DRV8426
SLOSE55B – MAY 2020 – REVISED MAY 2021
DRV8426 Stepper Driver With Integrated Current Sense, 1/256 Microstepping,
STEP/DIR Interface and smart tune Technology
1 Features
•
•
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•
•
•
•
•
•
•
•
•
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PWM microstepping stepper motor driver
– Simple STEP/DIR interface
– Up to 1/256 microstepping indexer
Integrated current sense functionality
– No sense resistors required
– ±5% full-scale current accuracy
Smart tune decay technology, fixed slow, and
mixed decay options
4.5 to 33-V Operating supply voltage range
Low RDS(ON):
– 900 mΩ HS + LS at 24 V, 25°C
High current capacity per bridge
– 2.5 A peak, 1.5 A full-scale, 1.1 A rms
Pin to pin compatible with – DRV8424/25: 33-V, 330/550 mΩ HS + LS
– DRV8436: 48-V, 900 mΩ HS + LS
– DRV8434: 48-V, 330 mΩ HS + LS
Configurable off-time PWM chopping
– 7-μs, 16-μs, 24-μs, or 32-μs.
Supports 1.8-V, 3.3-V, 5.0-V logic inputs
Low-current sleep mode (2 μA)
Spread spectrum clocking for low electromagnetic
interference (EMI)
Small package and footprint
Protection features
– VM undervoltage lockout (UVLO)
– Charge pump undervoltage (CPUV)
– Overcurrent protection (OCP)
– Thermal shutdown (OTSD)
– Fault condition output (nFAULT)
of driving up to 1.5-A full-scale output current
(dependent on PCB design).
The DRV8426 uses an internal current sense
architecture to eliminate the need for two external
power sense resistors, saving PCB area and
system cost. The device uses an internal PWM
current regulation scheme selectable between smart
tune, slow and mixed decay options. Smart tune
automatically adjusts for optimal current regulation,
compensates for motor variation and aging effects
and reduces audible noise from the motor.
A simple STEP/DIR interface allows an external
controller to manage the direction and step rate of
the stepper motor. The device can be configured
in full-step to 1/256 microstepping. A low-power
sleep mode is provided using a dedicated nSLEEP
pin. Protection features are provided for supply
undervoltage, charge pump faults, overcurrent, short
circuits, and overtemperature. Fault conditions are
indicated by the nFAULT pin.
Device Information(1)
(1)
PART NUMBER
PACKAGE
BODY SIZE (NOM)
DRV8426PWPR
HTSSOP (28)
9.7 mm x 4.4 mm
DRV8426RGER
VQFN (24)
4.0 mm x 4.0 mm
For all available packages, see the orderable addendum at
the end of the data sheet.
2 Applications
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Printers and scanners
3D printers
ATM and money handling machines
Textile and sewing machines
Stage lighting equipment
CCTV, security and dome cameras
Office and home automation
Factory automation and robotics
Medical applications
Simplified Schematic
3 Description
The DRV8426 is a stepper motor driver for industrial
and consumer applications. The device is fully
integrated with two N-channel power MOSFET
H-bridge drivers, a microstepping indexer, and
integrated current sensing. The DRV8426 is capable
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.
DRV8426
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Table of Contents
1 Features............................................................................1
2 Applications..................................................................... 1
3 Description.......................................................................1
4 Revision History.............................................................. 2
5 Pin Configuration and Functions...................................3
6 Specifications.................................................................. 6
6.1 Absolute Maximum Ratings........................................ 6
6.2 ESD Ratings............................................................... 6
6.3 Recommended Operating Conditions.........................7
6.4 Thermal Information....................................................7
6.5 Electrical Characteristics.............................................8
6.6 Indexer Timing Requirements..................................... 9
6.7 Typical Characteristics.............................................. 10
7 Detailed Description......................................................13
7.1 Overview................................................................... 13
7.2 Functional Block Diagram......................................... 14
7.3 Feature Description...................................................14
7.4 Device Functional Modes..........................................32
8 Application and Implementation.................................. 34
8.1 Application Information............................................. 34
8.2 Typical Application.................................................... 34
9 Power Supply Recommendations................................39
9.1 Bulk Capacitance...................................................... 39
10 Layout...........................................................................40
10.1 Layout Guidelines................................................... 40
11 Device and Documentation Support..........................41
11.1 Receiving Notification of Documentation Updates.. 41
11.2 Community Resources............................................41
11.3 Trademarks............................................................. 41
12 Mechanical, Packaging, and Orderable
Information.................................................................... 42
4 Revision History
NOTE: Page numbers for previous revisions may differ from page numbers in the current version.
Changes from Revision A (October 2020) to Revision B (May 2021)
Page
• Fixed typo in Description ................................................................................................................................... 1
• Fixed Typo in Table 7-4 ....................................................................................................................................16
• Removed duplicate package drawings............................................................................................................. 42
Changes from Revision * (May 2020) to Revision A (October 2020)
Page
• Changed Device Status to "Production Data".....................................................................................................1
2
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5 Pin Configuration and Functions
Figure 5-1. PWP PowerPAD™ Package 28-Pin HTSSOP Top View
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Figure 5-2. RGE Package 24-Pin VQFN with Exposed Thermal PAD Top View
Table 5-1. Pin Functions
PIN
NAME
AOUT1
4
NO.
HTSSOP
VQFN
4, 5
3
I/O
TYPE
DESCRIPTION
O
Output
Winding A output. Connect to stepper motor winding.
AOUT2
6, 7
4
O
Output
Winding A output. Connect to stepper motor winding.
PGND
3, 12
2, 7
—
Power
Power ground. Connect to system ground.
BOUT2
8, 9
5
O
Output
Winding B output. Connect to stepper motor winding
BOUT1
10, 11
6
O
Output
Winding B output. Connect to stepper motor winding
CPH
28
23
CPL
27
22
—
Power
Charge pump switching node. Connect a X7R, 0.022-µF, VM-rated
ceramic capacitor from CPH to CPL.
DIR
24
19
I
Input
Direction input. Logic level sets the direction of stepping; internal
pulldown resistor.
ENABLE
25
20
I
Input
Logic low to disable device outputs; logic high to enable; internal pullup
to DVDD. Also determines the type of OCP and OTSD response.
DVDD
15
10
O
Power
Logic supply voltage. Connect a X7R, 0.47-μF to 1-μF, 6.3-V or 10-V
rated ceramic capacitor to GND.
GND
14
9
—
Power
Device ground. Connect to system ground.
VREF
17
12
I
Input
Current set reference input. Maximum value 3.3 V for DRV8426. DVDD
can be used to provide VREF through a resistor divider.
M0
18
13
M1
22
17
I
Input
Microstepping mode-setting pins. Sets the step mode; internal pulldown
resistor.
DECAY0
21
16
DECAY1
20
15
I
Input
Decay-mode setting pins. Sets the decay mode (see the Section 7.3.6
section).
STEP
23
18
I
Input
Step input. A rising edge causes the indexer to advance one step;
internal pulldown resistor.
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Table 5-1. Pin Functions (continued)
PIN
NAME
NO.
I/O
TYPE
DESCRIPTION
HTSSOP
VQFN
VCP
1
24
—
Power
Charge pump output. Connect a X7R, 0.22-μF, 16-V ceramic capacitor
to VM.
VM
2, 13
1, 8
—
Power
Power supply. Connect to motor supply voltage and bypass to PGND
with two 0.01-µF ceramic capacitors (one for each pin) plus a bulk
capacitor rated for VM.
TOFF
19
14
I
Input
Sets the Decay mode off time during current chopping; four level pin.
Also sets the ripple current in smart tune ripple control mode.
nFAULT
16
11
O
Open Drain
Fault indication. Pulled logic low with fault condition; open-drain output
requires an external pullup resistor.
nSLEEP
26
21
I
Input
Sleep mode input. Logic high to enable device; logic low to enter lowpower sleep mode; internal pulldown resistor. An nSLEEP low pulse
clears faults.
-
-
-
-
PAD
Thermal pad. Connect to system ground.
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6 Specifications
6.1 Absolute Maximum Ratings
over operating free-air temperature range (unless otherwise noted)(1)
MIN
MAX
Power supply voltage (VM)
–0.3
35
V
Charge pump voltage (VCP, CPH)
–0.3
VVM + 7
V
Charge pump negative switching pin (CPL)
–0.3
VVM
V
nSLEEP pin voltage (nSLEEP)
–0.3
VVM
V
Internal regulator voltage (DVDD)
–0.3
5.75
V
Control pin voltage (STEP, DIR, ENABLE, nFAULT, DECAY0, DECAY1, TOFF, M0, M1)
–0.3
5.75
Open drain output current (nFAULT)
0
10
Reference input pin voltage (VREF)
UNIT
V
mA
–0.3
5.75
V
Continuous phase node pin voltage (AOUT1, AOUT2, BOUT1, BOUT2)
–1
VVM + 1
V
Transient 100 ns phase node pin voltage (AOUT1, AOUT2, BOUT1, BOUT2)
–3
VVM + 3
V
Peak drive current (AOUT1, AOUT2, BOUT1, BOUT2)
Internally Limited
Operating ambient temperature, TA
–40
A
125
°C
Operating junction temperature, TJ
–40
150
°C
Storage temperature, Tstg
–65
150
°C
(1)
Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. These are stress
ratings only, which do not imply functional operation of the device at these or any other conditions beyond those indicated under
Recommended Operating Conditions. Exposure to absolute-maximum-rated conditions for extended periods may affect device
reliability.
6.2 ESD Ratings
VALUE
Human-body model (HBM), per ANSI/ESDA/JEDEC JS-001
V(ESD)
6
Electrostatic
discharge
Charged-device model (CDM), per JEDEC specification JESD22C101
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UNIT
±2000
Corner pins for PWP (1,
14, 15, and 28)
±750
Other pins
±500
V
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6.3 Recommended Operating Conditions
over operating free-air temperature range (unless otherwise noted)
MIN
VVM
Supply voltage range for normal (DC) operation
VI
Logic level input voltage
MAX
UNIT
4.5
33
V
0
5.5
V
VVREF
VREF voltage
0.05
3.3
ƒSTEP
Applied STEP signal (STEP)
0
500(1)
kHz
V
IFS
Motor full-scale current (xOUTx)
0
1.5(2)
A
Irms
Motor RMS current (xOUTx)
0
1.1(2)
A
TA
Operating ambient temperature
–40
125
°C
TJ
Operating junction temperature
–40
150
°C
(1)
(2)
STEP input can operate up to 500 kHz, but system bandwidth is limited by the motor load
Power dissipation and thermal limits must be observed
6.4 Thermal Information
THERMAL METRIC(1)
RθJA
RGE (VQFN)
28 PINS
24 PINS
UNIT
33.0
43.0
°C/W
RθJC(top) Junction-to-case (top) thermal resistance
28.0
35.0
°C/W
RθJB
Junction-to-board thermal resistance
12.9
19.9
°C/W
ψJT
Junction-to-top characterization parameter
0.7
1.0
°C/W
ψJB
Junction-to-board characterization parameter
12.8
19.8
°C/W
RθJC(bot) Junction-to-case (bottom) thermal resistance
4.9
6.7
°C/W
(1)
Junction-to-ambient thermal resistance
PWP (HTSSOP)
For more information about traditional and new thermal metrics, see the Semiconductor and IC Package Thermal Metrics application
report.
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6.5 Electrical Characteristics
Typical values are at TA = 25°C and VVM = 24 V. All limits are over recommended operating conditions, unless otherwise
noted.
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
5
6.5
mA
2
4
μA
40
μs
POWER SUPPLIES (VM, DVDD)
IVM
VM operating supply current
IVMQ
VM sleep mode supply current nSLEEP = 0
ENABLE = 1, nSLEEP = 1, No motor load
tSLEEP
Sleep time
nSLEEP = 0 to sleep-mode
tRESET
nSLEEP reset pulse
nSLEEP low to clear fault
120
μs
20
tWAKE
Wake-up time
nSLEEP = 1 to output transition
0.8
1.2
ms
tON
Turn-on time
VM > UVLO to output transition
0.8
1.2
ms
tEN
Enable time
ENABLE = 0/1 to output transition
5
μs
VDVDD
Internal regulator voltage
5.25
V
No external load, 6 V < VVM < 33 V
No external load, VVM = 4.5 V
4.75
5
4.2
4.35
V
VVM + 5
V
CHARGE PUMP (VCP, CPH, CPL)
VCP
VCP operating voltage
6 V < VVM < 33 V
f(CP)
Charge pump switching
frequency
VVM > UVLO; nSLEEP = 1
360
kHz
LOGIC-LEVEL INPUTS (STEP, DIR, nSLEEP)
VIL
Input logic-low voltage
VIH
Input logic-high voltage
VHYS
Input logic hysteresis
IIL
Input logic-low current
VIN = 0 V
IIH
Input logic-high current
VIN = 5 V
0
0.6
V
1.5
5.5
V
150
–1
mV
1
μA
100
μA
0.6
V
2.2
V
TRI-LEVEL INPUTS (M0, DECAY0, DECAY1, ENABLE)
VI1
Input logic-low voltage
Tied to GND
VI2
Input Hi-Z voltage
Hi-Z
1.8
0
VI3
Input logic-high voltage
Tied to DVDD
2.7
IO
Output pull-up current
2
5.5
10
V
μA
QUAD-LEVEL INPUTS (M1, TOFF)
VI1
Input logic-low voltage
Tied to GND
1
1.25
1.4
V
Input Hi-Z voltage
Hi-Z
1.8
2
2.2
V
VI4
Input logic-high voltage
Tied to DVDD
2.7
IIL
Output pull-up current
VI2
330kΩ ± 5% to GND
VI3
0
0.6
5.5
10
V
V
μA
CONTROL OUTPUTS (nFAULT)
VOL
Output logic-low voltage
IOH
Output logic-high leakage
IO = 5 mA
–1
0.5
V
1
μA
550
mΩ
MOTOR DRIVER OUTPUTS (AOUT1, AOUT2, BOUT1, BOUT2)
TJ = 25 °C, IO = -1 A
RDS(ONH)
RDS(ONL)
tSR
8
High-side FET on resistance
Low-side FET on resistance
Output slew rate
450
TJ = 125 °C, IO = -1 A
700
850
mΩ
TJ = 150 °C, IO = -1 A
780
950
mΩ
TJ = 25 °C, IO = 1 A
450
550
mΩ
TJ = 125 °C, IO = 1 A
700
850
mΩ
TJ = 150 °C, IO = 1 A
780
950
mΩ
VVM = 24 V, IO = 1 A, Between 10% and
90%
240
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Typical values are at TA = 25°C and VVM = 24 V. All limits are over recommended operating conditions, unless otherwise
noted.
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
2.09
2.2
2.31
V/A
8.25
μA
PWM CURRENT CONTROL (VREF)
KV
Transimpedance gain
VREF = 3.3 V
IVREF
VREF Leakage Current
VREF = 3.3 V
tOFF
PWM off-time
ΔITRIP
Current trip accuracy
IO,CH
AOUT and BOUT current
matching
TOFF = 0
7
TOFF = 1
16
TOFF = Hi-Z
24
TOFF = 330 kΩ to GND
32
μs
IO = 1.5 A, 10% to 20% current setting
–15
15
IO = 1.5 A, 20% to 67% current setting
–10
10
IO = 1.5 A, 68% to 100% current setting
–5
5
–2.5
2.5
IO = 1.5 A
%
%
PROTECTION CIRCUITS
VM falling, UVLO falling
4.1
4.25
4.35
VM rising, UVLO rising
4.2
4.35
4.45
VUVLO
VM UVLO lockout
VUVLO,HYS
Undervoltage hysteresis
Rising to falling threshold
VCPUV
Charge pump undervoltage
VCP falling
IOCP
Overcurrent protection
Current through any FET
tOCP
Overcurrent deglitch time
tRETRY
Overcurrent retry time
TOTSD
Thermal shutdown
Die temperature TJ
THYS_OTSD
Thermal shutdown hysteresis
Die temperature TJ
100
mV
VVM + 2
V
1.8
μs
2.5
A
4
150
V
ms
165
180
20
°C
°C
6.6 Indexer Timing Requirements
Typical limits are at TJ = 25°C and VVM = 24 V. Over recommended operating conditions unless otherwise noted.
NO.
(1)
MIN
MAX
UNIT
500(1)
kHz
1
ƒSTEP
Step frequency
2
tWH(STEP)
Pulse duration, STEP high
970
3
tWL(STEP)
Pulse duration, STEP low
970
ns
4
tSU(DIR, Mx)
Setup time, DIR or MODEx to STEP rising
200
ns
5
tH(DIR, Mx)
Hold time, STEP rising to DIR or MODEx change
200
ns
ns
STEP input can operate up to 500 kHz, but system bandwidth is limited by the motor load.
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Figure 6-1. STEP and DIR Timing Diagram
6.7 Typical Characteristics
Figure 6-2. Sleep Current over Supply Voltage
10
Figure 6-3. Sleep Current over Temperature
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Figure 6-4. Operating Current over Supply Voltage
Figure 6-5. Operating Current over Temperature
Figure 6-6. Low-Side RDS(ON) over Supply Voltage
Figure 6-7. Low-Side RDS(ON) over Temperature
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Figure 6-8. High-Side RDS(ON) over Supply Voltage
12
Figure 6-9. High-Side RDS(ON) over Temperature
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7 Detailed Description
7.1 Overview
The DRV8426 is an integrated motor-driver solution for bipolar stepper motors. The device provides the
maximum integration by integrating two N-channel power MOSFET H-bridges, current sense resistors and
regulation circuitry, and a microstepping indexer. The DRV8426 is pin-to-pin compatible with the DRV8424/25,
DRV8436, and the DRV8434. The DRV8426 is capable of supporting wide supply voltage of 4.5 to 33 V. The
device provides an output current up to 2.5-A peak, 1.5-A full-scale, or 1.1-A root mean square (rms). The actual
full-scale and rms current depends on the ambient temperature, supply voltage, and PCB thermal capability.
The DRV8426 uses an integrated current-sense architecture which eliminates the need for two external power
sense resistors, hence saving significant board space, BOM cost, design efforts and reduces significant power
consumption. This architecture removes the power dissipated in the sense resistors by using a current mirror
approach and using the internal power MOSFETs for current sensing. The current regulation set point is adjusted
by the voltage at the VREF pin.
A simple STEP/DIR interface allows for an external controller to manage the direction and step rate of the
stepper motor. The internal microstepping indexer can execute high-accuracy micro-stepping without requiring
the external controller to manage the winding current level. The indexer is capable of full step, half step, and 1/4,
1/8, 1/16, 1/32, 1/64, 1/128, and 1/256 microstepping. High microstepping contributes to significant audible noise
reduction and smooth motion. In addition to a standard half stepping mode, a noncircular half stepping mode is
available for increased torque output at higher motor RPM.
Stepper motor drivers need to re-circulate the winding current by implementing several types of decay modes,
like slow decay, mixed decay and fast decay. The DRV8426 comes with smart tune decay modes. The smart
tune is an innovative decay mechanism that automatically adjusts for optimal current regulation performance
agnostic of voltage, motor speed, variation and aging effects. Smart tune Ripple Control uses a variable off-time,
ripple current control scheme to minimize distortion of the motor winding current. Smart tune Dynamic Decay
uses a fixed off-time, dynamic fast decay percentage scheme to minimize distortion of the motor winding current
while minimizing frequency content and significantly reducing design efforts. Along with this seamless, effortless
automatic smart tune, DRV8426 also provides the traditional decay modes like slow-mixed and mixed decay as
well.
A low-power sleep mode is included which allows the system to save power when not actively driving the motor.
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7.2 Functional Block Diagram
Figure 7-1.
7.3 Feature Description
Table 7-1 lists the recommended external components for the DRV8426 device.
14
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Table 7-1. DRV8426 External Components
COMPONENT
PIN 1
PIN 2
CVM1
VM
PGND
CVM2
VM
PGND
CCP
VCP
VM
RECOMMENDED
Two X7R, 0.01-µF, VM-rated ceramic capacitors
Bulk, VM-rated capacitor
X7R, 0.22-µF, 16-V ceramic capacitor
CSW
CPH
CPL
X7R, 0.022-µF, VM-rated ceramic capacitor
CDVDD
DVDD
GND
X7R, 0.47-µF to 1-µF, 6.3-V ceramic capacitor
RnFAULT
VCC (1)
nFAULT
RREF1
VREF
VCC
RREF2 (Optional)
VREF
GND
(1)
>4.7-kΩ resistor
Resistor to limit chopping current. It is recommended that the value of parallel
combination of RREF1 and RREF2 should be less than 50-kΩ.
VCC is not a pin on the DRV8426 device, but a VCC supply voltage pullup is required for open-drain output nFAULT; nFAULT may be
pulled up to DVDD.
7.3.1 Stepper Motor Driver Current Ratings
Stepper motor drivers can be classified using three different numbers to describe the output current: peak, RMS,
and full-scale.
7.3.1.1 Peak Current Rating
The peak current in a stepper driver is limited by the overcurrent protection trip threshold IOCP. The peak current
describes any transient duration current pulse, for example when charging capacitance, when the overall duty
cycle is very low. In general the minimum value of IOCP specifies the peak current rating of the stepper motor
driver. For the DRV8426 device, the peak current rating is 2.5A per bridge.
7.3.1.2 RMS Current Rating
The RMS (average) current is determined by the thermal considerations of the IC. The RMS current is calculated
based on the RDS(ON), rise and fall time, PWM frequency, device quiescent current, and package thermal
performance in a typical system at 25°C. The actual operating RMS current may be higher or lower depending
on heatsinking and ambient temperature. For the DRV8426 device, the RMS current rating is 1.1 A per bridge.
7.3.1.3 Full-Scale Current Rating
The full-scale current describes the top of the sinusoid current waveform while microstepping. Because the
sinusoid amplitude is related to the RMS current, the full-scale current is also determined by the thermal
considerations of the device. The full-scale current rating is approximately √2 × IRMS for a sinusoidal current
waveform, and IRMS for a square wave current waveform (full step).
Full-scale current
Output Current
RMS current
AOUT
BOUT
Step Input
Figure 7-2. Full-Scale and RMS Current
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7.3.2 PWM Motor Drivers
The DRV8426 device has drivers for two full H-bridges to drive the two windings of a bipolar stepper motor.
Figure 7-3 shows a block diagram of the circuitry.
Figure 7-3. PWM Motor Driver Block Diagram
7.3.3 Microstepping Indexer
Built-in indexer logic in the DRV8426 device allows a number of different step modes. The M0 and M1 pins are
used to configure the step mode as shown in Table 7-2. The settings can be changed on the fly.
Table 7-2. Microstepping Indexer Settings
16
MODE0
MODE1
STEP MODE
0
0
Full step (2-phase excitation) with 100%
current
0
330kΩ to
GND
Full step (2-phase excitation) with 71%
current
1
0
Non-circular 1/2 step
Hi-Z
0
1/2 step
0
1
1/4 step
1
1
1/8 step
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Table 7-2. Microstepping Indexer Settings
(continued)
MODE0
MODE1
STEP MODE
Hi-Z
1
1/16 step
0
Hi-Z
1/32 step
Hi-Z
330kΩ to
GND
1/64 step
Hi-Z
Hi-Z
1/128 step
1
Hi-Z
1/256 step
Table 7-3 shows the relative current and step directions for full-step (71% current), 1/2 step, 1/4 step and 1/8
step operation. Higher microstepping resolutions follow the same pattern. The AOUT current is the sine of the
electrical angle and the BOUT current is the cosine of the electrical angle. Positive current is defined as current
flowing from the xOUT1 pin to the xOUT2 pin while driving.
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 logic high. If the DIR pin is logic low, the sequence is reversed.
Note
If the step mode is changed on the fly while stepping, the indexer advances to the next valid state for
the new step mode setting at the rising edge of STEP.
The initial excitation state is an electrical angle of 45°, corresponding to 71% of full-scale current in both coils.
This state is entered after power-up, after exiting logic undervoltage lockout, or after exiting sleep mode.
Table 7-3. Relative Current and Step Directions
1/8 STEP
1/4 STEP
1/2 STEP
1
1
1
FULL
STEP
71%
2
3
2
4
5
3
2
1
6
7
4
8
9
5
3
10
11
6
12
13
7
4
2
14
15
8
16
17
9
5
18
19
10
20
21
11
6
22
3
AOUT CURRENT
(% FULL-SCALE)
BOUT CURRENT
(% FULL-SCALE)
ELECTRICAL
ANGLE (DEGREES)
0%
100%
0.00
20%
98%
11.25
38%
92%
22.50
56%
83%
33.75
71%
71%
45.00
83%
56%
56.25
92%
38%
67.50
98%
20%
78.75
100%
0%
90.00
98%
-20%
101.25
92%
-38%
112.50
83%
-56%
123.75
71%
-71%
135.00
56%
-83%
146.25
38%
-92%
157.50
20%
-98%
168.75
0%
-100%
180.00
-20%
-98%
191.25
-38%
-92%
202.50
-56%
-83%
213.75
-71%
-71%
225.00
-83%
-56%
236.25
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Table 7-3. Relative Current and Step Directions (continued)
1/8 STEP
1/4 STEP
23
12
FULL
STEP
71%
1/2 STEP
24
25
13
7
26
27
14
28
29
15
8
4
30
31
16
32
AOUT CURRENT
(% FULL-SCALE)
BOUT CURRENT
(% FULL-SCALE)
ELECTRICAL
ANGLE (DEGREES)
-92%
-38%
247.50
-98%
-20%
258.75
-100%
0%
270.00
-98%
20%
281.25
-92%
38%
292.50
-83%
56%
303.75
-71%
71%
315.00
-56%
83%
326.25
-38%
92%
337.50
-20%
98%
348.75
Table 7-4 shows the full step operation with 100% full-scale current. This stepping mode consumes more power
than full-step mode with 71% current, but provides a higher torque at high motor RPM.
Table 7-4. Full Step with 100% Current
FULL
STEP
100%
AOUT CURRENT
(% FULL-SCALE)
BOUT CURRENT
(% FULL-SCALE)
ELECTRICAL ANGLE
(DEGREES)
1
100
100
45
2
100
-100
135
3
-100
-100
225
4
-100
100
315
Table 7-5 shows the noncircular 1/2–step operation. This stepping mode consumes more power than circular
1/2-step operation, but provides a higher torque at high motor RPM.
Table 7-5. Non-Circular 1/2-Stepping Current
NON-CIRCULAR 1/2-STEP
AOUT CURRENT
(% FULL-SCALE)
BOUT CURRENT
(% FULL-SCALE)
ELECTRICAL ANGLE
(DEGREES)
1
0
100
0
2
100
100
45
3
100
0
90
4
100
–100
135
5
0
–100
180
6
–100
–100
225
7
–100
0
270
8
–100
100
315
7.3.4 Controlling VREF with an MCU DAC
In some cases, the full-scale output current may need to be changed between many different values, depending
on motor speed and loading. The voltage of the VREF pin can be adjusted in the system to change the full-scale
current.
In this mode of operation, as the DAC voltage increases, the full-scale regulation current increases as well. For
proper operation, the output of the DAC should not rise above 3.3V for DRV8426.
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Figure 7-4. Controlling VREF with a DAC Resource
The VREF pin can also be adjusted using a PWM signal and low-pass filter.
Figure 7-5. Controlling VREF With a PWM Resource
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7.3.5 Current Regulation
The current through the motor windings is regulated by an adjustable, off-time PWM current-regulation circuit.
When an H-bridge is enabled, current rises through the winding at a rate dependent on the DC voltage,
inductance of the winding, and the magnitude of the back EMF present. When the current hits the current
regulation threshold, the bridge enters a decay mode for a period of time determined by the TOFF pin setting to
decrease the current. After the off-time expires, the bridge is re-enabled, starting another PWM cycle.
Figure 7-6. Current Chopping Waveform
The PWM regulation current is set by a comparator which monitors the voltage across the current sense
MOSFETs in parallel with the low-side power MOSFETs. The current sense MOSFETs are biased with a
reference current that is the output of a current-mode sine-weighted DAC whose full-scale reference current is
set by the voltage at the VREF pin.
The full-scale regulation current (IFS) can be calculated as IFS (A) = VREF (V) / KV (V/A) = VREF (V) / 2.2 (V/A).
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7.3.6 Decay Modes
During PWM current chopping, the H-bridge is enabled to drive through the motor winding until the PWM current
chopping threshold is reached. This is shown in Figure 7-7, Item 1.
Once the chopping current threshold is reached, 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 a reverse direction. The opposite FETs are turned on; as the winding
current approaches zero, the bridge is disabled to prevent any reverse current flow. Fast decay mode is shown
in Figure 7-7, item 2. In slow decay mode, winding current is re-circulated by enabling both of the low-side FETs
in the bridge. This is shown in Figure 7-7, Item 3.
Figure 7-7. Decay Modes
The decay mode of the DRV8426 is selected by the DECAY0 and DECAY1 pins as shown in Table 7-6. If
DECAY1 pin is Hi-Z, irrespective of the DECAY0 pin voltage, the decay mode will be smart tune dynamic decay.
The decay modes can be changed on the fly. After a decay mode change, the new decay mode is applied after a
10 µs de-glitch time.
Table 7-6. Decay Mode Settings
DECAY0
DECAY1
INCREASING STEPS
DECREASING
STEPS
0
0
Smart tune Dynamic
Decay
Smart tune Dynamic
Decay
0
1
Smart tune Ripple
Control
Smart tune Ripple
Control
1
0
Mixed decay: 30%
fast
Mixed decay: 30%
fast
1
1
Slow decay
Mixed decay: 30%
fast
Hi-Z
0
Mixed decay: 60%
fast
Mixed decay: 60%
fast
Hi-Z
1
Slow decay
Slow decay
Figure 7-8 defines increasing and decreasing current. For the slow-mixed decay mode, the decay mode is
set as slow during increasing current steps and mixed decay during decreasing current steps. In full step and
noncircular 1/2-step operation, the decay mode corresponding to decreasing steps is always used.
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AOUT Current
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Increasing
Decreasing
Increasing
Decreasing
STEP Input
BOUT Current
AOUT Current
Decreasing
Increasing
Increasing
Decreasing
STEP Input
Figure 7-8. Definition of Increasing and Decreasing Steps
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7.3.6.1 Slow Decay for Increasing and Decreasing Current
Increasing Phase Current (A)
ITRIP
tBLANK
tOFF
tBLANK
tOFF
tDRIVE
Decreasing Phase Current (A)
tDRIVE
ITRIP
tBLANK
tOFF
tDRIVE
tBLANK
tDRIVE
tOFF
tBLANK
tDRIVE
Figure 7-9. Slow/Slow Decay Mode
During slow decay, both of the low-side FETs of the H-bridge are turned on, allowing the current to be
recirculated.
Slow decay exhibits the least current ripple of the decay modes for a given tOFF. However on decreasing current
steps, slow decay will take a long time to settle to the new ITRIP level because the current decreases very
slowly.
In cases where current is held for a long time (no input in the STEP pin) or at very low stepping speeds, slow
decay may not properly regulate current because no back-EMF is present across the motor windings. In this
state, motor current can rise very quickly, and may require a large off-time. In some cases this may cause a loss
of current regulation, and a more aggressive decay mode is recommended.
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7.3.6.2 Slow Decay for Increasing Current, Mixed Decay for Decreasing Current
Increasing Phase Current (A)
ITRIP
tBLANK
tOFF
tBLANK
tOFF
tDRIVE
Decreasing Phase Current (A)
tDRIVE
tBLANK
tDRIVE
ITRIP
tBLANK
tFAST
tDRIVE
tBLANK
tOFF
tFAST
tDRIVE
tOFF
Figure 7-10. Slow-Mixed Decay Mode
Mixed decay begins as fast decay for a time, followed by slow decay for the remainder of the tOFF time. In this
mode, mixed decay only occurs during decreasing current. Slow decay is used for increasing current.
This mode exhibits the same current ripple as slow decay for increasing current, because for increasing current,
only slow decay is used. For decreasing current, the ripple is larger than slow decay, but smaller than fast decay.
On decreasing current steps, mixed decay settles to the new ITRIP level faster than slow decay.
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7.3.6.3 Mixed Decay for Increasing and Decreasing Current
Increasing Phase Current (A)
ITRIP
tOFF
tBLANK
tOFF
tDRIVE
Decreasing Phase Current (A)
tDRIVE
tBLANK
tDRIVE
ITRIP
tBLANK
tDRIVE
tFAST
tBLANK
tOFF
tFAST
tDRIVE
tOFF
Figure 7-11. Mixed-Mixed Decay Mode
Mixed decay begins as fast decay for a time, followed by slow decay for the remainder of tOFF. In this mode,
mixed decay occurs for both increasing and decreasing current steps.
This mode exhibits ripple larger than slow decay, but smaller than fast decay. On decreasing current steps,
mixed decay settles to the new ITRIP level faster than slow decay.
In cases where current is held for a long time (no input in the STEP pin) or at very low stepping speeds, slow
decay may not properly regulate current because no back-EMF is present across the motor windings. In this
state, motor current can rise very quickly, and requires an excessively large off-time. Increasing or decreasing
mixed decay mode allows the current level to stay in regulation when no back-EMF is present across the motor
windings.
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7.3.6.4 Smart tune Dynamic Decay
The smart tune current regulation schemes are advanced current-regulation control methods compared to
traditional fixed off-time current regulation schemes. Smart tune current regulation schemes help the stepper
motor driver adjust the decay scheme based on operating factors such as the ones listed as follows:
•
•
•
•
•
•
•
Motor winding resistance and inductance
Motor aging effects
Motor dynamic speed and load
Motor supply voltage variation
Motor back-EMF difference on rising and falling steps
Step transitions
Low-current versus high-current dI/dt
The device provides two different smart tune current regulation modes, named smart tune Dynamic Decay and
smart tune Ripple Control.
Increasing Phase Current (A)
ITRIP
tBLANK
tBLANK
tOFF
tBLANK
tOFF
tDRIVE
tDRIVE
tDRIVE
Decreasing Phase Current (A)
ITRIP
tBLANK
tOFF
tDRIVE
tBLANK
tDRIVE
tBLANK
tOFF
tFAST
tDRIVE
tFAST
Figure 7-12. Smart tune Dynamic Decay Mode
Smart tune Dynamic Decay greatly simplifies the decay mode selection by automatically configuring the decay
mode between slow, mixed, and fast decay. In mixed decay, smart tune dynamically adjusts the fast decay
percentage of the total mixed decay time. This feature eliminates motor tuning by automatically determining the
best decay setting that results in the lowest ripple for the motor.
The decay mode setting is optimized iteratively each PWM cycle. If the motor current overshoots the target trip
level, then the decay mode becomes more aggressive (add fast decay percentage) on the next cycle to prevent
regulation loss. If a long drive time must occur to reach the target trip level, the decay mode becomes less
aggressive (remove fast decay percentage) on the next cycle to operate with less ripple and more efficiently. On
falling steps, smart tune Dynamic Decay automatically switches to fast decay to reach the next step quickly.
Smart tune Dynamic Decay is optimal for applications that require minimal current ripple but want to maintain a
fixed frequency in the current regulation scheme.
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7.3.6.5 Smart tune Ripple Control
Increasing Phase Current (A)
ITRIP
IVALLEY
tBLANK
tBLANK
tOFF
tBLANK
tOFF
tDRIVE
Decreasing Phase Current (A)
tDRIVE
tBLANK
tOFF
tDRIVE
tDRIVE
ITRIP
IVALLEY
tBLANK
tOFF
tBLANK
tOFF
tBLANK
tDRIVE
tDRIVE
tOFF
tDRIVE
Figure 7-13. Smart tune Ripple Control Decay Mode
Smart tune Ripple Control operates by setting an IVALLEY level alongside the ITRIP level. When the current level
reaches ITRIP, instead of entering slow decay until the t OFF time expires, the driver enters slow decay until I VALLEY
is reached. Slow decay operates similar to mode 1 in which both low-side MOSFETs are turned on allowing the
current to recirculate. In this mode, tOFF varies depending on the current level and operating conditions.
The ripple current in this decay mode is programmed by the TOFF pin. The ripple current is dependent on the
ITRIP of a particular microstep level.
Table 7-7. Current Ripple Settings
TOFF
Current Ripple at a specific microstep level
0
11mA + 1% of ITRIP
1
11mA + 2% of ITRIP
Hi-Z
11mA + 4% of ITRIP
330kΩ to GND
11mA + 6% of ITRIP
The ripple control method allows much tighter regulation of the current level increasing motor efficiency and
system performance. Smart tune Ripple Control can be used in systems that can tolerate a variable off-time
regulation scheme to achieve small current ripple in the current regulation. Select a low ripple current setting to
ensure that the PWM frequency is not in the audible range. However, higher values of ripple current reduces the
PWM frequency and therefore the switching loss.
7.3.6.6 PWM OFF Time
The TOFF pin configures the PWM OFF time for all decay modes except smart tune ripple control, as shown in
Table 7-6. The OFF time settings can be changed on the fly. After a OFF time setting change, the new OFF time
is applied after a 10 µs de-glitch time.
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Table 7-8. OFF Time Settings
TOFF
OFF Time
0
7 µs
1
16 µs
Hi-Z
24 µs
330kΩ to GND
32 µs
7.3.6.7 Blanking time
After the current is enabled (start of drive phase) in an H-bridge, the current sense comparator is ignored for a
period of time (tBLANK) before enabling the current-sense circuitry. The blanking time also sets the minimum drive
time of the PWM. The blanking time is approximately 1 µs.
7.3.7 Charge Pump
A charge pump is integrated to supply a high-side N-channel MOSFET gate-drive voltage. The charge pump
requires a capacitor between the VM and VCP pins to act as the storage capacitor. Additionally a ceramic
capacitor is required between the CPH and CPL pins to act as the flying capacitor.
Figure 7-14. Charge Pump Block Diagram
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7.3.8 Linear Voltage Regulators
A linear voltage regulator is integrated in the DRV8426 device. The DVDD regulator can be used to provide a
reference voltage. DVDD can supply a maximum of 2mA load. For proper operation, bypass the DVDD pin to
GND using a ceramic capacitor.
The DVDD output is nominally 5-V. When the DVDD LDO current load exceeds 2mA, the output voltage drops
significantly.
Figure 7-15. Linear Voltage Regulator Block Diagram
If a digital input must be tied permanently high (that is, Mx, DECAYx or TOFF), tying the input to the DVDD pin
instead of an external regulator is preferred. This method saves power when the VM pin is not applied or in
sleep mode: the DVDD regulator is disabled and current does not flow through the input pulldown resistors. For
reference, logic level inputs have a typical pulldown of 200 kΩ.
The nSLEEP pin cannot be tied to DVDD, else the device will never exit sleep mode.
7.3.9 Logic Level, tri-level and quad-level Pin Diagrams
Figure 7-16 shows the input structure for M0, DECAY0, DECAY1 and ENABLE pins.
Figure 7-16. Tri-Level Input Pin Diagram
Figure 7-16 shows the input structure for M1 and TOFF pins.
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Figure 7-17. Quad-Level Input Pin Diagram
Figure 7-18 shows the input structure for STEP, DIR and nSLEEP pins.
Figure 7-18. Logic-Level Input Pin Diagram
7.3.10 nFAULT Pin
The nFAULT pin has an open-drain output and should be pulled up to a 5-V, 3.3-V or 1.8-V supply. When a
fault is detected, the nFAULT pin will be logic low. nFAULT pin will be high after power-up. For a 5-V pullup, the
nFAULT pin can be tied to the DVDD pin with a resistor. For a 3.3-V or 1.8-V pullup, an external supply must be
used.
Output
nFAULT
Figure 7-19. nFAULT Pin
7.3.11 Protection Circuits
The DRV8426 device is fully protected against supply undervoltage, charge pump undervoltage, output
overcurrent, and device overtemperature events.
7.3.11.1 VM Undervoltage Lockout (UVLO)
If at any time the voltage on the VM pin falls below the UVLO-threshold voltage for the voltage supply, all
the outputs are disabled, and the nFAULT pin is driven low. The charge pump is disabled in this condition.
Normal operation resumes (motor-driver operation and nFAULT released) when the VM undervoltage condition
is removed.
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7.3.11.2 VCP Undervoltage Lockout (CPUV)
If at any time the voltage on the VCP pin falls below the CPUV voltage, all the outputs are disabled, and the
nFAULT pin is driven low. The charge pump remains active during this condition. Normal operation resumes
(motor-driver operation and nFAULT released) when the VCP undervoltage condition is removed.
7.3.11.3 Overcurrent Protection (OCP)
An analog current-limit circuit on each FET limits the current through the FET by removing the gate drive. If this
current limit persists for longer than the tOCP time, the FETs in both H-bridges are disabled and the nFAULT pin is
driven low. The charge pump remains active during this condition. The overcurrent protection can operate in two
different modes: latched shutdown and automatic retry. The operating modes can be changed on the fly.
7.3.11.3.1 Latched Shutdown
The ENABLE pin of the DRV8426 has to be made Hi-Z to select latched shutdown mode. In this mode, after
an OCP event, the outputs are disabled and the nFAULT pin is driven low. Once the OCP condition is removed,
normal operation resumes after applying an nSLEEP reset pulse or a power cycling.
7.3.11.3.2 Automatic Retry
The ENABLE pin of the DRV8424/25 has to be HIGH (>2.7V) to select automatic retry mode. In this mode,
after an OCP event the outputs are disabled and the nFAULT pin is driven low. Normal operation resumes
automatically (motor-driver operation and nFAULT released) after the tRETRY time has elapsed and the fault
condition is removed.
7.3.11.4 Thermal Shutdown (OTSD)
If the die temperature exceeds the thermal shutdown limit (TOTSD) all MOSFETs in the H-bridge are disabled,
and the nFAULT pin is driven low. The charge pump is disabled during this condition. The thermal shutdown
protection can operate in two different modes: latched shutdown and automatic retry. The operating modes can
be changed on the fly.
7.3.11.4.1 Latched Shutdown
The ENABLE pin of the DRV8426 has to be made Hi-Z to select latched shutdown mode. In this mode, after an
OTSD event, the relevant outputs are disabled and the nFAULT pin is driven low. After the junction temperature
falls below the overtemperature threshold limit minus the hysteresis (TOTSD – THYS_OTSD), normal operation
resumes after applying an nSLEEP reset pulse or a power cycling.
7.3.11.4.2 Automatic Retry
The ENABLE pin of the DRV8424/25 has to be HIGH (>2.7V) to select automatic retry mode. In this mode, after
a OTSD event all the outputs are disabled and the nFAULT pin is driven low. Normal operation resumes (motordriver operation and the nFAULT line released) when the junction temperature falls below the overtemperature
threshold limit minus the hysteresis (TOTSD – THYS_OTSD).
7.3.11.5 Fault Condition Summary
Table 7-9. Fault Condition Summary
FAULT
CONDITION
CONFIGU
RATION
ERROR
REPORT
H-BRIDGE CHARGE
PUMP
INDEXER
LOGIC
RECOVERY
VM undervoltage
(UVLO)
VM < VUVLO
—
nFAULT
Disabled
Disabled
Disabled
Reset
(VDVDD <
3.9 V)
Automatic: VM >
VUVLO
VCP undervoltage
(CPUV)
VCP < VCPUV
—
nFAULT
Disabled
Operating
Operating
Operating
VCP > VCPUV
ENABLE =
Hi-Z
nFAULT
Disabled
Operating
Operating
Operating
Latched
ENABLE =
1
nFAULT
Disabled
Operating
Operating
Operating
Automatic retry:
tRETRY
Overcurrent (OCP)
IOUT > IOCP
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Table 7-9. Fault Condition Summary (continued)
FAULT
CONDITION
Thermal Shutdown
(OTSD)
CONFIGU
RATION
TJ > TTSD
ERROR
REPORT
H-BRIDGE CHARGE
PUMP
INDEXER
LOGIC
RECOVERY
ENABLE =
Hi-Z
nFAULT
Disabled
Disabled
Operating
Operating
Latched
ENABLE =
1
nFAULT
Disabled
Disabled
Operating
Operating
Automatic: TJ <
TOTSD - THYS_OTSD
7.4 Device Functional Modes
7.4.1 Sleep Mode (nSLEEP = 0)
The DRV8426 device state is managed by the nSLEEP pin. When the nSLEEP pin is low, the DRV8426 device
enters a low-power sleep mode. In sleep mode, all the internal MOSFETs are disabled and the charge pump is
disabled. The tSLEEP time must elapse after a falling edge on the nSLEEP pin before the device enters sleep
mode. The DRV8426 device is brought out of sleep automatically if the nSLEEP pin is brought high. The tWAKE
time must elapse before the device is ready for inputs.
7.4.2 Disable Mode (nSLEEP = 1, ENABLE = 0)
The ENABLE pin is used to enable or disable the DRV8426 device. When the ENABLE pin is low, the output
drivers are disabled in the Hi-Z state.
7.4.3 Operating Mode (nSLEEP = 1, ENABLE = Hi-Z/1)
When the nSLEEP pin is high, the ENABLE pin is Hi-Z or 1, and VM > UVLO, the device enters the active mode.
The tWAKE time must elapse before the device is ready for inputs.
7.4.4 nSLEEP Reset Pulse
A latched fault can be cleared through a quick nSLEEP pulse. This pulse width must be greater than 20 µs and
shorter than 40 µs. If nSLEEP is low for longer than 40 µs but less than 120 µs, the faults are cleared and the
device may or may not shutdown, as shown in the timing diagram (see Figure 7-20). This reset pulse does not
affect the status of the charge pump or other functional blocks.
Figure 7-20. nSLEEP Reset Pulse
7.4.5 Functional Modes Summary
Table 7-10 lists a summary of the functional modes.
Table 7-10. Functional Modes Summary
CONDITION
CONFIGURA
TION
H-BRIDGE
DVDD
Regulator
CHARGE PUMP
INDEXER
Logic
Sleep mode
4.5 V < VM < 33 V
nSLEEP pin =
0
Disabled
Disabled
Disabled
Disabled
Disabled
Operating
4.5 V < VM < 33 V
nSLEEP pin =
1
ENABLE pin =
1 or Hi-Z
Operating
Operating
Operating
Operating
Operating
32
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Table 7-10. Functional Modes Summary (continued)
CONDITION
Disabled
CONFIGURA
TION
4.5 V < VM < 33 V
nSLEEP pin =
1
ENABLE pin =
0
H-BRIDGE
Disabled
DVDD
Regulator
Operating
CHARGE PUMP
Operating
INDEXER
Operating
Logic
Operating
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8 Application and Implementation
Note
Information in the following applications sections is not part of the TI component specification, and
TI does not warrant its accuracy or completeness. TI’s customers are responsible for determining
suitability of components for their purposes. Customers should validate and test their design
implementation to confirm system functionality.
8.1 Application Information
The DRV8426 is used in bipolar stepper control.
8.2 Typical Application
The following design procedure can be used to configure the DRV8426 device.
Figure 8-1. Typical Application Schematic (1/8 microstepping, smart tune Ripple Control Decay, HTSSOP
package)
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Figure 8-2. Typical Application Schematic (1/8 microstepping, smart tune Ripple Control Decay, VQFN
package)
8.2.1 Design Requirements
Table 8-1 lists the design input parameters for a typical application.
Table 8-1. Design Parameters
DESIGN PARAMETER
REFERENCE
EXAMPLE VALUE
Supply voltage
VM
Motor winding resistance
RL
2.4 Ω/phase
Motor winding inductance
LL
5.8 mH/phase
θstep
1.8°/step
nm
1/8 step
v
18.75 rpm
IFS
1A
Motor full step angle
Target microstepping level
Target motor speed
Target full-scale current
24 V
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8.2.2 Detailed Design Procedure
8.2.2.1 Stepper Motor Speed
The first step in configuring the DRV8426 device 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 speed is too high, the motor does not spin. Make sure that the motor can support
the target speed. Use Equation 1 to calculate ƒstep for a desired motor speed (v), microstepping level (nm), and
motor full step angle (θstep)
¦step VWHSV V
v (rpm) u 360 (q / rot)
Tstep (q / step) u nm (steps / microstep) u 60 (s / min)
(1)
The value of θstep can be found in the stepper motor data sheet, or written on the motor. For example, the
motor in this application is required to rotate at 1.8°/step for a target of 18.75 rpm at 1/8 microstep mode. Using
Equation 1, ƒstep can be calculated as 500 Hz.
The microstepping level is set by the M0 and M1 pins and can be any of the settings listed in Table 8-2. Higher
microstepping results in a smoother motor motion and less audible noise, but requires a higher ƒstep to achieve
the same motor speed.
Table 8-2. Microstepping Indexer Settings
MODE0
MODE1
STEP MODE
0
0
Full step (2-phase excitation) with 100%
current
0
330kΩ to
GND
Full step (2-phase excitation) with 71%
current
1
0
Non-circular 1/2 step
Hi-Z
0
1/2 step
0
1
1/4 step
1
1
1/8 step
Hi-Z
1
1/16 step
0
Hi-Z
1/32 step
Hi-Z
330kΩ to
GND
1/64 step
Hi-Z
Hi-Z
1/128 step
1
Hi-Z
1/256 step
8.2.2.2 Current Regulation
In a stepper motor, the full-scale current (IFS) is the maximum current driven through either winding. This quantity
depends on the VREF voltage. The maximum allowable voltage on the VREF pin is 3.3V for DRV8426. DVDD
can be used to provide VREF through a resistor divider. During stepping, IFS defines the current chopping
threshold (ITRIP) for the maximum current step. IFS (A) = VREF (V) / 2.2 (V/A)
8.2.2.3 Decay Modes
The DRV8426 device supports six different decay modes, as shown in Table 7-6. When a motor winding current
has hit the current chopping threshold (ITRIP), the DRV8426 places the winding in one of the six decay modes for
tOFF. After tOFF, a new drive phase starts.
36
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8.2.3 Thermal Application
This section presents the power dissipation calculation and junction temperature estimation of the device.
8.2.3.1 Power Dissipation
The total power dissipation constitutes of three main components - conduction loss (PCOND), switching loss
(PSW) and power loss due to quiescent current consumption (PQ).
8.2.3.1.1 Conduction Loss
The current path for a motor connected in full-bridge is through the high-side FET of one half-bridge and
low-side FET of the other half-bridge. The conduction loss (PCOND) depends on the motor rms current (IRMS) and
high-side (RDS(ONH)) and low-side (RDS(ONL)) on-state resistances as shown in Equation 2.
PCOND = 2 x (IRMS)2 x (RDS(ONH) + RDS(ONL))
(2)
The conduction loss for the typical application shown in Table 8-2 is calculated in Equation 3.
PCOND = 2 x (IRMS)2 x (RDS(ONH) + RDS(ONL)) = 2 x (1-A / √2)2 x (0.45-Ω + 0.45-Ω) = 0.9-W
(3)
Note
This power calculation is highly dependent on the device temperature which significantly effects
the high-side and low-side on-resistance of the FETs. For more accurate calculation, consider the
dependency of on-resistance of FETs with device temperature.
8.2.3.1.2 Switching Loss
The power loss due to the PWM switching frequency depends on the slew rate (tSR), supply voltage, motor RMS
current and the PWM switching frequency. The switching losses in each H-bridge during rise-time and fall-time
are calculated as shown in Equation 4 and Equation 5.
PSW_RISE = 0.5 x VVM x IRMS x tRISE_PWM x fPWM
(4)
PSW_FALL = 0.5 x VVM x IRMS x tFALL_PWM x fPWM
(5)
Both tRISE_PWM and tFALL_PWM can be approximated as VVM/ tSR. After substituting the values of various
parameters, and assuming 30-kHz PWM frequency, the switching losses in each H-bridge are calculated as
shown below PSW_RISE = 0.5 x 24-V x (1-A / √2) x (24-V / 240 V/µs) x 30-kHz = 0.025-W
(6)
PSW_FALL = 0.5 x 24-V x (1-A / √2) x (24-V / 240 V/µs) x 30-kHz = 0.025-W
(7)
The total switching loss for the stepper motor driver (PSW) is calculated as twice the sum of rise-time (PSW_RISE)
switching loss and fall-time (PSW_FALL) switching loss as shown below PSW = 2 x (PSW_RISE + PSW_FALL) = 2 x (0.025-W + 0.025-W) = 0.1-W
(8)
Note
The rise-time (tRISE) and the fall-time (tFALL) are calculated based on typical values of the slew rate
(tSR). This parameter is expected to change based on the supply-voltage, temperature and device to
device variation.
The switching loss is directly proportional to the PWM switching frequency. The PWM frequency in an
application will depend on the supply voltage, inductance of the motor coil, back emf voltage and OFF
time or the ripple current (for smart tune ripple control decay mode).
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8.2.3.1.3 Power Dissipation Due to Quiescent Current
The power dissipation due to the quiescent current consumed by the power supply is calculated as shown below
PQ = VVM x IVM
(9)
Substituting the values, quiescent power loss can be calculated as shown below PQ = 24-V x 5-mA = 0.12-W
(10)
Note
The quiescent power loss is calculated using the typical operating supply current (IVM) which is
dependent on supply-voltage, temperature and device to device variation.
8.2.3.1.4 Total Power Dissipation
The total power dissipation (PTOT) is calculated as the sum of conduction loss, switching loss and the quiescent
power loss as shown in Equation 11.
PTOT = PCOND + PSW + PQ = 0.9-W + 0.1-W + 0.12-W = 1.12-W
(11)
8.2.3.2 Device Junction Temperature Estimation
For an ambient temperature of TA and total power dissipation (PTOT), the junction temperature (TJ) is calculated
as TJ = TA + (PTOT x RθJA)
Considering a JEDEC standard 4-layer PCB, the junction-to-ambient thermal resistance (RθJA) is 33 °C/W for the
HTSSOP package and 43 °C/W for the VQFN package.
Assuming 25°C ambient temperature, the junction temperature for the HTSSOP package is calculated as shown
below TJ = 25°C + (1.12-W x 33°C/W) = 61.96 °C
(12)
The junction temperature for the VQFN package is calculated as shown below TJ = 25°C + (1.12-W x 43°C/W) = 73.16 °C
38
(13)
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9 Power Supply Recommendations
The DRV8426 device is designed to operate from an input voltage supply (VM) range from 4.5 V to 33 V. A
0.01-µF ceramic capacitor rated for VM must be placed at each VM pin as close to the DRV8426 device as
possible. In addition, a bulk capacitor must be included on VM.
9.1 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 power supply’s capacitance and ability to source 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.
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.
Power Supply
Parasitic Wire
Inductance
Motor Drive System
VM
+
±
+
Motor
Driver
GND
Local
Bulk Capacitor
IC Bypass
Capacitor
Copyright © 2016, Texas Instruments Incorporated
Figure 9-1. Example Setup of Motor Drive System With External Power Supply
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10 Layout
10.1 Layout Guidelines
The VM pin should be bypassed to PGND using a low-ESR ceramic bypass capacitor 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 PGND pin.
The VM pin must be bypassed to PGND using a bulk capacitor rated for VM. This component can be an
electrolytic capacitor.
A low-ESR ceramic capacitor must be placed in between the CPL and CPH pins. A value of 0.022 µF rated for
VM is recommended. Place this component as close to the pins as possible.
A low-ESR ceramic capacitor must be placed in between the VM and VCP pins. A value of 0.22 µF rated for 16
V is recommended. Place this component as close to the pins as possible.
Bypass the DVDD pin to ground with a low-ESR ceramic capacitor. A value of 0.47 µF rated for 6.3 V is
recommended. Place this bypassing capacitor as close to the pin as possible.
The thermal PAD must be connected to system ground.
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11 Device and Documentation Support
11.1 Receiving Notification of Documentation Updates
To receive notification of documentation updates, navigate to the device product folder on ti.com. In the upper
right corner, click on Alert me to register and receive a weekly digest of any product information that has
changed. For change details, review the revision history included in any revised document.
11.2 Community Resources
11.3 Trademarks
All trademarks are the property of their respective owners.
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12 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.
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PACKAGE OUTLINE
PWP0028M
TM
PowerPAD TSSOP - 1.2 mm max height
SCALE 2.000
SMALL OUTLINE PACKAGE
C
6.6
TYP
6.2
A
0.1 C
PIN 1 INDEX
AREA
SEATING
PLANE
26X 0.65
28
1
2X
9.8
9.6
NOTE 3
8.45
14
15
0.30
0.19
0.1
C A B
28X
4.5
4.3
B
SEE DETAIL A
(0.15) TYP
2X 0.82 MAX
NOTE 5
14
15
2X 0.825 MAX
NOTE 5
0.25
GAGE PLANE
1.2 MAX
4.05
3.53
THERMAL
PAD
0 -8
0.15
0.05
0.75
0.50
DETAIL A
A 20
TYPICAL
28
1
3.10
2.58
4224480/A 08/2018
PowerPAD is a trademark of Texas Instruments.
NOTES:
1. All linear dimensions are in millimeters. Any dimensions in parenthesis are for reference only. Dimensioning and tolerancing
per ASME Y14.5M.
2. This drawing is subject to change without notice.
3. This dimension does not include mold flash, protrusions, or gate burrs. Mold flash, protrusions, or gate burrs shall not
exceed 0.15 mm per side.
4. Reference JEDEC registration MO-153.
5. Features may differ or may not be present.
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EXAMPLE BOARD LAYOUT
PWP0028M
TM
PowerPAD TSSOP - 1.2 mm max height
SMALL OUTLINE PACKAGE
(3.4)
NOTE 9
(3.1)
METAL COVERED
BY SOLDER MASK
SYMM
28X (1.5)
1
28X (0.45)
28
SEE DETAILS
(R0.05) TYP
26X (0.65)
(4.05)
(0.6)
SYMM
(9.7)
NOTE 9
SOLDER MASK
DEFINED PAD
(1.2) TYP
( 0.2) TYP
VIA
15
14
(1.2) TYP
(5.8)
LAND PATTERN EXAMPLE
EXPOSED METAL SHOWN
SCALE: 8X
SOLDER MASK
OPENING
METAL UNDER
SOLDER MASK
METAL
SOLDER MASK
OPENING
EXPOSED METAL
EXPOSED METAL
0.05 MIN
ALL AROUND
0.05 MAX
ALL AROUND
NON-SOLDER MASK
DEFINED
(PREFERRED)
SOLDER MASK
DEFINED
SOLDER MASK DETAILS
15.000
4224480/A 08/2018
NOTES: (continued)
6. Publication IPC-7351 may have alternate designs.
7. Solder mask tolerances between and around signal pads can vary based on board fabrication site.
8. This package is designed to be soldered to a thermal pad on the board. For more information, see Texas Instruments literature
numbers SLMA002 (www.ti.com/lit/slma002) and SLMA004 (www.ti.com/lit/slma004).
9. Size of metal pad may vary due to creepage requirement.
10. Vias are optional depending on application, refer to device data sheet. It is recommended that vias under paste be filled, plugged
or tented.
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EXAMPLE STENCIL DESIGN
PWP0028M
TM
PowerPAD TSSOP - 1.2 mm max height
SMALL OUTLINE PACKAGE
(3.1)
BASED ON
0.125 THICK
STENCIL
28X (1.5)
METAL COVERED
BY SOLDER MASK
1
28
28X (0.45)
(R0.05) TYP
26X (0.65)
(4.05)
BASED ON
0.125 THICK
STENCIL
SYMM
15
14
SYMM
(5.8)
SEE TABLE FOR
DIFFERENT OPENINGS
FOR OTHER STENCIL
THICKNESSES
SOLDER PASTE EXAMPLE
BASED ON 0.125 mm THICK STENCIL
SCALE: 8X
STENCIL
THICKNESS
SOLDER STENCIL
OPENING
0.1
0.125
0.15
0.175
3.47 X 4.53
3.10 X 4.05 (SHOWN)
2.83 X 3.70
2.62 X 3.42
4224480/A 08/2018
NOTES: (continued)
11. Laser cutting apertures with trapezoidal walls and rounded corners may offer better paste release. IPC-7525 may have alternate
design recommendations.
12. Board assembly site may have different recommendations for stencil design.
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PACKAGE OPTION ADDENDUM
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14-Aug-2021
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)
DRV8426PWPR
ACTIVE
HTSSOP
PWP
28
2500
RoHS & Green
NIPDAU
Level-3-260C-168 HR
-40 to 125
DRV8426
DRV8426RGER
ACTIVE
VQFN
RGE
24
3000
RoHS & Green
NIPDAU
Level-1-260C-UNLIM
-40 to 125
DRV
8426
(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