TI DRV8821

DRV8821
www.ti.com
SLVS912C – JANUARY 2009 – REVISED JANUARY 2010
DUAL STEPPER MOTOR CONTROLLER/DRIVER
Check for Samples: DRV8821
FEATURES
1
•
Dual PWM microstepping motor driver
– Built-In Microstepping Indexers
– Up to 1.5-A Current Per Winding
– Three-Bit Winding Current Control Allows
up to Eight Current Levels
– Low MOSFET On-Resistance
– Selectable Slow or Mixed Decay Modes
8-V to 32-V Operating Supply Voltage Range
Internal Charge Pump for Gate Drive
Built-in 3.3-V Reference
2
•
•
•
•
•
•
Simple Step/Direction Interface
Fully Protected Against Undervoltage,
Overtemperature, and Overcurrent
Thermally Enhanced Surface Mount Package
APPLICATIONS
•
•
•
•
•
•
Printers
Scanners
Office Automation Machines
Gaming Machines
Factory Automation
Robotics
DESCRIPTION/ORDERING INFORMATION
The DRV8821 provides a dual microstepping-capable stepper motor controller/driver solution for printers,
scanners, and other office automation equipment applications.
Two independent stepper motor driver circuits include four H-bridge drivers and microstepping-capable indexer
logic. Each of the motor driver blocks employ N-channel power MOSFETs configured as an H-bridge to drive the
motor windings.
A simple step/direction interface allows easy interfacing to controller circuits. Pins allow configuration of the
motor in full-step, half-step, quarter-step, or eighth step modes, and the selection of slow or mixed decay modes.
Internal shutdown functions are provided for over current protection, short circuit protection, under voltage
lockout and overtemperature.
The DRV8821 is packaged in a 48-pin HTSSOP package (Eco-friendly : RoHS & no Sb/Br).
ORDERING INFORMATION (1)
TA
–40°C to 85°C
(1)
(2)
PACKAGE (2)
PowerPad™ (HTSSOP) - DCA
ORDERABLE PART NUMBER
Reel of 2000
DRV8821DCAR
Tube of 40
DRV8821DCA
TOP-SIDE MARKING
DRV8821
For the most current package and ordering information, see the Package Option Addendum at the end of this document, or see the TI
web site at www.ti.com.
Package drawings, thermal data, and symbolization are available at www.ti.com/packaging.
1
2
Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of Texas
Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet.
PowerPad, PowerPAD are trademarks of Texas Instruments.
PRODUCTION DATA information is current as of publication date.
Products conform to specifications per the terms of the Texas
Instruments standard warranty. Production processing does not
necessarily include testing of all parameters.
Copyright © 2009–2010, Texas Instruments Incorporated
DRV8821
SLVS912C – JANUARY 2009 – REVISED JANUARY 2010
www.ti.com
FUNCTIONAL BLOCK DIAGRAM
CP1
Dig.
VCC
Charge
Pump and
Gate Drive
Regulator
3.3V
Regulator
V3P3
0.47µF
6.3V
CP2
0.01µF
35V
+24
VCP
VGD
0.1µF
16V
+24
VCP
VM
ABVREF
AOUT1
PWM H-bridge
driver A
Step
Motor
AOUT2
ABSTEP
AISEN
ABDIR
ABENBLn
+24
VM
ABUSM0
ABUSM1
BOUT1
PWM H-bridge
driver B
ABDECAY
BOUT2
ABRESETn
BISEN
Indexer
Logic
+24
CDSTEP
VM
CDDIR
COUT1
PWM H-bridge
driver C
CDENBLn
CDUSM0
COUT2
CDUSM1
CISEN
Step
Motor
CDDECAY
+24
CDRESETn
VM
DOUT1
PWM H-bridge
driver D
CDVREF
DOUT2
DISEN
OCP
Thermal
Shut down
Oscillator
UVLO
RESET
GND
2
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SLVS912C – JANUARY 2009 – REVISED JANUARY 2010
TERMINAL FUNCTIONS
NAME
NO.
I/O
(1)
DESCRIPTION
EXTERNAL COMPONENTS OR CONNECTIONS
POWER AND GROUND
VM
(4 pins)
1,2,
23, 24
-
Motor supply voltage (multiple pins)
Connect all VM pins together to motor supply voltage.
Bypass to GND with several 0.1-mF, 35-V ceramic capacitors.
V3P3
16
-
3.3 V regulator output
Bypass to GND with 0.47-mF, 6.3-V ceramic capacitor.
GND
10-15,
34-39
-
Power ground (multiple pins)
Connect all PGND pins to GND and solder to copper heatsink areas.
CP1
7
IO
CP2
8
IO
Charge pump flying capacitor
Connect a 0.01-mF capacitor between CP1 and CP2
VCP
9
IO
Charge pump storage capacitor
Connect a 0.1-mF, 16 V ceramic capacitor to VM
ABSTEP
45
I
Motor AB step input
Rising edge causes the indexer to move one step.
ABDIR
43
I
Motor AB direction input
Level sets the direction of stepping.
ABUSM0
44
I
Motor AB microstep mode 0
ABUSM1
41
I
Motor AB microstep mode 1
USM0 and USM1 set the step mode - full step, half step, quarter
step, or eight microsteps/step.
ABENBLn
42
I
Motor AB enable input
Logic high to disable motor A outputs, logic low to enable.
ABRESETn
40
I
Motor AB reset input
Active-low reset input initializes the indexer logic and disables the
H-bridge outputs for motor A.
ABDECAY
6
I
Motor AB decay mode
Logic low for slow decay mode, high for mixed decay.
Sets current trip threshold.
MOTOR AB
ABVREF
17
I
Motor AB current set reference
voltage
AOUT1
5
O
Bridge A output 1
AOUT2
3
O
Bridge A output 2
AISEN
4
-
Bridge A current sense
Connect to current sense resistor for bridge A.
BOUT1
48
O
Bridge B output 1
BOUT2
46
O
Bridge B output 2
Connect to second coil of bipolar stepper motor 1, or DC motor
winding.
BISEN
45
-
Bridge B current sense
Connect to current sense resistor for bridge B.
CDSTEP
33
I
Motor CD step input
Rising edge causes the indexer to move one step.
CDDIR
31
I
Motor CD direction input
Level sets the direction of stepping.
CDUSM0
32
I
Motor CD microstep mode 0
CDUSM1
29
I
Motor CD microstep mode 1
USM0 and USM1 set the step mode - full step, half step, quarter
step, or eight microsteps/step.
CDENBLn
30
I
Motor CD enable input
Logic high to disable motor Boutputs, logic low to enable.
CDRESETn
28
I
Motor CD reset input
Active-low reset input initializes the indexer logic and disables the
H-bridge outputs for motor B.
CDDECAY
19
I
Motor CD decay mode
Logic low for slow decay mode, high for mixed decay.
Sets current trip threshold.
Connect to first coil of bipolar stepper motor 1, or DC motor winding.
MOTOR CD
CDREF
18
I
Motor CD current set reference
voltage
COUT1
27
O
Bridge C output 1
COUT2
25
O
Bridge C output 2
CISEN
26
-
Bridge C current sense
Connect to current sense resistor for bridge C.
DOUT1
22
O
Bridge D output 1
DOUT2
20
O
Bridge D output 2
Connect to second coil of bipolar stepper motor 2, or DC motor
winding.
DISEN
21
-
Bridge D current sense
Connect to current sense resistor for bridge D.
(1)
Connect to first coil of bipolar stepper motor 2, or DC motor winding.
Directions: I = input, O = output, OZ = 3-state output, OD = open-drain output, IO = input/output
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SLVS912C – JANUARY 2009 – REVISED JANUARY 2010
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DCA PACKAGE
VM
VM
AOUT2
AISEN
AOUT1
ABDECAY
CP1
CP2
VCP
PGND
PGND
Solder these
PGND
pins to copper
PGND
heatsink area
PGND
PGND
V3P3
ABVREF
CDVREF
CDDECAY
DOUT2
DISEN
DOUT1
VM
VM
ABSOLUTE MAXIMUM RATINGS (1)
1
48
2
3
47
46
4
45
5
6
44
43
7
8
42
41
9
40
10
11
39
38
12
13
37
36
14
15
35
34
16
17
33
32
18
19
20
31
30
29
21
28
27
22
23
24
26
25
BOUT1
BISEN
BOUT2
ABSTEP
ABUSM0
ABDIR
ABENBLn
ABUSM1
ABRESETn
PGND
PGND
Solder these
PGND
pins to copper
PGND
heatsink area
PGND
PGND
CDSTEP
CDUSM0
CDDIR
CDENBLn
CDUSM1
CDRESETn
COUT1
CISEN
COUT2
(2)
over operating free-air temperature range (unless otherwise noted)
VM
Power supply voltage range
–0.3 to 34
V
VI
Logic input voltage range (3)
–0.5 to 5.75
V
IO(peak)
Peak motor drive output current, t < 1 ms
IO
Motor drive output current (4)
PD
Continuous total power dissipation
TJ
Operating virtual junction temperature range
–40 to 150
°C
TA
Operating ambient temperature range
–40 to 85
°C
Tstg
Storage temperature range
–60 to 150
°C
(1)
(2)
(3)
(4)
Internally limited
1.5
A
See Dissipation Ratings Table
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.
Input pins may be driven in this voltage range regardless of presence or absence of VM.
Power dissipation and thermal limits must be observed.
DISSIPATION RATINGS
RqJA
DERATING FACTOR
ABOVE TA = 25°C
TA < 25°C
TA = 70°C
TA = 85°C
Low-K (1)
75.7°C/W
13.2 mW/°C
1.65 W
1.06 W
0.86 W
Low-K (2)
32°C/W
31.3 mW/°C
3.91 W
2.50 W
2.03 W
30.3°C/W
33 mW/°C
4.13 W
2.48 W
2.15 W
22.3°C/W
44.8 mW/°C
5.61 W
3.59 W
2.91 W
BOARD
High-K (3)
High-K
(1)
(2)
(3)
(4)
4
(4)
PACKAGE
DCA
The JEDEC Low-K board used to derive this data was a 76-mm x 114-mm, 2-layer, 1.6-mm thick PCB with no backside copper.
The JEDEC Low-K board used to derive this data was a 76-mm x 114-mm, 2-layer, 1.6-mm thick PCB with 25-cm2 2-oz copper on back
side.
The JEDEC High-K board used to derive this data was a 76-mm x 114-mm, 4-layer, 1.6-mm thick PCB with no backside copper and
solid 1-oz internal ground plane.
The JEDEC High-K board used to derive this data was a 76-mm x 114-mm, 4-layer, 1.6-mm thick PCB with 25-cm2 1-oz copper on back
side and solid 1-oz internal ground plane.
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SLVS912C – JANUARY 2009 – REVISED JANUARY 2010
RECOMMENDED OPERATING CONDITIONS
over operating free-air temperature range (unless otherwise noted)
MIN
VM
Motor power supply voltage range
IMOT
Continuous motor drive output current (1)
VREF
VREF input voltage
(1)
NOM
8
1
1
MAX
UNIT
32
V
1.5
A
4
V
MAX
UNIT
Power dissipation and thermal limits must be observed.
ELECTRICAL CHARACTERISTICS
over operating free-air temperature range (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
POWER SUPPLIES
IVM
VM operating supply current
VM = 24 V, no loads
IVMSD
VM shutdown supply current
VM = 24 V, ABENBLn = CDENBLn = 1
VUVLO
VM undervoltage lockout voltage
VM rising
VCP
Charge pump voltage
Relative to VM
VV3P3
VV3P3 output voltage
5
6.5
8
mA
2.5
mA
8
V
12
3.20
3.30
V
3.40
V
0.7
V
LOGIC-LEVEL INPUTS
VIL
Input low voltage
VIH
Input high voltage
VHYS
Input hysteresis
IIN
Input current
(internal pulldown current)
2
0.3
V
0.45
VIN = 3.3 V
0.6
V
100
mA
OVERTEMPERATURE PROTECTION
tTSD
Thermal shutdown temperature
Die temperature
150
°C
MOTOR DRIVER
Rds(on)
Motor #1 FET on resistance
(each individual FET)
VM = 24 V, IO = 0.8 A, TJ = 25°C
0.25
VM = 24 V, IO = 0.8 A, TJ = 85°C
0.31
Rds(on)
Motor #2 FET on resistance
(each individual FET)
VM = 24 V, IO = 0.8 A, TJ = 25°C
0.30
VM = 24 V, IO = 0.8 A, TJ = 85°C
0.38
IOFF
Off-state leakage current
(1)
45
50
0.37
0.45
Ω
Ω
±12
mA
55
kHz
fPWM
Motor PWM frequency
tBLANK
ITRIP blanking time (2)
tF
Output fall time
50
300
ns
tR
Output rise time
50
300
ns
IOCP
Overcurrent protect level
1.5
tOCP
Overcurrent protect trip time
2.5
tMD
Mixed decay percentage
3.75
Measured from beginning of PWM cycle
3
ms
4.5
A
ms
75
%
VREF INPUT/CURRENT CONTROL ACCURACY
IREF
xVREF input current
ΔICHOP
(1)
(2)
Chopping current accuracy
xVREF = 3.3 V
–3
3
mA
xVREF = 2.5 V, derived from V3P3;
71% to 100% current
–5
5
%
xVREF = 2.5 V, derived from V3P3;
20% to 56% current
–10
10
%
Factory option 100 kHz.
Factory options for 2.5 ms, 5 ms or 6.25 ms.
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TIMING REQUIREMENTS
over operating free-air temperature range (unless otherwise noted)
MIN MAX UNIT
1
fSTEP
Step frequency
2
tWH(STEP)
Pulse duration, xSTEP high
2.5
200
kHz
ms
3
tWL(STEP)
Pulse duration, xSTEP low
2.5
ms
4
tSU(STEP)
Setup time, command to xSTEP rising
200
ns
5
tH(STEP)
Hold time, command to xSTEP rising
200
ns
6
tWAKE
Wakeup time, SLEEPn inactive to xSTEP
1
ms
1
2
3
xSTEP
xDIR, xUSMx
4
5
ABENBLn
& CDENBLn
6
6
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SLVS912C – JANUARY 2009 – REVISED JANUARY 2010
FUNCTIONAL DESCRIPTION
PWM Motor Drivers
The DRV8821 contains four H-bridge motor drivers with current-control PWM circuitry. A block diagram showing
drivers A and B of the motor control circuitry (as typically used to drive a bipolar stepper motor) is shown below.
Drivers C and D are the same as A and B (though the Rds(on) of the output FETs is different).
VM
OC P
VM
VC P, VGD
A OU T1
From Indexer Logic
Predrive
AEN B L
Step
Motor
APH A SE
A OU T2
A BD EC A Y
PW M
OC P
A I[2:0]
3
+
A I[2:0]
A IS EN
A =5
DAC
3
A BVR EF
VM
OC P
VM
V CP, VGD
BOU T1
Predrive
B EN BL
B OU T2
BPH A SE
PW M
OC P
B ISEN
+
B I[2:0]
A =5
DAC
3
Figure 1. Block Diagram
Note that there are multiple VM motor power supply pins. All VM pins must be connected together to the motor
supply voltage.
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Current Regulation
The PWM chopping current is set by a comparator which compares the voltage across a current sense resistor
connected to the xISEN pins, multiplied by a factor of 5, with a reference voltage. The reference voltage is input
from the xVREF pin.
The full-scale (100%) chopping current is calculated as follows:
5
(1)
Example:
If a 0.22-Ω sense resistor is used and the VREFx pin is 3.3 V, the full-scale (100%) chopping current is
3.3 V/(5 * 0.22 Ω) = 1.875 A.
The reference voltage is also scaled by an internal DAC that allows torque control for fractional stepping of a
bipolar stepper motor, as described in the "microstepping indexer" section below.
Decay Mode
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 2 as case 1. The current flow direction shown indicates
positive current flow in the step table below.
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. As the winding current approaches zero, the bridge is
disabled to prevent any reverse current flow. Fast-decay mode is shown in Figure 2 as case 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 2 as case 3.
VM
1 Drive current
1
xOUT2
xOUT1
3
2
Fast decay (reverse)
3
Slow decay (brake)
2
Figure 2. Decay Mode
8
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The DRV8821 also supports a mixed decay mode. Mixed decay mode begins as fast decay, but after a period of
time (75% of the PWM cycle) switches to slow decay mode for the remainder of the fixed PWM period.
Mixed decay mode is only active if the current through the winding is decreasing (per the indexer step table); if
the current is increasing, then slow decay is always used.
Slow or mixed decay mode is selected by the state of the xDECAY pins - logic low selects slow decay, and logic
high selects mixed decay operation.
Blanking Time
After the current is enabled in an H-bridge, the voltage on the xISEN pin is ignored for a fixed period of time
before enabling the current sense circuitry. This blanking time is fixed at 3.75 ms. Note that the blanking time also
sets the minimum on time of the PWM.
Microstepping Indexer
Built-in indexer logic in the DRV8821 allows a number of different stepping configurations. The xUSM1 and
xUSM0 pins are used to configure the stepping format as shown in the table below:
xUSM1
xUSM0
0
0
Full step (2-phase excitation)
STEP MODE
0
1
½ step (1-2 phase excitation)
1
0
1/4 step (W1-2 phase excitation)
1
1
Eight microsteps/steps
The following table shows the relative current and step directions for different settings of xUSM1 and xUSM0. At
each rising edge of the xSTEP input, the indexer travels to the next state in the table. The direction is shown with
the DIR pin high; if the xDIR pin is low the sequence is reversed. Positive current is defined as xOUT1 = positive
with respect to xOUT2.
Note that the home state is 45 degrees. This state is entered at power-up or application of xRESETn.
Motor AB and motor CD act independently, and their indexer logic functions identically.
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FULL STEP
xUSM = 00
1/4 STEP
xUSM = 10
1/8 STEP
xUSM = 11
1
1
1
100
0
0
2
98
20
11.25
3
92
38
22.5
4
83
56
33.75
5
71
71
45 (home state)
6
56
83
56.25
7
38
92
67.5
8
20
98
78.75
9
0
100
90
10
–20
98
101.25
11
–38
92
112.5
12
–56
83
123.75
13
–71
71
135
14
–83
56
146.25
15
–92
38
157.5
16
–98
20
168.75
17
–100
0
180
18
–98
–20
191.25
19
–92
–38
202.5
20
–83
–56
213.75
21
–71
–71
225
22
–56
–83
236.25
23
–38
–92
247.5
24
–20
–98
258.75
25
0
–100
270
26
20
–98
281.25
27
38
–92
292.5
28
56
–83
303.75
29
71
–71
315
30
83
–56
326.25
31
92
–38
337.5
32
98
–20
348.75
2
3
4
3
5
6
2
4
7
8
5
9
10
3
6
11
12
7
13
14
4
AOUTx
BOUTx
CURRENT
CURRENT
(% FULL-SCALE) (% FULL-SCALE)
½ STEP
xUSM = 01
2
1
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8
15
16
STEP ANGLE
(DEGREES)
xRESETn and xENBLn Operation
The xRESETn pin, when driven active low, resets the step table to the home position. It also disables the
H-bridge drivers. The xSTEP input is ignored while xRESETn is active. Note that there is a separate xRESETn
pin for each motor; each acts only on one of the two motor controllers.
The xENABLEn pin is used to control the output drivers. When xENBLn is low, the output H-bridges are enabled.
When xENBLn is high, the H-bridges are disabled and the outputs are in a high-impedance state.. Note that
there is a separate xENBLn pin for each motor; each acts only on one of the two motor drivers.
Note that when xENBLn is high, the input pins and control logic, including the indexer (xSTEP and xDIR pins) are
still functional.
Driving both ABENBLn and CDENBLn high 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, and all internal clocks are stopped. In this state
all inputs are ignored until one or both of the xENBLn pits return active low.
10
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Protection Circuits
The DRV8821 is fully protected against undervoltage, overcurrent and overtemperature events.
Overcurrent Protection (OCP)
All of the drivers in DRV8821 are protected with an OCP (Over-Current Protection) circuit.
The OCP circuit includes an analog current limit circuit, which acts by removing the gate drive form each output
FET if the current through it exceeds a preset level. This circuit will limit the current to a level that is safe to
prevent damage to the FET.
A digital circuit monitors the analog current limit circuits. If any analog current limit condition exists for longer than
a preset period, all drivers in the device will be disabled.
The device is re-enabled upon the removal and re-application of power at the VM pins.
Thermal Shutdown (TSD)
If the die temperature exceeds safe limits, all drivers in the device will be shut down.
The device will remain disabled until the die temperature has fallen to a safe level. After the temperature has
fallen, the device may be re-enabled upon the removal and re-application of power at the VM pin.
Undervoltage Lockout (UVLO)
If at any time the voltage on the VM pins falls below the undervoltage lockout threshold voltage, all circuitry in the
device will be disabled. Operation will resume when VM rises above the UVLO threshold. The indexer logic will
be reset to its initial condition in the event of an undervoltage lockout.
Shoot-Through Current Prevention
The gate drive to each FET in the H-bridge is controlled to prevent any cross-conduction (shoot through current)
during transitions.
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THERMAL INFORMATION
Thermal Protection
The DRV8821 has thermal shutdown (TSD) as described above. If the die temperature exceeds approximately
150°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.
Power Dissipation
Power dissipation in the DRV8821 is dominated by the power dissipated in the output FET resistance, or RDS(ON).
Average power dissipation when running a stepper motor can be roughly estimated by Equation 2.
PTOT = 4
·
RDS(ON)
·
(IOUT(RMS))
2
(2)
where PTOT is the total power dissipation, RDS(ON) is the resistance of each FET, and IOUT(RMS) is the RMS output
current being applied to each winding. IOUT(RMS) is equal to the approximately 0.7x the full-scale output current
setting. The factor of 4 comes from the fact that there are two motor windings, and at any instant two FETs are
conducting winding current for each winding (one high-side and one low-side). Remember that the DRV8821 has
two stepper motor drivers, so the power dissipation of each must be added together to determine the total device
power dissipation.
The maximum amount of power that can be dissipated in the DRV8821 is dependent on ambient temperature
and heatsinking. The thermal dissipation ratings table in the datasheet can be used to estimate the temperature
rise for typical PCB constructions.
Note that RDS(ON) increases with temperature, so as the device heats, the power dissipation increases. This must
be taken into consideration when sizing the heatsink.
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 SLMA002, " PowerPAD™ Thermally
Enhanced Package" and TI application brief SLMA004, " PowerPAD™ Made Easy", available at www.ti.com.
In general, the more copper area that can be provided, the more power can be dissipated. Figure 3 shows
thermal resistance vs. copper plane area for both a single-sided PCB with 2-oz copper heatsink area, and a
4-layer PCB with 1-oz copper and a solid ground plane. Both PCBs are 76 mm x 114 mm, and 1.6 mm thick. It
can be seen that the heatsink effectiveness increases rapidly to about 20 cm2, then levels off somewhat for
larger areas.
Six pins on the center of each side of the package are also connected to the device ground. A copper area can
be used on the PCB that connects to the PowerPAD™ as well as to all the ground pins on each side of the
device. This is especially useful for single-layer PCB designs.
12
Submit Documentation Feedback
Copyright © 2009–2010, Texas Instruments Incorporated
Product Folder Link(s): DRV8821
DRV8821
www.ti.com
SLVS912C – JANUARY 2009 – REVISED JANUARY 2010
70
65
Thermal Resistance (RqJA) - °C/W
60
55
50
45
Low-K PCB (2 layer)
40
35
30
High-K PCB (4 layer with ground plane)
25
20
0
10
20
30
40
50
60
70
80
90
2
Backside Copper Area - cm
Figure 3. Thermal Resistance vs. Copper Plane Area
Submit Documentation Feedback
Copyright © 2009–2010, Texas Instruments Incorporated
Product Folder Link(s): DRV8821
13
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