutdown functions with a fault output pin are provided for overcurrent protection, short-circuit protection, undervoltage lockout and overtemperature. A low-power sleep mode is also provided. The DRV8834 is packaged in a 24-pin HTSSOP or VQFN package with PowerPAD™ (Eco-friendly: RoHS & no Sb/Br). Device Information(1) PART NUMBER DRV8834 PACKAGE BODY SIZE (NOM) HTSSOP (24) 7.80 mm × 4.40 mm VQFN (24) 4.00 mm × 4.00 mm (1) For all available packages, see the orderable addendum at the end of the data sheet. 4 Simplified Schematic 2.5 V to 10.8 V DIR Decay Mode Step Size nFAULT Stepper Motor Driver 1/32 µstep 1.5 A M - Controller DRV8834 + STEP + - 1.5 A 1 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. DRV8834 SLVSB19D – FEBRUARY 2012 – REVISED MARCH 2015 www.ti.com Table of Contents 1 2 3 4 5 6 7 8 Features .................................................................. Applications ........................................................... Description ............................................................. Simplified Schematic............................................. Revision History..................................................... Pin Configuration and Functions ......................... Specifications......................................................... 1 1 1 1 2 3 5 7.1 7.2 7.3 7.4 7.5 7.6 7.7 5 5 5 6 7 8 9 Absolute Maximum Ratings ...................................... ESD Ratings ............................................................ Recommended Operating Conditions....................... Thermal Information ................................................. Electrical Characteristics........................................... Timing Requirements ................................................ Typical Characteristics .............................................. Detailed Description ............................................ 10 8.1 Overview ................................................................. 10 8.2 Functional Block Diagram ....................................... 11 8.3 Feature Description................................................. 11 8.4 Device Functional Modes........................................ 15 9 Application and Implementation ........................ 20 9.1 Application Information............................................ 20 9.2 Typical Application .................................................. 20 10 Power Supply Recommendations ..................... 29 10.1 Bulk Capacitance .................................................. 29 11 Layout................................................................... 30 11.1 Layout Guidelines ................................................. 30 11.2 Layout Example .................................................... 30 11.3 Thermal Considerations ........................................ 30 12 Device and Documentation Support ................. 32 12.1 12.2 12.3 12.4 Documentation Support ....................................... Trademarks ........................................................... Electrostatic Discharge Caution ............................ Glossary ................................................................ 32 32 32 32 13 Mechanical, Packaging, and Orderable Information ........................................................... 32 5 Revision History Changes from Revision C (June 2013) to Revision D Page • Added ESD Ratings table, Features Description section, Device Functional Modes, Application and Implementation section, Power Supply Recommendations section, Layout section, Device and Documentation Support section, and Mechanical, Packaging, and Orderable Information section .................................................................................................. 1 • Deleted Ordering Information table. ....................................................................................................................................... 3 2 Submit Documentation Feedback Copyright © 2012–2015, Texas Instruments Incorporated Product Folder Links: DRV8834 DRV8834 www.ti.com SLVSB19D – FEBRUARY 2012 – REVISED MARCH 2015 6 Pin Configuration and Functions PWP Package 24-Pin HTSSOP Top View RGE Package 24-Pin VQFN Top View BOUT1 9 16 nFAULT nENBL / AENBL 10 15 CONFIG STEP / BENBL 11 14 M1 DIR / BPHASE 12 13 M0 / APHASE 19 VCP 20 17 18 GND AISEN 2 17 VINT AOUT 2 3 16 VM BOUT 2 4 15 VM BISEN 5 14 VCP BOUT 1 6 13 nFAULT GND (PPAD) 12 8 1 11 BISEN AOUT 1 M1 VM C O N FIG 18 21 7 M0 / APHASE VM BOUT2 22 19 GND (PPAD) 10 6 23 VINT AOUT2 9 20 D IR / B P H A S E 5 24 GND AISEN 8 21 S TE P / B E N B L 4 7 AVREF AOUT1 nE N B L / A E N B L 22 BVREF 3 AVREF BVREF ADECAY V R E FO VREFO 23 nS LE E P 24 2 ADECAY 1 BDECAY nSLEEP BDECAY Pin Functions PIN NAME HTSSOP VQFN I/O DESCRIPTION EXTERNAL COMPONENTS OR CONNECTIONS POWER AND GROUND GND 21, PPAD 18, PPAD — Device ground Both the GND pin and device PowerPAD must be connected to ground VM 18, 19 15, 16 — Bridge A power supply Connect to motor supply. A 10-µF (minimum) capacitor to GND is recommended. VINT 20 17 — Internal supply Bypass to GND with 2.2-μF (minimum), 6.3-V capacitor. Can be used to provide logic high voltage for configuration pins (except nSLEEP). VREFO 24 21 O Reference voltage output May be connected to AVREF/BVREF inputs. Do not place a bypass capacitor on this pin. VCP 17 14 O High-side gate drive voltage Connect a 0.01-μF, 16-V (minimum) X7R ceramic capacitor to VM. CONTROL (INDEXER MODE OR PHASE/ENABLE MODE) nENBL/AENBL 10 7 I Step motor enable/Bridge A enable Indexer mode: Logic low enables all outputs. Phase/enable mode: Logic high enables the AOUTx outputs. Internal pulldown. STEP/BENBL 11 8 I Step input/Bridge B enable Indexer mode: Rising edge moves indexer to next step. Phase/enable mode: Logic high enables the BOUTx outputs. Internal pulldown. DIR/BPHASE 12 9 I Direction input/Bridge B Phase Indexer mode: Level sets direction of step. Phase/enable mode: Logic high sets BOUT1 high, BOUT2 low. Internal pulldown. Submit Documentation Feedback Copyright © 2012–2015, Texas Instruments Incorporated Product Folder Links: DRV8834 3 DRV8834 SLVSB19D – FEBRUARY 2012 – REVISED MARCH 2015 www.ti.com Pin Functions (continued) PIN NAME M0/APHASE M1 HTSSOP 13 14 VQFN 10 11 I/O I I EXTERNAL COMPONENTS OR CONNECTIONS DESCRIPTION Microstep mode/Bridge A phase Indexer mode: Controls microstep mode (full, half, up to 1/32-step) along with M1. Phase/enable mode: Logic high sets AOUT1 high, AOUT2 low. Internal pulldown. Microstep mode/Disable state Indexer mode: Controls microstep mode (full, half, up to 1/32-step) along with M0. Phase/enable mode: Determines the state of the outputs when xENBL = 0. Internal pulldown. CONFIG 15 12 I Device configuration Logic high to put the device in indexer mode. Logic low to put the device into phase/enable mode. State is latched at power up and sleep exit. Internal pulldown. nSLEEP 1 22 I Sleep mode input Logic high to enable device, logic low to enter low-power sleep mode and reset all internal logic. Bridge A current set reference input Reference voltage for AOUT winding current. In Indexer Mode, it should be tied to a reference voltage for the internal DAC (for example, VREFO). In Phase/Enable Mode, an external DAC can drive it for microstepping. AVREF 22 19 I BVREF 23 20 I Bridge B current set reference input Reference voltage for BOUT winding current. In Indexer Mode, it should be tied to a reference voltage for the internal DAC (for example, VREFO). In Phase/Enable Mode, an external DAC can drive it for microstepping. ADECAY 3 24 I Decay mode for bridge A Determines decay mode for H-Bridge A (or A and B in indexer mode) – slow, fast or mixed decay BDECAY 2 23 I Decay mode for bridge B Determines decay mode for H-Bridge B – slow, fast or mixed decay 16 13 OD Fault output Logic low when in fault condition (overtemp, overcurrent, undervoltage) AISEN 5 2 IO Bridge A ground/Isense Connect to current sense resistor for bridge A, or GND if current control not needed BISEN 8 5 IO Bridge B ground/Isense Connect to current sense resistor for bridge B, or GND if current control not needed AOUT1 4 1 O Bridge A output 1 AOUT2 6 3 O Bridge A output 2 BOUT1 9 6 O Bridge B output 1 BOUT2 7 4 O Bridge B output 2 STATUS nFAULT OUTPUT 4 Submit Documentation Feedback Connect to motor winding A Connect to motor winding B Copyright © 2012–2015, Texas Instruments Incorporated Product Folder Links: DRV8834 DRV8834 www.ti.com SLVSB19D – FEBRUARY 2012 – REVISED MARCH 2015 7 Specifications 7.1 Absolute Maximum Ratings over operating free-air temperature range (unless otherwise noted) (1) (2) VM MIN MAX UNIT –0.3 11.8 V –0.5 3.6 V Digital input pin voltage –0.5 7 V xISEN pin voltage –0.3 0.5 V Power supply voltage AVREF, BVREF, VINT, Analog input pin voltage ADECAY , BDECAY Peak motor drive output current, t < 1 µs Internally limited A TJ Operating virtual junction temperature –40 150 °C Tstg Storage temperature –60 150 °C (1) (2) Stresses beyond those listed under absolute maximum ratings may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated under recommended operating conditions is not implied. Exposure to absolute–maximum–rated conditions for extended periods may affect device reliability. All voltage values are with respect to network ground terminal. 7.2 ESD Ratings VALUE Human body model (HBM), per ANSI/ESDA/JEDEC JS-001, all pins V(ESD) (1) (2) Electrostatic discharge (1) Charged device model (CDM), per JEDEC specification JESD22-C101, all pins (2) UNIT ±4000 V ±1500 JEDEC document JEP155 states that 500-V HBM allows safe manufacturing with a standard ESD control process. JEDEC document JEP157 states that 250-V CDM allows safe manufacturing with a standard ESD control process. 7.3 Recommended Operating Conditions TA = 25°C, over operating free-air temperature range (unless otherwise noted) MIN (1) VM Motor power supply voltage range VREF VREF input voltage range (2) IVINT VINT external load current IVREF VREF external load current VDIGIN Digital input pin voltage range IOUT Continuous RMS or DC output current per bridge (3) (1) (2) (3) MAX UNIT 2.5 10.8 V 1 2.1 –0.3 NOM V 1 mA 400 µA 5.75 V 1.5 A RDS(ON) increases and maximum output current is reduced at VM supply voltages below 5 V. Operational at VREF between 0 V and 1 V, but accuracy is degraded. Power dissipation and thermal limits must be observed. Submit Documentation Feedback Copyright © 2012–2015, Texas Instruments Incorporated Product Folder Links: DRV8834 5 DRV8834 SLVSB19D – FEBRUARY 2012 – REVISED MARCH 2015 www.ti.com 7.4 Thermal Information DRV8834 THERMAL METRIC (1) PWP [HTSSOP] RGE [VQFN] 24 PINS 24 PINS RθJA Junction-to-ambient thermal resistance 40.2 35.1 RθJC(top) Junction-to-case (top) thermal resistance 23.7 36.6 RθJB Junction-to-board thermal resistance 21.9 12.2 ψJT Junction-to-top characterization parameter 0.7 0.6 ψJB Junction-to-board characterization parameter 21.7 12.2 RθJC(bot) Junction-to-case (bottom) thermal resistance 3.9 4 (1) 6 UNIT °C/W For more information about traditional and new thermal metrics, see the IC Package Thermal Metrics application report, SPRA953. Submit Documentation Feedback Copyright © 2012–2015, Texas Instruments Incorporated Product Folder Links: DRV8834 DRV8834 www.ti.com SLVSB19D – FEBRUARY 2012 – REVISED MARCH 2015 7.5 Electrical Characteristics TA = 25°C, over operating free-air temperature range (unless otherwise noted) PARAMETER TEST CONDITIONS MIN TYP MAX VM = 5 V, excluding winding current 2.4 4 VM = 10 V, excluding winding current 2.75 UNIT POWER SUPPLY IVM VM operating supply current IVMQ VM sleep mode supply current VUVLO VM undervoltage lockout voltage VM = 5 V 0.6 VM = 10 V 9.6 VM falling 2 mA μA 2.39 V INTERNAL REGULATORS VINT VINT voltage VM > 3.3 V, IOUT = 0 A to 1 mA VREFO VREF voltage IOUT = 0 A to 400 µA 2.85 3 3.15 V 1.9 2 2.1 V LOGIC-LEVEL INPUTS VIL Input low voltage VIH Input high voltage VHYS Input hysteresis RPD Input pulldown resistance IIL Input low current IIN Input current (M0) IIH Input high current tDEG Input deglitch time nSLEEP 0.5 All other digital input pins 0.7 nSLEEP 2.5 All other digital input pins V 2 nSLEEP 0.2 All except nSLEEP 0.4 nSLEEP 500 All except nSLEEP, M0 200 VIN = 0 -20 VIN = 3.3 V, nSLEEP VIN = 3.3 V, all except nSLEEP V V kΩ 1 μA 20 µA 6.6 13 16.5 33 312 468 μA ns nFAULT OUTPUT (OPEN-DRAIN OUTPUT) VOL Output low voltage IO = 5 mA IOH Output high leakage current VO = 3.3 V 0.5 V 1 μA H-BRIDGE FETs VM = 5 V, I HS FET ON-resistance RDS(ON) LS FET ON-resistance = 500 mA, TJ = 25°C 160 VM = 5 V, IO = 500 mA, TJ = 85°C 190 VM = 2.7 V, I O = 500 mA, TJ = 25°C 200 VM = 2.7 V, IO = 500 mA, TJ = 85°C 240 VM = 5 V, I = 500 mA, TJ = 25°C 145 VM = 5 V, IO = 500 mA, TJ = 85°C 180 VM = 2.7 V, I O = 500 mA, TJ = 25°C 190 O O VM = 2.7 V, IO = 500 mA, TJ = 85°C IOFF Off-state leakage current 250 295 240 mΩ 285 235 –2 2 μA MOTOR DRIVER fPWM Current control PWM frequency Internal PWM frequency 42.5 VREF > 375 mV or DAC codes > 29% 2.4 VREF < 375 mV or DAC codes < 29% 1.6 kHz tBLANK Current sense blanking time µs tR Rise time VM = 5 V, 16 Ω to GND, 10% to 90% VM 120 ns tF Fall time VM = 5 V, 16 Ω to GND, 10% to 90% VM 100 ns PROTECTION CIRCUITS IOCP Overcurrent protection trip level tOCP Overcurrent protection period 2 A VREF > 375 mV or DAC codes > 29% 1.6 VREF < 375 mV or DAC codes < 29% 1.1 Submit Documentation Feedback Copyright © 2012–2015, Texas Instruments Incorporated Product Folder Links: DRV8834 µs 7 DRV8834 SLVSB19D – FEBRUARY 2012 – REVISED MARCH 2015 www.ti.com Electrical Characteristics (continued) TA = 25°C, over operating free-air temperature range (unless otherwise noted) PARAMETER tTSD TEST CONDITIONS Thermal shutdown temperature Die temperature MIN TYP MAX UNIT 150 160 180 °C 1 µA CURRENT CONTROL IREF VREF input current VREF = 3.3 V –1 VTRIP xISEN trip voltage For 100% current step AISENSE Current sense amplifier gain Reference only xVREF/5 V 5 V/V 7.6 Timing Requirements TA = 25°C, over operating free-air temperature range (unless otherwise noted) NO. PARAMETER CONDITIONS MIN TYP MAX UNIT 250 kHz 1 fSTEP Step frequency 2 tWH(STEP) Pulse duration, STEP high 1.9 µs 3 tWL(STEP) Pulse duration, STEP low 1.9 µs 4 tSU(STEP) Setup time, command to STEP rising 200 ns 5 tH(STEP) Hold time, command to STEP rising 1 µs 6 tWAKE Wake-up time, nSLEEP inactive to STEP 1 ms 1 2 3 STEP DIR, M0, M1 4 5 nSLEEP 6 Figure 1. Timing Diagram 8 Submit Documentation Feedback Copyright © 2012–2015, Texas Instruments Incorporated Product Folder Links: DRV8834 DRV8834 www.ti.com SLVSB19D – FEBRUARY 2012 – REVISED MARCH 2015 7.7 Typical Characteristics 3.5 25.0 3.0 20.0 2.5 15.0 ±40ƒC 25°C IVMQ (uA) IVM (mA) 85°C 2.0 10.0 1.5 5.0 ±40ƒC 1.0 0.0 25°C 85°C 0.5 2.7 3.5 4.3 5.1 5.9 6.7 7.5 8.3 9.1 ±5.0 9.9 10.7 11.5 VVM (V) 2.7 3.6 4.5 5.4 6.3 7.2 8.1 9.0 9.9 10.8 VVM (V) C001 Figure 2. Operating Current C002 Figure 3. Sleep Current 700 600 RDS(ON) (HS + LS) (mŸ) RDS(ON) (HS + LS) (mŸ) ±40ƒC 600 500 400 300 2.7 V 200 5V 25°C 550 85°C 500 450 400 350 11.5 V 100 300 ±40 ±20 0 20 40 Temperature (ƒC) 60 80 2.7 C003 Figure 4. RDS(ON) 3.5 4.3 5.1 5.9 6.7 7.5 8.3 9.1 9.9 10.7 11.5 VVM (V) C004 Figure 5. RDS(ON) Submit Documentation Feedback Copyright © 2012–2015, Texas Instruments Incorporated Product Folder Links: DRV8834 9 DRV8834 SLVSB19D – FEBRUARY 2012 – REVISED MARCH 2015 www.ti.com 8 Detailed Description 8.1 Overview The DRV8834 supports two configurations: phase/enable mode, where the outputs are controlled by phase (direction) and enable signals for each H-bridge, and indexer mode, which allow control of a stepper motor using simple step and direction inputs. DC motors can only be controlled in phase/enable mode; indexer mode is not applicable to DC motors. Stepper motors can be controlled using either phase/enable load, or indexer mode. The device is configured to be controlled either way using CONFIG pin. Logic HIGH on the CONFIG pin puts the device in the STEP/DIR mode; logic LOW lets the motor to be controlled using the xPHASE/xENBL pins. The state of the CONFIG pin is latched at power up, and also whenever exiting sleep mode. CONFIG has an internal pulldown resistor. 10 Submit Documentation Feedback Copyright © 2012–2015, Texas Instruments Incorporated Product Folder Links: DRV8834 DRV8834 www.ti.com SLVSB19D – FEBRUARY 2012 – REVISED MARCH 2015 8.2 Functional Block Diagram VM VM + 0.01µF VM VM VM 10µF VCP VINT 2.2µF VREFO Internal Ref & Regs VINT, refs, Int. supp. Charge Pump VCP 0.01µF PUC, UVLO VM VREFO nENBL / AENBL AOUT1 STEP / BENBL Gate Drive & OCP DIR / BPHASE CONFIG DCM VM M0 / APHASE Step Motor AOUT2 M1 nSLEEP AISEN ISEN nFAULT VM Logic BOUT1 ADECAY Gate Drive & OCP BDECAY VREFO DCM VM OverTemp BOUT2 AVREF BVREF ISEN BISEN GND 8.3 Feature Description DRV8834 contains two identical H-bridge motor drivers with current-control PWM circuitry. A block diagram of the circuitry is shown in Figure 6: Submit Documentation Feedback Copyright © 2012–2015, Texas Instruments Incorporated Product Folder Links: DRV8834 11 DRV8834 SLVSB19D – FEBRUARY 2012 – REVISED MARCH 2015 www.ti.com Feature Description (continued) VM OCP VM VCP, VM xOUT1 Predrive Step Motor xOUT2 From Logic PWM OCP xISEN - *5 + xVREF Optional Comparator CONFIG DAC From Indexer 5 Figure 6. Motor Control Circuitry 8.3.1 Current Control The current through the motor windings may be regulated by a fixed-frequency PWM current regulation (current chopping). With stepping motors, current control is normally used at all times. Often it is used to vary the current in the two windings in a sinusoidal fashion to provide smooth motion. This is referred to as microstepping. The DRV8834 can provide up to 1/32 step microstepping, using internal 5-bit DACs. Finer microstepping can be implemented using the xPHASE/xENBL signals to control the stepper motor, and varying the xVREF voltages. The current flowing through the corresponding H-bridge varies according to the equation given below. A very high degree of microstepping can be achieved through this technique. With DC motors, current control can be used to limit the start-up current of the motor to less than the stall current of the motor. Current regulation works as follows: When an H-bridge is enabled, current rises through the winding at a rate dependent on the supply voltage and inductance of the winding. If the current reaches the current chopping threshold, the bridge disables the current until the beginning of the next PWM cycle. Immediately after the current is enabled, the voltage on the xISEN pin is ignored for a period of time before enabling the current sense circuitry. This blanking time also sets the minimum on time of the PWM when operating in current chopping mode. 12 Submit Documentation Feedback Copyright © 2012–2015, Texas Instruments Incorporated Product Folder Links: DRV8834 DRV8834 www.ti.com SLVSB19D – FEBRUARY 2012 – REVISED MARCH 2015 Feature Description (continued) The blanking time also sets the minimum PWM duty cycle. This can cause current control errors near the zero current level when microstepping. To help eliminate this error, the DRV8834 has a dynamic tBLANK time. When the commanded current is low, the blanking period is reduced, which in turn lowers the minimum duty cycle. This provides a smoother current transition across the zero crossing region of the current waveform. The end result is smoother and quieter motor operation. The PWM chopping current is set by a comparator which compares the voltage across a current sense resistor connected to the xISEN pins, with a reference voltage supplied to the AVREF and BVREF pins. In indexer mode, the reference voltages are scaled by internal DACs to provide scaled currents used to perform microstepping. The chopping current is calculated as follows: xVREF Full-Scale ITRIP = 5¾ · RISENSE (1) Example: If xVREF is 2 V (as it would be if xVREF is connected directly to VREFO) and a 400-mΩ sense resistor is used, the chopping current will be 2 V / 5 × 400 mΩ = 1 A. In indexer mode, this current value is scaled by between 5% and 100% by the internal DACs, as shown in the step table in the "Microstepping Indexer" section of the data sheet. If current control is not needed, the xISEN pins may be connected directly to ground. In this case, TI also recommends connecting AVREF and BVREF directly to VREFO. 8.3.2 Current Recirculation and Decay Modes During PWM current chopping, the H-bridge is enabled to drive current through the motor winding until the PWM current chopping threshold is reached. This is shown in Figure 7 as case 1. The current flow direction shown indicates positive current flow in the step table below for indexer mode, or the current flow with xPHASE = 1 in phase/enable mode. Once the chopping current threshold is reached, the drive current is interrupted, but due to the inductive nature of the motor, the current must continue to flow. This is called recirculation current. To handle this recirculation current, the H-bridge can operate in two different states, fast decay or slow decay. In fast decay mode, once the PWM chopping current level has been reached, the H-bridge reverses state to allow winding current to flow in through the opposing FETs. As the winding current approaches zero, the bridge is disabled to prevent any reverse current flow. Fast decay mode is shown in Figure 7 as case 2. In slow decay mode, winding current is recirculated by enabling both of the low-side FETs in the bridge. Slow decay is shown as case 3 in Figure 7. xVM 1 Drive Current 1 2 Fast decay xOUT2 xOUT1 3 Slow decay 2 3 Figure 7. Decay Modes Submit Documentation Feedback Copyright © 2012–2015, Texas Instruments Incorporated Product Folder Links: DRV8834 13 DRV8834 SLVSB19D – FEBRUARY 2012 – REVISED MARCH 2015 www.ti.com Feature Description (continued) The DRV8834 supports fast, slow, and also mixed decay modes. With DC motors, slow decay is nearly always used to minimize current ripple and optimize speed control; with stepper motors, the decay mode is chosen for a given stepper motor and operating conditions to minimize mechanical noise and vibration. In mixed decay mode, the current recirculation begins as fast decay, but at a fixed period of time (determined by the state of the xDECAY pins shown in Table 1) switches to slow decay mode for the remainder of the fixed PWM period. Table 1. Decay Pin Configuration RESISTANCE ON xDECAY PIN -OR- VOLTAGE FORCED ON xDECAY PIN < 1 kΩ < 0.1 V % OF PWM CYCLE IS FAST DECAY 0% 20 kΩ ±5% 0.2 V ±5% 25% 50% 50 kΩ ±5% 0.5 V ±5% 100 kΩ ±5% 1 V ±5% 75% > 200 kΩ >2V 100% Figure 8 shows the current waveforms in slow, 25% mixed, and fast decay modes. I ITRIP Slow 25% Mixed Fast 0mA 25% PWM on 50% 75% 100% t PWM off (tOFF) PWM cycle Figure 8. Current Decay Modes Decay mode is selected by the voltage present on the xDECAY pins. Internal current sources of 10 µA (typical) are connected to the pins, which allows setting of the decay mode by a resistor connected to ground if desired. It is possible to drive the xDECAY pin with a tristate GPIO pin and also place the resistor to ground. This allows a microcontroller to select fast, slow, or mixed decay modes by driving the pin high, low, or high-impedance. The logic-low voltage must be less than 0.1 V with 10-µA of current sourced from the DRV8834 to attain slow decay. In indexer mode, only the ADECAY pin is used, and slow decay mode is always used when at any point in the step table where the current is increasing. When current is decreasing or remaining constant, the decay mode used will be fast, slow, or mixed, as commanded by the ADECAY pin. 8.3.3 Protection Circuits The DRV8834 is fully protected against undervoltage, overcurrent and overtemperature events. 14 Submit Documentation Feedback Copyright © 2012–2015, Texas Instruments Incorporated Product Folder Links: DRV8834 DRV8834 www.ti.com SLVSB19D – FEBRUARY 2012 – REVISED MARCH 2015 8.3.3.1 Overcurrent Protection (OCP) An analog current limit circuit on each FET limits the current through the FET by limiting the gate drive. If this analog current limit persists for longer than the OCP deglitch time (tOCP), all FETs in the H-bridge are disabled and the nFAULT pin are driven low. The driver will be re-enabled after the OCP retry period (approximately 1.2 ms) has passed. nFAULT becomes high again at this time. If the fault condition is still present, the cycle repeats. If the fault is no longer present, normal operation resumes and nFAULT remains deasserted. Only the H-bridge in which the OCP is detected will be disabled while the other bridge will function normally. Overcurrent conditions are detected independently on both high-side and low-side devices; that is, a short to ground, supply, or across the motor winding will all result in an overcurrent shutdown. Overcurrent protection does not use the current sense circuitry used for PWM current control, so functions even without presence of the xISEN resistors. 8.3.3.2 Thermal Shutdown (TSD) If the die temperature exceeds safe limits, all FETs in the H-bridge will be disabled and the nFAULT pin will be driven low. When the die temperature falls to a safe level, operation automatically resumes and nFAULT becomes inactive. 8.3.3.3 Undervoltage Lockout (UVLO) If at any time the voltage on the VM pin falls below the undervoltage lockout threshold voltage, all circuitry in the device will be disabled, and all internal logic will be reset. Operation will resume when VM rises above the UVLO threshold. The nFAULT pin is driven low during an undervoltage condition, and also at power up or sleep mode, until the internal power supplies have stabilized. 8.4 Device Functional Modes 8.4.1 Phase/Enable Mode In phase/enable mode, the xPHASE input pins control the direction of current flow through each H-bridge. This sets the direction of rotation of a DC motor, or the direction of the current flow in a stepper motor winding. Driving the xENBL input pins active high enables the H-bridge outputs. This can be used as PWM speed control of a DC motor, or to enable/disable the current in a stepper motor. In phase/enable mode, the M1 input pin controls the state of the H-bridges when xENBL = 0. If M1 is high, the outputs are disabled (high impedance) when xENBL = 0; this corresponds to asynchronous fast decay mode, and is usually used in stepper motor applications to command a "zero current" state. If M1 is low, then the outputs are both driven low; this corresponds to slow decay or brake mode, and is usually used when controlling the speed of a DC motor by PWMing the xENBL pin. Table 2. H-Bridge Control Using Phase/Enable Mode M1 xENBL xPHASE xOUT1 xOUT2 1 0 X Z Z 0 0 X 0 0 X 1 0 L H X 1 1 H L 8.4.2 Indexer Mode To allow a simple step and direction interface to control stepper motors, the DRV8834 contains a microstepping indexer. The indexer controls the state of the H-bridges automatically. Whenever there is a rising edge at the STEP input, the indexer moves to the next step, according to the direction set by the DIR pin. The nENBL pin is used to disable the output stage in indexer mode. When nENBL = 1, the indexer inputs are still active and will respond to the STEP and DIR input pins; only the output stage is disabled. The indexer logic in the DRV8834 allows a number of different stepping configurations. The M0 and M1 pins are used to configure the stepping format as shown in Table 3. Submit Documentation Feedback Copyright © 2012–2015, Texas Instruments Incorporated Product Folder Links: DRV8834 15 DRV8834 SLVSB19D – FEBRUARY 2012 – REVISED MARCH 2015 www.ti.com Table 3. Stepping Format M1 M0 0 0 Full step (2-phase excitation) STEP MODE 0 1 1/2 step (1-2 phase excitation) 0 Z 1/4 step (W1-2 phase excitation) 1 0 8 microsteps/step 1 1 16 microsteps/step 1 Z 32 microsteps/step The M0 pin is a tri-level input. It can be driven logic low, logic high, or high-impedance (Z). The M0 and M1 pins can be statically configured by connecting to VINT, GND, or left open, or can be driven with standard tristate microcontroller I/O port pins. Their state is latched at each rising edge of the STEP input. The step mode may be changed on-the-fly while the motor is moving. The indexer will advance to the next valid state for the new M0/M1 setting at the next rising edge of STEP. The home state is 45°. This state is entered after power up, after exiting undervoltage lockout, or after exiting sleep mode. This is shown in Table 4 by cells shaded yellow. Table 4 shows the relative current and step directions for different step mode settings. At each rising edge of the STEP input, the indexer travels to the next state in the table. The direction is shown with the DIR pin high; if the DIR pin is low the sequence is reversed. Positive current is defined as xOUT1 = positive with respect to xOUT2. 16 Submit Documentation Feedback Copyright © 2012–2015, Texas Instruments Incorporated Product Folder Links: DRV8834 DRV8834 www.ti.com SLVSB19D – FEBRUARY 2012 – REVISED MARCH 2015 Table 4. Current and Step Directions 1/32 STEP 1/16 STEP 1/8 STEP 1/4 STEP 1/2 STEP 1 1 1 1 1 FULL STEP 70% 2 3 2 4 5 3 2 6 7 4 8 9 5 3 2 10 11 6 12 13 7 4 14 15 8 16 17 9 5 3 2 1 18 19 10 20 21 11 6 22 23 12 24 25 13 7 4 26 27 14 28 29 15 8 30 31 16 32 33 17 9 5 3 34 35 18 36 37 19 10 38 39 20 40 41 21 11 6 42 43 22 44 45 23 12 46 47 24 WINDING CURRENT A WINDING CURRENT B ELECTRICAL ANGLE 100% 0% 0 100% 5% 3 100% 10% 6 99% 15% 8 98% 20% 11 97% 24% 14 96% 29% 17 94% 34% 20 92% 38% 23 90% 43% 25 88% 47% 28 86% 51% 31 83% 56% 34 80% 60% 37 77% 63% 39 74% 67% 42 71% 71% 45 67% 74% 48 63% 77% 51 60% 80% 53 56% 83% 56 51% 86% 59 47% 88% 62 43% 90% 65 38% 92% 68 34% 94% 70 29% 96% 73 24% 97% 76 20% 98% 79 15% 99% 82 10% 100% 84 5% 100% 87 0% 100% 90 –5% 100% 93 –10% 100% 96 –15% 99% 98 –20% 98% 101 –24% 97% 104 –29% 96% 107 –34% 94% 110 –38% 92% 113 –43% 90% 115 –47% 88% 118 –51% 86% 121 –56% 83% 124 –60% 80% 127 –63% 77% 129 Submit Documentation Feedback Copyright © 2012–2015, Texas Instruments Incorporated Product Folder Links: DRV8834 17 DRV8834 SLVSB19D – FEBRUARY 2012 – REVISED MARCH 2015 www.ti.com Table 4. Current and Step Directions (continued) 1/32 STEP 1/16 STEP 1/8 STEP 1/4 STEP 1/2 STEP FULL STEP 70% 25 13 7 4 2 48 49 50 51 26 52 53 27 14 54 55 28 56 57 29 15 8 58 59 30 60 61 31 16 62 63 32 64 65 33 17 9 5 66 67 34 68 69 35 18 70 71 36 72 73 37 19 10 74 75 38 76 77 39 20 78 79 40 80 81 41 21 11 6 3 82 83 42 84 85 43 22 86 87 44 88 89 45 23 12 90 91 46 92 93 47 24 94 18 Submit Documentation Feedback WINDING CURRENT A WINDING CURRENT B ELECTRICAL ANGLE –67% 74% 132 –71% 71% 135 –74% 67% 138 –77% 63% 141 –80% 60% 143 –83% 56% 146 –86% 51% 149 –88% 47% 152 –90% 43% 155 –92% 38% 158 –94% 34% 160 –96% 29% 163 –97% 24% 166 –98% 20% 169 –99% 15% 172 –100% 10% 174 –100% 5% 177 –100% 0% 180 –100% –5% 183 –100% –10% 186 –99% –15% 188 –98% –20% 191 –97% –24% 194 –96% –29% 197 –94% –34% 200 –92% –38% 203 –90% –43% 205 –88% –47% 208 –86% –51% 211 –83% –56% 214 –80% –60% 217 –77% –63% 219 –74% –67% 222 –71% –71% 225 –67% –74% 228 –63% –77% 231 –60% –80% 233 –56% –83% 236 –51% –86% 239 –47% –88% 242 –43% –90% 245 –38% –92% 248 –34% –94% 250 –29% –96% 253 –24% –97% 256 –20% –98% 259 –15% –99% 262 Copyright © 2012–2015, Texas Instruments Incorporated Product Folder Links: DRV8834 DRV8834 www.ti.com SLVSB19D – FEBRUARY 2012 – REVISED MARCH 2015 Table 4. Current and Step Directions (continued) 1/32 STEP 1/16 STEP 95 48 1/8 STEP 1/4 STEP 1/2 STEP FULL STEP 70% 96 97 49 25 13 7 98 99 50 100 101 51 26 102 103 52 104 105 53 27 14 106 107 54 108 109 55 28 110 111 56 112 113 57 29 15 8 4 114 115 58 116 117 59 30 118 119 60 120 121 61 31 16 122 123 62 124 125 63 32 126 127 64 128 WINDING CURRENT A WINDING CURRENT B ELECTRICAL ANGLE –10% –100% 264 –5% –100% 267 0% –100% 270 5% –100% 273 10% –100% 276 15% –99% 278 20% –98% 281 24% –97% 284 29% –96% 287 34% –94% 290 38% –92% 293 43% –90% 295 47% –88% 298 51% –86% 301 56% –83% 304 60% –80% 307 63% –77% 309 67% –74% 312 71% –71% 315 74% –67% 318 77% –63% 321 80% –60% 323 83% –56% 326 86% –51% 329 88% –47% 332 90% –43% 335 92% –38% 338 94% –34% 340 96% –29% 343 97% –24% 346 98% –20% 349 99% –15% 352 100% –10% 354 100% –5% 357 8.4.3 nSLEEP Operation Driving nSLEEP low will put the device into a low-power sleep state. In this state, the H-bridges are disabled, the gate drive charge pump is stopped, all internal logic is reset (this returns the indexer to the home state), the VINT supply is disabled, and all internal clocks are stopped. All inputs are ignored until nSLEEP returns inactive high. Because the VINT supply is disabled during sleep mode, it cannot be used to provide a logic high signal to the nSLEEP pin. To simplify board design, the nSLEEP can be pulled up directly to the supply (VM) if it is not actively driven. Unless VM is less than 5.75 V, a pullup resistor is required. The nSLEEP pin is protected by a Zener diode that will clamp the pin voltage to approximately 6.5 V. The pullup resistor limits the current to the input in case VM is higher than 6.5 V. The recommended pullup resistor is 20 kΩ to 50 kΩ. Submit Documentation Feedback Copyright © 2012–2015, Texas Instruments Incorporated Product Folder Links: DRV8834 19 DRV8834 SLVSB19D – FEBRUARY 2012 – REVISED MARCH 2015 www.ti.com When exiting sleep mode, the nFAULT pin will be briefly driven active low as the internal power supplies turn on. nFAULT will return to inactive high once the internal power supplies (including charge pump) have stabilized. This process takes some time (up to 1 ms), before the motor driver becomes fully operational. 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 DRV8834 is a very flexible motor driver. It can be used to drive two DC motors or a stepper motor, in a number of different configurations. The following applications schematics show various configurations and connections for the DRV8834. Component values, especially for RSENSE and the DECAY pins, may be different depending on your motor and application. Refer to the information above to determine the best values for these components in your application. 9.1.1 Sense Resistor For optimal performance, it is important for the sense resistor to be: • Surface-mount • Low inductance • Rated for high enough power • Placed closely to the motor driver The power dissipated by the sense resistor equals IRMS2 × R. For example, if peak motor current is 3 A, RMS motor current is 2 A, and a 0.05-Ω sense resistor is used, the resistor will dissipate 2A2 × 0.05 Ω = 0.2 W. The power quickly increases with higher current levels. Resistors typically have a rated power within some ambient temperature range, along with a derated power curve for high ambient temperatures. When a PCB is shared with other components generating heat, margin should be added. It is always best to measure the actual sense resistor temperature in a final system, along with the power MOSFETs, as those are often the hottest components. Because power resistors are larger and more expensive than standard resistors, it is common practice to use multiple standard resistors in parallel, between the sense node and ground. This distributes the current and heat dissipation. 9.2 Typical Application 9.2.1 Phase/Enable Mode Driving Two DC Motors In this configuration, the DRV8834 is used to drive two independent DC motors. Current up to 1 A per motor is possible. The M1 pin is pulled low to allow slow decay PWM from the controller (if desired) to control the motor speed by PWMing the xENBL inputs, and ADECAY and BDECAY are connected to ground to set slow decay mode during current limiting. The value of the RSENSE resistors shown is for a 1-A current limit; if current limiting is not needed, the AISEN and BISEN pins may be connected directly to ground. If the sleep function is not needed, nSLEEP can be connected to VM with an approximate 47-kΩ resistor. 20 Submit Documentation Feedback Copyright © 2012–2015, Texas Instruments Incorporated Product Folder Links: DRV8834 DRV8834 www.ti.com SLVSB19D – FEBRUARY 2012 – REVISED MARCH 2015 Typical Application (continued) VM 10 uf VM VM 0.01 uf VCP Motor A Enable NENBL/AENBL Motor B Enable STEP/BENBL AOUT1 DIR/BPHASE AOUT2 M Motor B Direction Motor A Direction M0/APHASE M1 BOUT1 NSLEEP BOUT2 CONFIG NFAULT VREFO VINT M LOW = SLEEP AVREF BVREF AISEN 2.2 uf BISEN ADECAY BDECAY GND Figure 9. Phase/Enable Mode Driving Two DC Motors 9.2.1.1 Design Requirements Table 5 lists the design parameters. Table 5. Design Parameters PARAMETER REFERENCE Motor voltage VM EXAMPLE VALUE 10 V Motor RMS current IRMS 0.8 A Motor start-up current ISTART 1A Motor current trip point ITRIP 1.5 A 9.2.1.2 Detailed Design Procedure 9.2.1.2.1 Motor Voltage The motor voltage to use will depend on the ratings of the motor selected and the desired RPM. A higher voltage spins a brushed DC motor faster with the same PWM duty cycle applied to the power FETs. A higher voltage also increases the rate of current change through the inductive motor windings. 9.2.1.2.2 Power Dissipation The power dissipation of the DRV8834 is a function of RMS motor current and the FET resistance (RDS(ON)) of each output. Power ≈ IRMS2 × (High-Side RDS(ON) + Low-Side RDS(ON)) (2) For this example, the ambient temperature is 35°C, and the junction temperature reaches 65°C. At 65°C, the sum of RDS(ON) is about 1 Ω. With an example motor current of 0.8 A, the dissipated power in the form of heat will be 0.8 A2 × 1 Ω = 0.64 W. The temperature that the DRV8834 reaches will depend on the thermal resistance to the air and PCB. It is important to solder the device PowerPAD to the PCB ground plane, with vias to the top and bottom board layers, in order dissipate heat into the PCB and reduce the device temperature. In the example used here, the DRV8834 had an effective thermal resistance RθJA of 47°C/W, and: Submit Documentation Feedback Copyright © 2012–2015, Texas Instruments Incorporated Product Folder Links: DRV8834 21 DRV8834 SLVSB19D – FEBRUARY 2012 – REVISED MARCH 2015 www.ti.com TJ = TA + (PD × RθJA) = 35°C + (0.64 W x 47° C/W) = 65°C. (3) 9.2.1.2.3 Motor Current Trip Point When the voltage on pin SENSE exceeds VTRIP (0.5 V), overcurrent is detected. The RSENSE resistor should be sized to set the desired ITRIP level. RSENSE = 0.5 V / ITRIP (4) To set ITRIP to 2 A, RSENSE = 0.5 V / 2 A = 0.25 Ω. To prevent false trips, ITRIP must be higher than regular operating current. Motor current during start-up is typically much higher than steady-state spinning, because the initial load torque is higher, and the absence of back-EMF causes a higher voltage and extra current across the motor windings. It can be beneficial to limit start-up current by using series inductors on the DRV8834 output, as that allows ITRIP to be lower, and it may decrease the system’s required bulk capacitance. Start-up current can also be limited by ramping the forward drive duty cycle. 9.2.1.3 Application Curves Figure 10. Brushed Motor – VM = 8 V, DRV8834 is Regulating Current Figure 11. Internal Indexer – VM = 8 V, 1200 Steps per second, 1/8 microstep mode, 1-A Current regulation Figure 12. External Microstepping – VM = 8 V, 4000 Steps Per Second, 1/128 microstep mode, 1.2-A Current Regulation 22 Submit Documentation Feedback Copyright © 2012–2015, Texas Instruments Incorporated Product Folder Links: DRV8834 DRV8834 www.ti.com SLVSB19D – FEBRUARY 2012 – REVISED MARCH 2015 9.2.2 Phase/Enable Mode Driving a Stepper Motor VM 10 uf VM VM 0.01 uf Coil A Enable Coil B Enable Coil B Direction Coil A Direction VINT LOW = SLEEP VCP NENBL/AENBL STEP/BENBL AOUT1 DIR/BPHASE AOUT2 Stepper M0/APHASE M1 BOUT1 NSLEEP BOUT2 CONFIG NFAULT VREFO VINT AVREF BVREF AISEN 2.2 uf BISEN ADECAY BDECAY 51K GND 51K Figure 13. Phase/Enable Mode Driving a Stepper Motor 9.2.2.1 Design Requirements Table 6 lists the design parameters. Table 6. Design Parameters PARAMETER REFERENCE EXAMPLE VALUE Supply voltage VM 6V Motor winding resistance RL 3.9 Ω Motor winding inductance IL 2.9 mH Motor full step angle θstep 1.8°/step Target microstepping level nm 2 µsteps per step Target motor speed V 120 RPM Target full-scale current IFS 1.25 A 9.2.2.2 Detailed Design Procedure Phase/enable mode can be used with a simple interface to a controller to operate a stepper motor in full or half step modes. The decay mode can be set by changing the values of the resistors connected to the ADECAY and BDECAY pins. The M1 pin is driven to logic high (by connecting to the VINT supply), to allow a zero-current (off) state when the xENBL pin is set low. Coil current is set by the RSENSE resistors. If the sleep function is not needed, nSLEEP can be connected to VM with an approximate 47-kΩ resistor. 9.2.2.2.1 Stepper Motor Speed The first step in configuring the DRV8834 requires the desired motor speed and microstepping level. If the target application requires a constant speed, then a square wave with frequency ƒstep must be applied to the STEP pin. If the target motor start-up speed is too high, the motor will not spin. Make sure that the motor can support the target speed or implement an acceleration profile to bring the motor up to speed. For a desired motor speed (v), microstepping level (nm), and motor full step angle (θstep), Submit Documentation Feedback Copyright © 2012–2015, Texas Instruments Incorporated Product Folder Links: DRV8834 23 DRV8834 SLVSB19D – FEBRUARY 2012 – REVISED MARCH 2015 www.ti.com θstep can be found in the stepper motor data sheet or written on the motor itself. For the DRV8834, the microstepping level is set by the MODE pins and can be any of the settings in Table 6. Higher microstepping will mean a smoother motor motion and less audible noise, but will increase switching losses and require a higher fstep to achieve the same motor speed. 9.2.2.2.2 Current Regulation In a stepper motor, the set full-scale current (IFS) is the maximum current driven through either winding. This quantity will depend on the xVREF analog voltage and the sense resistor value (RSENSE). During stepping, IFS defines the current chopping threshold (ITRIP) for the maximum current step. The gain of DRV8834 is set for 5 V/V. To achieve IFS = 1.25 A with RSENSE of 0.2 Ω, xVREF should be 1.25 V. 9.2.2.2.3 Decay Modes The DRV8834 supports three different decay modes: slow decay, fast decay, and mixed decay. The current through the motor windings is regulated using a fixed-frequency PWM scheme. This means that after any drive phase, when a motor winding current has hit the current chopping threshold (ITRIP), the DRV8834 will place the winding in one of the three decay modes until the PWM cycle has expired. Afterward, a new drive phase starts. The blanking time TBLANK defines the minimum drive time for the current chopping. ITRIP is ignored during TBLANK, so the winding current may overshoot the trip level. 9.2.2.3 Application Curves 1 Step 1 Step APHASE APHASE BPHASE BPHASE AENBL AENBL BENBL BENBL A Current A Current B Current B Current Figure 14. Full Step Sequence (2-Phase) 24 Figure 15. Half Step Sequence (1-2 Phase) Submit Documentation Feedback Copyright © 2012–2015, Texas Instruments Incorporated Product Folder Links: DRV8834 DRV8834 www.ti.com SLVSB19D – FEBRUARY 2012 – REVISED MARCH 2015 9.2.3 Indexer Mode Driving a Stepper Motor In indexer mode, only a rising edge on the STEP pin is needed to move the motor to the next step. The DIR pin sets which direction the motor rotates, by reversing the step sequence. The internal indexer can operate in fullstep, half-step, and smaller microsteps up to 1/32-step, depending on the state of the M0 and M1 pins. The M0 and M1 pins can also be connected directly to ground or to VINT to program the step modes, if desired. If the sleep function is not needed, nSLEEP can be connected to VM with an approximate 47-kΩ resistor. Step sequences for full and half step are shown below. VM 10 uf VM VM 0.01 uf L=Enable H = Disable STEP Pulse Direction Step Mode M0 VCP NENBL/AENBL STEP/BENBL AOUT1 DIR/BPHASE AOUT2 Stepper M0/APHASE Step Mode M1 LOW = SLEEP VINT M1 BOUT1 NSLEEP BOUT2 CONFIG NFAULT VREFO VINT AVREF BVREF AISEN 2.2 uf BISEN ADECAY BDECAY 51K GND 51K Figure 16. Indexer Mode Driving a Stepper Motor 9.2.3.1 Design Requirements Table 7 lists the design parameters. Table 7. Design Parameters PARAMETER REFERENCE EXAMPLE VALUE Supply Voltage VM 6V Motor Winding Resistance RL 3.9 Ω Motor Winding Inductance IL 2.9 mH Motor Full Step Angle θstep 1.8°/step Target Microstepping Level nm 8 µsteps per step Target Motor Speed V 120 RPM Target Full-Scale Current IFS 1.25 A 9.2.3.2 Detailed Design Procedures Phase/enable mode can be used with a simple interface to a controller to operate a stepper motor in full or half step modes. The decay mode can be set by changing the values of the resistors connected to the ADECAY and BDECAY pins. The M1 pin is driven to logic high (by connecting to the VINT supply), to allow a zero-current (off) state when the xENBL pin is set low. Coil current is set by the RSENSE resistors. If the sleep function is not needed, nSLEEP can be connected to VM with an approximate 47-kΩ resistor. Submit Documentation Feedback Copyright © 2012–2015, Texas Instruments Incorporated Product Folder Links: DRV8834 25 DRV8834 SLVSB19D – FEBRUARY 2012 – REVISED MARCH 2015 www.ti.com 9.2.3.2.1 Stepper Motor Speed The first step in configuring the DRV8834 requires the desired motor speed and microstepping level. If the target application requires a constant speed, then a square wave with frequency ƒstep must be applied to the STEP pin. If the target motor start-up speed is too high, the motor will not spin. Make sure that the motor can support the target speed or implement an acceleration profile to bring the motor up to speed. For a desired motor speed (v), microstepping level (nm), and motor full step angle (θstep), θstep can be found in the stepper motor data sheet or written on the motor itself. For the DRV8834, the microstepping level is set by the MODE pins and can be any of the settings in Table 6. Higher microstepping will mean a smoother motor motion and less audible noise, but will increase switching losses and require a higher fstep to achieve the same motor speed. 9.2.3.2.2 Current Regulation In a stepper motor, the set full-scale current (IFS) is the maximum current driven through either winding. This quantity will depend on the xVREF analog voltage and the sense resistor value (RSENSE). During stepping, IFS defines the current chopping threshold (ITRIP) for the maximum current step. The gain of DRV8834 is set for 5 V/V. To achieve IFS = 1.25 A with RSENSE of 0.2 Ω, xVREF should be 1.25 V. 9.2.3.2.3 Decay Modes The DRV8834 supports three different decay modes: slow decay, fast decay, and mixed decay. The current through the motor windings is regulated using a fixed-frequency PWM scheme. This means that after any drive phase, when a motor winding current has hit the current chopping threshold (ITRIP), the DRV8834 will place the winding in one of the three decay modes until the PWM cycle has expired. Afterward, a new drive phase starts. The blanking time TBLANK defines the minimum drive time for the current chopping. ITRIP is ignored during TBLANK, so the winding current may overshoot the trip level. 9.2.3.3 Application Curves 1 Step 1 Step STEP STEP DIR DIR A Current A Current B Current B Current Figure 17. Full Step Sequence (2-Phase) 26 Figure 18. Half Step Sequence (1-2 Phase) Submit Documentation Feedback Copyright © 2012–2015, Texas Instruments Incorporated Product Folder Links: DRV8834 DRV8834 www.ti.com SLVSB19D – FEBRUARY 2012 – REVISED MARCH 2015 9.2.4 High-Resolution Microstepping Using a Microcontroller to Modulate VREF Signals VM 10 uf VM VM 0.01 uf Coil A Enable Coil B Enable Coil B Direction Coil A Direction VINT LOW = SLEEP NENBL/AENBL STEP/BENBL AOUT1 DIR/BPHASE AOUT2 M1 BOUT1 NSLEEP BOUT2 CONFIG NFAULT VREFO VINT AVREF Coil B VREF BVREF AISEN 2.2 uf BISEN Coil A Decay ADECAY Coil B Decay BDECAY GND 51K Stepper M0/APHASE Coil A VREF Low = Slow Open = Mixed High = Fast VCP 51K Figure 19. High-Resolution Microstepping 9.2.4.1 Design Requirements Table 8 lists the design parameters. Table 8. Design Parameters PARAMETER REFERENCE EXAMPLE VALUE Supply voltage VM 6V Motor winding resistance RL 3.9 Ω Motor winding inductance IL 2.9 mH Motor full step angle θstep 1.8°/step Target microstepping level nm 128 µsteps per step Target motor speed V 120 RPM Target full-scale current IFS 1.25 A 9.2.4.2 Detailed Design Procedure Using a microcontroller with two DAC outputs, very high resolution microstepping can be performed with the DRV8834. In this mode, the coil current direction is controlled by the PHASE pins, and the current in each coil is independently set using the two VREF input pins, which are connected to DACs. In addition, the microcontroller can set the decay mode for each coil dynamically, by driving the xDECAY pin low for slow decay, high for fast decay, or high-impedance which sets mixed decay (based on the value of a resistor connected to ground). If the sleep function is not needed, nSLEEP can be connected to VM with an approximate 47-kΩ resistor. For more details on this technique, refer to TI Application Report, High Resolution Microstepping Driver With the DRV88xx Series (SLVA416). Submit Documentation Feedback Copyright © 2012–2015, Texas Instruments Incorporated Product Folder Links: DRV8834 27 DRV8834 SLVSB19D – FEBRUARY 2012 – REVISED MARCH 2015 www.ti.com 9.2.4.3 Application Curves 1 Step 1 Step APHASE APHASE BPHASE BPHASE AVREF AENBL BVREF BENBL A Current A Current B Current B Current Figure 20. Microstepping Sequence Figure 21. Full Step Sequence (2-Phase) 1 Step APHASE BPHASE AENBL BENBL A Current B Current Figure 22. Half Step Sequence (1-2 Phase) 28 Submit Documentation Feedback Copyright © 2012–2015, Texas Instruments Incorporated Product Folder Links: DRV8834 DRV8834 www.ti.com SLVSB19D – FEBRUARY 2012 – REVISED MARCH 2015 10 Power Supply Recommendations 10.1 Bulk Capacitance Having appropriate local bulk capacitance is an important factor in motor drive system design. It is generally beneficial to have more bulk capacitance, while the disadvantages are increased cost and physical size. The amount of local capacitance needed depends on a variety of factors, including: • The highest current required by the motor system • The capacitance of the power supply and its ability to source or sink current • The amount of parasitic inductance between the power supply and motor system • The acceptable voltage ripple • The type of motor used (brushed DC, brushless DC, stepper) • The motor braking method The inductance between the power supply and motor drive system will limit the rate current can change from the power supply. If the local bulk capacitance is too small, the system will respond to excessive current demands or dumps from the motor with a change in voltage. When adequate bulk capacitance is used, the motor voltage remains stable and high current can be quickly supplied. The data sheet generally provides a recommended value, but system-level testing is required to determine the appropriate sized bulk capacitor. Power Supply Parasitic Wire Inductance Motor Drive System VM + – + Motor Driver GND Local Bulk Capacitor IC Bypass Capacitor Figure 23. Example Setup of Motor Drive System With External Power Supply The voltage rating for bulk capacitors should be higher than the operating voltage, to provide margin for cases when the motor transfers energy to the supply. Submit Documentation Feedback Copyright © 2012–2015, Texas Instruments Incorporated Product Folder Links: DRV8834 29 DRV8834 SLVSB19D – FEBRUARY 2012 – REVISED MARCH 2015 www.ti.com 11 Layout 11.1 Layout Guidelines The VM pin should be bypassed to GND using low-ESR ceramic bypass capacitors with a recommended value of 0.01-μF rated for VM. This capacitor should be placed as close to the VM pin as possible with a thick trace or ground plane connection to the device GND pin. The VM pin must be bypassed to ground using an appropriate bulk capacitor. This component may be an electrolytic and should be located close to the DRV8834. A low-ESR ceramic capacitor must be placed in between the VM and VCP pins. TI recommends a value of 0.01- μF rated for 16 V. Place this component as close to the pins as possible. Bypass VINT to ground with a 2.2-μF ceramic capacitor rated 6.3 V. Place this bypass capacitor as close to the pin as possible. 11.2 Layout Example VREFO BVREF ADECAY AVREF AOUT1 GND AISEN VINT 10 µF 2.2 µF AOUT2 VM BOUT2 VM BISEN VCP BOUT1 nFAULT 0.01 µF + RAISEN nSLEEP BDECAY 0.01 µF RBISEN nENBL / AENBL CONFIG STEP / BENBL M1 DIR / BPHASE M0 / APHASE Logic high voltage Figure 24. Recommended Layout 11.3 Thermal Considerations 11.3.1 Maximum Output Current In actual operation, the maximum output current achievable with a motor driver is a function of die temperature. This in turn is greatly affected by ambient temperature and PCB design. Basically, the maximum motor current will be the amount of current that results in a power dissipation level that, along with the thermal resistance of the package and PCB, keeps the die at a low enough temperature to stay out of thermal shutdown. The thermal data given in the data sheet can be used as a guide to calculate the approximate maximum power dissipation that can be expected to be possible without entering thermal shutdown for several different PCB constructions. However, for accurate data, the actual PCB design must be analyzed via measurement or thermal simulation. 30 Submit Documentation Feedback Copyright © 2012–2015, Texas Instruments Incorporated Product Folder Links: DRV8834 DRV8834 www.ti.com SLVSB19D – FEBRUARY 2012 – REVISED MARCH 2015 Thermal Considerations (continued) 11.3.2 Thermal Protection The DRV8834 has thermal shutdown (TSD) as described above. If the die temperature exceeds approximately 160°C, the device will be disabled until the temperature drops to a safe level. Any tendency of the device to enter thermal shutdown is an indication of either excessive power dissipation, insufficient heatsinking, or too high an ambient temperature. 11.3.3 Power Dissipation Power dissipation in the DRV8834 is dominated by the DC power dissipated in the output FET resistance, or RDS(ON). There is additional power dissipated due to PWM switching losses, which are dependent on PWM frequency, rise and fall times, and VM supply voltages. These switching losses are typically on the order of 10% to 20% of the DC power dissipation. The DC power dissipation of one H-bridge can be roughly estimated by Equation 5. 2 2 PTOT = (HS - RDS(ON) · IOUT(RMS) ) + (LS - RDS(ON) · IOUT(RMS) ) (5) where PTOT is the total power dissipation, HS - RDS(ON) is the resistance of the high side FET, LS - RDS(ON) is the resistance of the low side FET, and IOUT(RMS) is the RMS output current being applied to the motor. RDS(ON) increases with temperature, so as the device heats, the power dissipation increases. This must be taken into consideration when sizing the heatsink. 11.3.4 Heatsinking The PowerPAD™ package uses an exposed pad to remove heat from the device. For proper operation, this pad must be thermally connected to copper on the PCB to dissipate heat. On a multi-layer PCB with a ground plane, this can be accomplished by adding a number of vias to connect the thermal pad to the ground plane. On PCBs without internal planes, copper area can be added on either side of the PCB to dissipate heat. If the copper area is on the opposite side of the PCB from the device, thermal vias are used to transfer the heat between top and bottom layers. For details about how to design the PCB, refer to TI application report, PowerPAD™ Thermally Enhanced Package(SLMA002), and TI application brief, PowerPAD™ Made Easy (SLMA004), available at www.ti.com. In general, the more copper area that can be provided, the more power can be dissipated. Submit Documentation Feedback Copyright © 2012–2015, Texas Instruments Incorporated Product Folder Links: DRV8834 31 DRV8834 SLVSB19D – FEBRUARY 2012 – REVISED MARCH 2015 www.ti.com 12 Device and Documentation Support 12.1 Documentation Support 12.1.1 Related Documentation • • • High Resolution Microstepping Driver With the DRV88xx Series, SLVA416 PowerPAD™ Thermally Enhanced Package, SLMA002 PowerPAD™ Made Easy, SLMA004 12.2 Trademarks PowerPAD is a trademark of Texas Instruments. All other trademarks are the property of their respective owners. 12.3 Electrostatic Discharge Caution These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam during storage or handling to prevent electrostatic damage to the MOS gates. 12.4 Glossary SLYZ022 — 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. 32 Submit Documentation Feedback Copyright © 2012–2015, Texas Instruments Incorporated Product Folder Links: DRV8834 PACKAGE OPTION ADDENDUM www.ti.com 10-Dec-2020 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) DRV8834PWP ACTIVE HTSSOP PWP 24 60 RoHS & Green NIPDAU Level-3-260C-168 HR -40 to 85 DRV8834 DRV8834PWPR ACTIVE HTSSOP PWP 24 2000 RoHS & Green NIPDAU Level-3-260C-168 HR -40 to 85 DRV8834 DRV8834RGER ACTIVE VQFN RGE 24 3000 RoHS & Green NIPDAU Level-3-260C-168 HR -40 to 85 DRV8834 DRV8834RGET ACTIVE VQFN RGE 24 250 RoHS & Green NIPDAU Level-3-260C-168 HR -40 to 85 DRV8834 (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