TI DRV3201-Q1

DRV3201-Q1
www.ti.com
SLVSBD6 – MAY 2012
3 Phase Motor Driver-IC for Automotive Safety Applications
Check for Samples: DRV3201-Q1
FEATURES
APPLICATIONS
•
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The bridge driver is dedicated to automotive 3 phase
brushless DC motor control including safety relevant
applications. It provides six dedicated drivers for
normal level N-Channel MOSFET transistors. The
driver capability is designed to handle gate charges
of 250 nC, and the driver source/sink currents are
programmable for easy output slope adjustment. The
device also incorporates sophisticated diagnosis,
protection and monitoring features through an SPI
interface. A boost converter with integrated FET
provides the overdrive voltage, allowing full control on
the power-stages even for low battery voltage down
to 4.75 V.
Battery Voltage
Boost Converter
B_EN
Controller
3 × Phase Comp
GNDLS_B
PHxC
ERR
SPI
RSTN
EN
Control Logic
and
Safety / Diagnostic
3 Phase Gate Driver
3 × PowerStage
GHSx
SHSx
IHSx, ILSx
DRVOFF
VCC5
BLDC
Motor
GLSx
VCC3
Internal
Supply
RI
Shift Buffer
SLSx
x = 1..3
ADREF
RO
2 × 2nd Current Sense Amp
2 × 1st Current Sense Amp
IPy
O3,4
2 × Current Shunt
INy
y = 1..2
Figure 1. Typical Application Diagram
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 is a trademark of Texas Instruments.
PRODUCT PREVIEW information concerns products in the
formative or design phase of development. Characteristic data and
other specifications are design goals. Texas Instruments reserves
the right to change or discontinue these products without notice.
Copyright © 2012, Texas Instruments Incorporated
PRODUCT PREVIEW
•
DESCRIPTION
BOOST
•
•
Automotive Safety Critical Motor-Control
Applications
– Electrical Power Steering (EPS, EHPS)
– Electrical Brake/Brake Assist
– Transmission
– Oil-Pump
Industrial Safety Critical Motor-Control
Applications
O1,2
•
Qualified for Automotive Applications
AEC-Q100 Qualified
3 Phase Bridge Driver for Motor Control
Drives 6 Separate N-Channel Power MOSFETs
up to 250 nC Gate Charge
Programmable 140 mA–1 A Gate Current Drive
(Source/Sink) for Easy Output Slope
Adjustment
–7 V to 40 V Compliance on All FET Driver
Pins to Handle Inductive Under/Overshooting
Separate Control Input for Each Power
MOSFET
PWM Frequency up to 30 kHz
Supports 100% Duty Cycle Operation
Operating Voltage: 4.75 to 30 V
Proper Low Supply Voltage Operation Due to
Integrated Boost Converter for Gate-Driver
Voltage Generation
Logic Functional Down to 3 V
Short Circuit Protection With VDS-Monitoring
and Adjustable Detection Level
Two Integrated High Accuracy Current Sense
Amplifiers With Two Gain-Programmable
Second Stage for Higher Resolution at Low
Load Current Operation
Over and Undervoltage Protection
Shoot Through Protection With Programmable
Dead Time
Three Real Time Phase Comparators
Over Temperature Warning and Shut Down
Sophisticated Failure Detection and Handling
Through SPI Interface
Reverse Battery Protection Down to –4 V (With
Series Protection Resistance)
Sleep Mode Function
Reset and Enable Function
Package: 64-pin HTQFP PowerPAD™
SW
2
VS
1
DRV3201-Q1
SLVSBD6 – MAY 2012
www.ti.com
This integrated circuit can be damaged by ESD. Texas Instruments recommends that all integrated circuits be handled with
appropriate precautions. Failure to observe proper handling and installation procedures can cause damage.
ESD damage can range from subtle performance degradation to complete device failure. Precision integrated circuits may be more
susceptible to damage because very small parametric changes could cause the device not to meet its published specifications.
THERMAL INFORMATION
DRV3201
THERMAL METRIC (1)
HTQFP
UNIT
PAP - 64 PINS
θJA
Junction-to-ambient thermal resistance
21.6
θJCtop
Junction-to-case (top) thermal resistance
10.9
θJB
Junction-to-board thermal resistance
4.5
ψJT
Junction-to-top characterization parameter
0.1
ψJB
Junction-to-board characterization parameter
4.4
θJCbot
Junction-to-case (bottom) thermal resistance
0.3
(1)
°C/W
For more information about traditional and new thermal metrics, see the IC Package Thermal Metrics application report, SPRA953.
PRODUCT PREVIEW
2
Copyright © 2012, Texas Instruments Incorporated
Product Folder Link(s): DRV3201-Q1
DRV3201-Q1
www.ti.com
SLVSBD6 – MAY 2012
ABSOLUTE MAXIMUM RATINGS (1) (2)
over operating temperature TJ = –40°C to 150°C
VS, VSH
VS, VSH
PARAMETER
CONDITIONS
DC
Supply voltage, transient 1s
VALUE
UNIT
MIN
MAX
VS, negative voltages with minimum serial
resistor 5 Ω
–5
38
V
VS, negative voltages with external protection
NMOS
–14
38
V
VS, negative voltages with minimum serial
resistor 5 Ω
–5
42
V
VS, negative voltages with external protection
NMOS driven by device internal circuit
–14
42
V
GHSx
Gate high-side voltage
–7
47
V
SHSx
Source high-side voltage
–7
42
V
GHSx-SHSx
Gate-source high-side voltage
difference
–0.3
15
V
GLSx
Gate low-side voltage
–7
20
V
SLSx
Source low-side voltage
GLSx-SLSx
Gate-source low-side voltage
difference
BOOST, SW
INx, IPx
INx, IPx clamping
current
Current sense input current
Ox
External driven, internal limited (see IBOOST in
RECOMMENDED OPERATING
CONDITIONS)
–7
7
V
–0.3
15
V
Boost converter
–0.3
60
V
Current sense Input voltage
–0.3
42
V
–5
5
mA
Current sense output voltage
–0.3
ADREF
+0.3
V
–10
10
mA
Analog input voltage
–0.3
8
V
ILSx,IHSx, EN,
Digital input voltage
DRVOFF, SCLK, NCS,
SDI, RSTN, CSM,
B_EN
–0.3
18
V
SCTH
Analog input voltage
–0.3
18
V
GNDA, GNDL,
GNDLS_B, PGND, NC
Difference one GND or NC to
any other GND or NC
–0.3
0.3
V
TJ
Operating virtual junction
temperature range
–40
150
°C
TS
Storage temperature range
–40
165
°C
TLEAD
Lead temperature (soldering, 10
s)
260
°C
ESD all pins (3)
ESD performance of all pins to
any other pin
HBM model
–2
2
kV
ESD pin SHSx (3)
ESD performance of SHSx to
SHSx and GND
HBM model
–4
4
kV
ESD all pins (3)
ESD performance of all pins to
any other pin
CDM model
–500
500
V
SRSHS
Maximum slew rate of SHSx pins
–150
150
V/µs
ERR, SDO, PHxC, RO
Analog/digital output voltages
–0.3
8
V
ERR, SDO, PHxC, RO
Forced input/output current
–10
10
mA
TEST, AMUX, NC
Unused pins. Connect to GND
–0.3
0.3
V
External driven, internal limited (see IBOOST,sw
in RECOMMENDED OPERATING
CONDITIONS)
Clamping current
Ox forced input current
VDDIO, ADREF
(1)
(2)
(3)
PRODUCT PREVIEW
SYMBOL
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 voltages are with respect to network ground terminal, unless otherwise specified.
ESD testing is performed according to AEC-Q100 standard.
3
Copyright © 2012, Texas Instruments Incorporated
Product Folder Link(s): DRV3201-Q1
DRV3201-Q1
SLVSBD6 – MAY 2012
www.ti.com
ABSOLUTE MAXIMUM RATINGS(1)(2) (continued)
over operating temperature TJ = –40°C to 150°C
SYMBOL
PARAMETER
CONDITIONS
VALUE
UNIT
MIN
MAX
RI
Analog input voltage
–0.3
18
VCC5
Internal supply voltage
–0.3
8
V
I_VCC5
Short-to-ground current
40
mA
VCC3
Internal supply voltage
VCC3
Short-to-ground current
Internal current limit
–0.3
Limited by VCC5
V
3.6
V
40
mA
RECOMMENDED OPERATING CONDITIONS
over operating temperature TJ = -40°C to 150°C (unless otherwise noted)
MIN
Supply voltage, normal voltage operation, VS
Full device functionality
Supply voltage, logic operation, VSLO
Logic functional (during battery cranking
after coming from full device functionality)
Supply voltage for digital IOs, VDDIO
MAX
UNIT
4.75
NOM
30
V
3
40
V
PRODUCT PREVIEW
1.72
5.5
V
Duty cycle of bridge drivers, D
0
100
%
PWM switching frequency, fPWM
0
30
kHz
VS quiescent current normal operation (boost
converter enabled, drivers not switching), IVSn
Typically 65 mA (boost converter enabled),
see Figure 13 and Figure 14.
90
mA
BOOST pin quiescent current normal operation
(drivers not switching), IBOOST
Typically 15 mA
20
mA
BOOST pin additional load current due to switching
gate-drivers, IBOOST,sw
Without external power FETS (pure internal
switching current, 30 kHz all gate-drivers
switching at the same time)
3
mA
VS quiescent current shut down (EN = low; sleep
mode), IVSq
VS = 14 V, no operation, TJ < 85°C total
leakage current on all supply connected
pins
30
µA
–40
150
°C
Junction temperature, TJ
Operating ambient free-air temperature, TA
With proper thermal connection
Current sense input voltage range, VINx,VIPx
Relative to GNDA
Clamping voltage for current sense amplifier outputs O 1/ 2/ 3/ 4, ADREF
–40
125
°C
–0.14
1.6
V
0.7
5
V
3.3
V
Internal supply voltage, VCC3
VS > 3 V, external load current < 100 µA.
Decoupling capacitance is typically 4.7 nF.
VCC3 output current, I_VCC3
Intended for MCU ADC input
0
100
µA
VCC3 decoupling capacitance, C_VCC3
Typically 4.7 nF
1
10
nF
Internal supply voltage, VCC5
VS > 6 V, external load current < 100 µA.
Decoupling capacitance is typically 4.7 nF.
4.5
5.5
V
VCC5 output current, I_VCC5
Intended for MCU ADC input
0
100
µA
VCC5 decoupling capacitance, C_VCC5
Typically 4.7 nF
1
10
nF
(1)
2.1
(1)
Lower limit of functional range dependent of internal PowerOnReset level for internal digital logic. It is specified by VS > 3 V the internal
digital logic is operational and not put into PowerOnReset.
4
Copyright © 2012, Texas Instruments Incorporated
Product Folder Link(s): DRV3201-Q1
DRV3201-Q1
www.ti.com
SLVSBD6 – MAY 2012
ELECTRICAL CHARACTERISTICS
over operating temperature TJ = –40°C to 150°C and recommended operating conditions, VS = 4.75 to 30 V, fPWM< 30 kHz
(unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
–1
0
1
mV
–1
0
1
mV
10
µA
Current Sense Amplifier First Stages
Voff1/2
Initial input offset of amplifiers at TJ
= 25°C
Voff1/2_d
Temperature and aging offset
Ileak,INxIPx
Input leakage current INx, IPx
–0.3 V < INx, IPx < 1V pin-to-pin and pin-toground
Go1/2
DC open loop gain
Specified by design
80
VO1/2_N
Nominal output voltage range
Normal voltage operation, VS ≥ 6 V, ADREF = 5
V; 0.5 mA load current
0.5
4.5
V
VO1/2_L
Output voltage range during low
voltage operation
Low voltage operation, 4.75 V ≤ VS ≤ 6 V,
ADREF = 5 V; 0.5 mA load current
0.5
4
V
GBP1/2
Gain bandwidth product (GBP)
0.5 V ≤ O1/2 ≤ 4.5 V
Specified by design
SR1/2
Slew rate
0.5 V ≤ O1/2 ≤ 4.5 V, cap load = 25 pF
PSRR1/2
Power supply rejection ratio
VS to O1/2. Decoupling capacitance is typically
4.7 nF on VCC5 and VCC3.
80
dB
CMRR1/2
Common mode rejection ratio
IN1/2 or IP1/2 to O1/2
80
dB
–10
dB
5
MHz
V/µs
PRODUCT PREVIEW
2.9
Current Sense Amplifier Second Stages
Voff3/4
Initial input offset of amplifiers at TJ
= 25 °C
–3
0
–3
0
3
mV
Voff3/4_d
Temperature and aging offset
VO3/4_N
Nominal output voltage range
Normal voltage operation, VS ≥ 6 V, ADREF = 5
V; 0.5 mA load current
0.5
3
mV
4.5
V
VO3/4_L
Output voltage range during low
voltage operation
Low voltage operation, 4.75 V ≤ VS ≤ 6 V,
ADREF = 5 V; 0.5 mA load current
0.5
4
V
GBP3/4
Gain bandwidth product (GBP)
0.5 V ≤ O3/4 ≤ 4.5 V, gain = 8
Specified by design
SR3/4
Slew rate
0.5 V ≤ O3/4 ≤ 4.5 V, cap load = 25 pF
G1
Gain1
1.98
2
2.02
V/V
G2
Gain2
3.96
4
4.04
V/V
G3
Gain3
5.94
6
6.06
V/V
G4
Gain4
7.82
8
8.08
V/V
PSRR3/4
Power supply rejection ratio
5
MHz
2.9
VS to O3/4 decoupling capacitance is typically
4.7 nF on VCC5 and VCC3.
V/µs
80
dB
Shift Buffer
VRI
Shift input voltage range
0.1
2.6
V
VRO
Shift output voltage range
0.1
2.6
V
VRoffset
Shift voltage offset
–5
5
mV
IRO
Shift output current capability
–5
5
mA
Ileak,RI
Input leakage current RI
pin-to-ground
5
µA
Voxm
Maximum DC voltage of O1/2/3/4
relative to ADREF
ADREF = 3.3/ 5 V; Ox-ADREF
0.25
V
Voxos
Overshoot of O1/2/3/4 over
ADREF
Ox-ADREF; for < 1 µs; never higher than 5 V
over GND
Specified by design
1.2
V
IADREF
Bias current for voltage clamping
circuit
100
µA
0.2
V
ADREF
–0.1
0.03
Gate-Driver
VGS,low
Gate-source voltage low high/lowside driver
Active pulldown, Iload = –2 mA
0
5
Copyright © 2012, Texas Instruments Incorporated
Product Folder Link(s): DRV3201-Q1
DRV3201-Q1
SLVSBD6 – MAY 2012
www.ti.com
ELECTRICAL CHARACTERISTICS (continued)
over operating temperature TJ = –40°C to 150°C and recommended operating conditions, VS = 4.75 to 30 V, fPWM< 30 kHz
(unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
500
UNIT
PRODUCT PREVIEW
RGSp
Passive gate-source resistance
kΩ
RGSsa
Semi-active gate-source resistance In sleep mode, Vgs > 2 V
RGSa2
Active gate-source resistance
Vgs < 1 V, gate driven low by gate-driver, Regyx
= 100
2.3
Ω
RGSa1
Active gate-source resistance
Vgs < 1 V, gate driven low by gate-driver, Regyx
= 010
4.5
Ω
RGSa0
Active gate-source resistance
Vgs < 1 V, gate driven low by gate-driver, Regyx
= 001
9
Ω
VGS,HS,high
high-side output voltage
Iload = –2 mA
9
12.8
V
VGS,LS,high
low-side output voltage
Iload = –2 mA
9
12.8
V
IGC2C
Gate charge current high/low-side
driver 2
VGLS-VSLS = 2 V - 5 V, Regyx = 100, if not
disabled in CFG1
0.46
0.57
0.69
A
IGC1C
Gate charge current high/low-side
driver 1
VGLS-VSLS = 2 V - 5 V, Regyx = 010, if not
disabled in CFG1
0.23
0.29
0.34
A
IGC0C
Gate charge current high/low-side
driver 0
VGLS-VSLS = 2 V - 5 V, Regyx = 001, if not
disabled in CFG1
0.11
0.14
0.17
A
IGD2D
Gate discharge current high/lowside driver 2
VGLS-VSLS = 2 V - 5 V, Regyx = 100, if not
disabled in CFG1
0.46
0.57
0.69
A
IGD1D
Gate discharge current high/lowside driver 1
VGLS-VSLS = 2 V - 5 V, Regyx = 010, if not
disabled in CFG1
0.23
0.29
0.34
A
IGD0D
Gate discharge current high/lowside driver 0
VGLS-VSLS = 2 V - 5 V, Regyx = 001, if not
disabled in CFG1
0.11
0.14
0.17
A
tDon
Propagation on delay time
After ILx/IHx rising edge
tDondif
Propagation on delay time
difference
tDoff
Propagation off delay time
tDoffdiff
Propagation off delay time
difference
50
ns
TDon_Doff_diff
Difference between propagation on
delay time and propagation off
delay time
15
ns
tDRVoff
Propagation off (DRVOFF) delay
time
After rising edge on DRVOFF
tENoff
Propagation off (EN) deglitching
time
After falling edge on EN
tSD
Time until device enters shutdown
After falling edge on EN
tRSTNoff
Propagation off (RSTN) delay time
After falling edge on RSTN
Adt
Accuracy of dead time
If not disabled in CFG1
-15
14
7
kΩ
200
ns
50
After ILx/IHx falling edge
200
ns
ns
200
ns
6
µs
20
35
200
µs
ns
15
%
16
V
Boost Converter
VBOOST
Boost output voltage
BOOST-VS voltage
IBOOST
Output current capability
For device internal use only
fBOOST
Switching frequency
BOOST-VS > VBOOSTUV
VBOOSTUV
Undervoltage shutdown Level
BOOST-VS voltage
11
11.9
V
tBCSD
Filter time for undervoltage
shutdown
5
6
µs
VGNDLS_B,off
Voltage at GNDLS_B pin at which
boost FET switches off due to
current limit
80
120
mV
tSW,off
Delay of the GNDLS_B current
limit comparator
20
ns
ISW,fail
Internal second level current limit
1100
mA
(1)
15
40
(1)
mA
2.5
480
100
MHz
During startup when BOOST-VS < VBOOSTUV , fBOOST is typically 1.25 MHz.
6
Copyright © 2012, Texas Instruments Incorporated
Product Folder Link(s): DRV3201-Q1
DRV3201-Q1
www.ti.com
SLVSBD6 – MAY 2012
ELECTRICAL CHARACTERISTICS (continued)
over operating temperature TJ = –40°C to 150°C and recommended operating conditions, VS = 4.75 to 30 V, fPWM< 30 kHz
(unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
0.9
V
Digital Inputs
INL
Input low threshold
All digital inputs: EN, RSTN, B_EN, NCS,
DRVOFF, ILSx, IHSx, CSM, SDI
INH
Input high threshold
All digital inputs: EN, RSTN, B_EN, NCS,
DRVOFF, ILSx, IHSx, CSM, SDI
2
Inhys
Input hysteresis
All digital inputs: EN, RSTN, B_EN, NCS,
DRVOFF, ILSx, IHSx, CSM, SDI
0.3
0.4
0.78
V
Rpd,EN
Input pull down resistor at EN pin
EN
170
200
300
kΩ
tdeg,ENon
Power-up time after EN pin high
from sleep mode to active mode
After rising edge on EN, time until logic out-ofreset
TBD
Ms
Rpullup
Input pull up resistance
RSTN, B_EN, NCS, DRVOFF
100
140
200
kΩ
Rpulldown
Input pull down resistance
ILSx, IHSx, CSM, SDI
100
140
200
kΩ
V
Digital Outputs
Output high voltage
OL
Output low voltage
All digital outputs: ERR, SDO, PHxC
I = ±2 mA;
VDDIO in functional range (2)
VDDIO
–0.2
V
0.2
V
2.5
V
100
mV
PRODUCT PREVIEW
OH
VDS Monitoring
VSCTH
VDS short circuit threshold input
range
Avds
Accuracy of VDS monitoring
tVDS
Detection filter time
If not disabled in CFG1
0
-100
Only rising edge of VDS comparators are filtered
5
µs
°C
THERMAL SHUTDOWN
Tmsd0
Thermal recovery
140
150
Tmsd1
Thermal warning
Specified by characterization
160
170
Tmsd2
Thermal global reset
175
190
Thmsd
Thermal shutdown hysteresis
tTSD
Thermal warning filter time
40
45
50
µs
tTSD
Thermal shutdown filter time
40
45
50
µs
°C
205
40
°C
°C
Phase Comparator
VPCHth
Phase comparator high threshold
0.7*VSH
0.8*V
SH
VPCLth
Phase comparator low threshold
0.2*VSH
0.3*V
SH
tDHL
Delay time high–low
Cout = 50 pF
30
tDLH
Delay time low–high
Cout = 50 pF
30
tD,match
Matching between two channels
RVSH
Resistance of internal voltage
divider to ground
ns
ns
50
ns
170
330
kΩ
V
VS Monitoring
VVS,OV
Overvoltage shutdown level
VVS,UV
Undervoltage shutdown level
tVS,SHD
Filter time for voltage shutdown
If not disabled in CFG1
30
30.5
4.5
4.75
V
5
6
µs
4 (3)
MHz
Serial Peripheral Interface Timing
fSPI
SPI clock (SCLK) frequency
TSPI
SPI clock period
250
ns
thigh
High time: SCLK logic high duration
90
ns
tlow
Low time: SCLK logic low duration
90
ns
(2)
(3)
All digital outputs have a push-pull output stage between VDDIO and ground.
MAX SPI clock tolerance is ± 10%.
7
Copyright © 2012, Texas Instruments Incorporated
Product Folder Link(s): DRV3201-Q1
DRV3201-Q1
SLVSBD6 – MAY 2012
www.ti.com
ELECTRICAL CHARACTERISTICS (continued)
over operating temperature TJ = –40°C to 150°C and recommended operating conditions, VS = 4.75 to 30 V, fPWM< 30 kHz
(unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
90
UNIT
tsMCUs
Setup time NCS: time between falling edge of NCS and rising edge of SCLK
ns
td1
Delay time: time delay from falling edge of NCS to data valid at SDO
60
ns
tsusi
Setup time at SDI: setup time of SDI before the rising edge of SCLK
30
ns
td2
Delay time: time delay from falling edge of SCLK to data valid at SDO
0
30
ns
thcs
Hold time: time between the falling edge of SCLK and rising edge of NCS
45
thlcs
SPI transfer inactive time: time between two transfers
250
ttri
3-state delay time: time between rising edge of NCS and SDO in 3-state
ns
ns
15
ns
NCS
tthlcst
tthcst
ttsucst
PRODUCT PREVIEW
SCLK
tthight
ttsucst
ttlowt
SDI
tsusi
tsusi
SDO
td1
td2
ttri
td1
Figure 2. SPI Timing Parameters
8
Copyright © 2012, Texas Instruments Incorporated
Product Folder Link(s): DRV3201-Q1
DRV3201-Q1
www.ti.com
SLVSBD6 – MAY 2012
PIN FUNCTIONS
IN2
IP2
GNDA
RO
RI
IP1
O1
IN1
GNDA
VDDIO
IHS3
ILS3
IHS2
ILS2
IHS1
ILS1
PAP Package
(Top View)
VSH
1
48
O2
SLS3
2
47
O3
GLS3
3
46
O4
SHS3
4
45
GNDL
GHS3
5
44
ADREF
PGND
6
43
AMUX (GND)
SLS2
7
42
VCC3
GLS2
8
41
TEST (GND)
SHS2
9
GHS2
DRV3201
40
VCC5
10
39
GNDA
GNDA
11
38
ERR
SCTH
12
37
RSTN
SLS1
13
36
EN
GLS1
14
35
CSM
SHS1
15
34
B_EN
GHS1
16
33
NC
PRODUCT PREVIEW
64 63 62 61 60 59 58 57 56 55 54 53 52 51 50 49
NC
GNDLS_B
SW
BOOST
VS
GNDA
SDO
SDI
NCS
GNDL
SCLK
DRVOFF
GNDA
PH3C
PH2C
PH1C
17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32
Figure 3. Pin Assignment (HTQFP-64 Package)
PIN FUNCTIONS
TYPE (1)
PIN
NAME
DESCRIPTION
NO.
VSH
1
HVI_A
Sense high-side, sensing VS connection of the external power MOSFETs for VDS monitoring.
SLS3
2
PWR
Source low-side 3, connected to external power MOSFET for gate discharge and VDS monitoring.
GLS3
3
PWR
Gate low-side 3, connected to gate of external power MOSFET.
SHS3
4
PWR
Source high-side 3, connected to external power MOSFET for gate discharge and VDS monitoring.
GHS3
5
PWR
Gate high-side 3, connected to gate of external power MOSFET.
PGND
6
GND
Sense low-side (ground), sensing ground connection of the external power MOSFETs for phase
comparators.
SLS2
7
PWR
Source low-side 2, connected to external power MOSFET for gate discharge and VDS monitoring.
GLS2
8
PWR
Gate low-side 2, connected to gate of external power MOSFET.
SHS2
9
PWR
Source high-side 2, connected to external power MOSFET gate discharge and VDS monitoring.
GHS2
10
PWR
Gate high-side 2, connected to gate of external power MOSFET.
(1)
Description of pin type: GND = Ground, HVI_A = High-Voltage Input Analog, HVI_D = High-Voltage Input Digital, LVI_A = Low-Voltage
Input Analog, LVO_A = Low-Voltage Output Analog, LVO_D = Low-Voltage Output Digital, NC = NoConnect, PWR = Power Output,
Supply = Supply Input.
9
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SLVSBD6 – MAY 2012
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PIN FUNCTIONS (continued)
PIN
NAME
TYPE
(1)
DESCRIPTION
NO.
PRODUCT PREVIEW
GNDA
11
GND
SCTH
12
HVI_A
Analog ground
Short circuit threshold, reference input voltage for VDS monitoring.
SLS1
13
PWR
Source low-side 1, connected to external power MOSFET for gate discharge and VDS monitoring.
GLS1
14
PWR
Gate low-side 1, connected to gate of external power MOSFET.
SHS1
15
PWR
Source high-side 1, connected to external power MOS transistor for gate discharge and VDS
monitoring.
GHS1
16
PWR
Gate high-side 1, connected to gate of external power MOS transistor.
PH1C
17
LVO_D
Phase comparator output1
PH2C
18
LVO_D
Phase comparator output2
PH3C
19
LVO_D
Phase comparator output3
GNDA
20
GND
DRVOFF
21
HVI_D
Driver OFF (high active), secondary bridge driver disable
SCLK
22
HVI_D
SPI clock
GNDL
23
GND
NCS
24
HVI_D
SPI chip select
SDI
25
HVI_D
SPI data input
SDO
26
LVO_D
SPI data output
GNDA
27
GND
Analog ground
VS
28
Supply
Power supply voltage
BOOST
29
Supply
Boost output voltage, used as supply for the gate-drivers.
SW
30
PWR
Boost converter switching node connected to external coil and external diode.
GNDLS_B
31
GND
Boost GND to set current limit. Boost switching current goes through this pin via exterior resistor to
GND.
NC
32
NC
NC pin, connected to GND during normal application.
NC
33
NC
NC pin, connected to GND during normal application.
B_EN
34
HVI_D
Boost enable. Enable boost operation or disable during e.g. sensitive measurement.
CSM
35
HVI_D
Configurable safety mode (high active), defines the level of safety.
EN
36
HVI_D
Enable (high active) of the device
RSTN
37
HVI_D
Reset (low active)
ERR
38
LVO_D
Error (low active). Error pin to indicate detected error.
GNDA
39
GND
VCC5
40
LVO_A
VCC5 regulator, for internal use only. Recommended external decoupling capacitance: 4.7 nF.
External load < 100 µA
TEST
41
HVI_A
TEST mode input, connected to GND during normal application.
VCC3
42
LVO_A
VCC3 regulator, for internal use only. Recommended external decoupling capacitance: 4.7 nF.
External load < 100 µA
AMUX
(GND)
43
LVO_A
Analog TEST output MUX, connected to GND during normal application.
ADREF
44
LVI_A
ADC reference of MCU, used as maximum voltage clamp for O1-O4.
GNDL
45
GND
Logic ground
O4
46
LVO_A
Output second stage current sense amplifier 2
O3
47
LVO_A
Output second stage current sense amplifier 1
O2
48
LVO_AO
IN2
49
HVI_A
Current sense input N 2
IP2
50
HVI_A
Current sense input P 2
GNDA
51
GND
RO
52
LVO_A
Current sense reference output for the shift voltage.
RI
53
HVI_A
Current sense reference input for the shift voltage.
Analog ground
Logic ground
Ground analog
Output first stage current sense amplifier 2
Ground analog
10
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Product Folder Link(s): DRV3201-Q1
DRV3201-Q1
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SLVSBD6 – MAY 2012
PIN FUNCTIONS (continued)
PIN
NAME
TYPE
(1)
DESCRIPTION
NO.
IP1
54
HVI_A
Current sense input P 1
O1
55
LVO_A
Output first stage current sense amplifier 1
IN1
56
HVI_A
Current sense input N 1
GNDA
57
GND
VDDIO
58
Supply
IO supply voltage, defines the interface voltage of digital I/O e.g. SPI.
IHS3
59
HVI_D
Input HS 3, digit input to drive the HS3
ILS3
60
HVI_D
Input LS 3, digit input to drive the LS3
IHS2
61
HVI_D
Input HS 2, digit input to drive the HS2
ILS2
62
HVI_D
Input LS 2, digit input to drive the LS2
IHS1
63
HVI_D
Input HS 1, digit input to drive the HS1
ILS1
64
HVI_D
Input LS 1, digit input to drive the LS1
PRODUCT PREVIEW
Ground analog
11
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FUNCTIONAL BLOCK DIAGRAM
5
BOOST
Battery Voltage
VS
SW
22 H
1 F
B_EN
Controller
GNDLS_B
330m
3 × Phase Comp
PHxC
PGND
SCTH
VSH
Safety / Diagnostic
ERR
CSM
PRODUCT PREVIEW
VDDIO
RSTN
EN
NCS
SCLK
SDI
SDO
- Overtemp
- Overvoltage
- Undervoltage
- Clock Monitoring
- Overtemperature Detection
- Short Circuit
- Shoot Through Protection
- VDS Monitoring
- Dead Time Control
6 × VDS Monitor
3 Phase Gate Driver
3 × PowerStage
GHSx
SHSx
Level
Shift
BLDC
Motor
GLSx
Control Logic
SLSx
- Progr. Gate Current
- Progr. Gain
- Sleep Mode Control
x = 1..3
IHSx, ILSx
DRVOFF
2 × Current Shunt
RO
VCC5
VCC3
IPy
Bandgap,
Bias,
Oscillator
15k
1k
15k
1k
INy
4.7nF
PGND
O1,2
GNDL
O3,4
ADREF
RI
Ext. Reference voltage
(VCC5 or VCC3 can
not be used for this)
GNDA
Clamp
4.7nF
y = 1..2
Power Supply
Bridge Driver
Reference/Bias
Digital
Safety
Figure 4. DRV3201-Q1 Functional Block Diagram
12
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SLVSBD6 – MAY 2012
DETAILED DESCRIPTION
The DRV3201-Q1 is designed to control 3 phase brushless DC motors in automotive applications using pulse
width modulation. Three high-side and three low-side gate-drivers can be switched individually with low
propagation delay. The input logic prevents simultaneous activation of high and low-side driver of the same
channel. A configuration and status register can be accessed through the SPI communication interface.
SUPPLY CONCEPT
The battery voltage functional operation range for the DRV3201-Q1 is between 4.75 V and 30 V. The DRV3201Q1 operates with either 3.3 V or 5 V MCUs, which can be achieved by connecting the IO voltage of the MCU to
the VDD_IO pin of the DRV3201-Q1, and by connecting the ADC reference voltage of the MCU to the ADREF
pin of the DRV3201-Q1. All digital outputs are related to VDDIO, and all analog outputs are related (clamped) to
ADREF. All digital inputs are related to the internal supply VCC3, except the EN pin. The gate-drivers for the
external power FETs operate down to 4.75 V battery voltage. For supply voltage falling below 4.75 V, the gates
of the external FETs are pulled down actively. For supply voltage below 3 V, these gates are pulled down semiactively. The minimum start-up battery voltage for the gate-drivers and the internal logic is 4.75 V.
The VCC5 is an internal supply for the current sense amplifiers and other internal analog circuitry. The VCC5 pin
needs to be externally decoupled with a typical 4.7 nF capacitance. The VCC5 has an internal current limit to
avoid any internal damage due to an external short-to-ground on the VCC5 pin.
The VCC3 is an internal supply for the internal logic. The VCC3 pin needs to be externally decoupled with a
typical 4.7 nF capacitance. Since the VCC3 is supplied from the VCC5 regulator, its output is current limited by
the VCC5 current limit so any internal damage is avoided in case of an external short-to-ground on the VCC3
pin. In case of a short-to-ground on either the VCC5 pin or the VCC3 pin, the internal logic is put in reset, which
is detectable by the MCU because of disabled SPI communication. In this situation it is strongly recommended
that the MCU takes necessary action to bring down the EN pin and shut off the DRV3201-Q1 to avoid VCC5
and/or VCC3 overloading for too long.
Boost Converter
The boost converter is configured to supply an add-on voltage to the supply voltage. The boost converter
requires an external inductance, capacitor, Schottky-diode, and a series resistance in its ground for current
sensing. Both the high-side and the low-side gate-drivers are supplied from the boost converter. This allows the
DRV3201-Q1 to achieve full-range gate-source driving voltage for all external power FETs even at battery
voltage down to 4.75 V. The boost converter has a separate B_EN pin to enable/disable. When the device is put
in sleep mode, the boost converter cannot be enabled.
Sleep Mode/Active Mode
The EN (Enable) pin puts the device into sleep mode. At the falling edge on the EN pin, after a typical 6 µs
deglitch time, the gates of the external power FETs are actively pulled low by the gate-drivers. Afterwards (min
20 µs, max 35 µs later) the internal supplies VCC5, VCC3, the boost converter, and the current sense amplifiers
are switched off and the gates of the external power FETs are pulled low with a semi-active pulldown resistor
(see Semi-Active Pull-Down Resistor). The internal logic is put in reset state, and all internal registers are
cleared. No diagnostic information is available during sleep mode.
A rising edge on the EN pin puts the device in active mode after TBD power-up time. In active mode, the
supplies VCC5 and VCC3 are present, and the boost converter can be enabled or disabled with the B_EN pin.
Since all internal registers are cleared in sleep mode, the MCU must program the DRV3201-Q1 in the desired
settings after each wake-up from sleep mode to active mode.
13
Copyright © 2012, Texas Instruments Incorporated
Product Folder Link(s): DRV3201-Q1
PRODUCT PREVIEW
Coming from full functional battery voltage range (i.e. between 4.7 V and 30 V) the internal logic, including the
SPI interface, operates even during battery voltage drops down to 3 V. When the battery drops below 3 V, the
DRV3201-Q1 triggers a complete internal reset, clearing all internal status bits and registers. Also, the SPI
communication to the MCU is disabled when the DRV3201-Q1 logic is put in reset.
DRV3201-Q1
SLVSBD6 – MAY 2012
www.ti.com
DIGITAL INPUT/OUTPUT PINS
All digital input pins (marked HVI_D in terminal function table), except the EN pin, have a threshold voltage
related to the internal VCC3 supply. Therefore, the state of these input pins is effective regardless of whether the
VDDIO level is out of limits. These digital input pins have a fail-safe ESD structure with only a reverse diode path
to ground, and no reverse diode path to any supply voltage. Depending on the function, these input pins have an
internal passive pulldown or pullup. All digital output pins (marked LVO_D) have a push-pull stage between
VDDIO and ground. Therefore, the logic high-levels are related to VDDIO.
RESET
The DRV3201-Q1 can be reset by switching the RSTN to low. When RSTN is low, all status bits and register
settings are cleared, the boost converter and the current sense amplifiers are off, and the gate-driver outputs are
actively pulled low with the maximum setting for the sink current, hence turning off the external power FETs. The
internal supplies VCC3 and VCC5 are still active when RSTN is forced low. The input high and low thresholds of
RSTN are related to VCC3, and therefore independent of VDDIO, hence the state of the RSTN pin is effective
regardless of whether the VDDIO level is out of limits.
GATE-DRIVERS
PRODUCT PREVIEW
The DRV3201-Q1 has three high-side and low-side gate-drivers. Each high-side and low-side gate-driver
contains a programmable sourcing and sinking current to charge and discharge the gate of the external power
FETs.
The digital logic prevents the simultaneous activation of high and low-side gate-driver of one power-stage. If a
command from the MCU for simultaneous activation is detected, the failure is flagged in the status register.
Gate-Driver Slope Control
The DRV3201-Q1 has been designed to support adaptive slope control by programmable sink and source
currents to charge and discharge the gates of the external power FETs. Table 1 gives the slope registers which
are supported to program the sink and source currents of the gate-drivers.
Table 1. Slope Configuration Registers
Slope
Current Range
Number of steps
HS1 & HS2
Affected Gate-Drivers
HS1/2 Slope Register
(CURR0)
Register
Rising Edge
140mA–1A
8
HS1 & HS2
HS1/2 Slope Register
(CURR0)
Falling Edge
140mA–1A
8
LS1 & LS2
LS1/2 Slope Register
(CURR1)
Rising Edge
140mA–1A
8
LS1 & LS2
LS1/2 Slope Register
(CURR1)
Falling Edge
140mA–1A
8
HS3
HS3 Slope Register
(CURR2)
Rising Edge
140mA–1A
8
HS3
HS3 Slope Register
(CURR2)
Falling Edge
140mA–1A
8
LS3
LS3 Slope Register
(CURR3)
Rising Edge
140mA–1A
8
LS3
LS3 Slope Register
(CURR3)
Falling Edge
140mA–1A
8
14
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SLVSBD6 – MAY 2012
To reduce the risk of a distorted slope due to changing the slope setting, a new slope setting for a rising edge
only becomes active after the next falling edge of the affected gate-driver and vice versa for the falling edge. This
does not apply directly after wake-up to active mode. As long as no low-side or high-side gate-driver has been
switched after wake-up to active mode, the programmed slope settings are active immediately.
To allow a high scalability of the output FETs and switching speed, there is also one general reduced current
mode setting, in which all gate charge/discharge currents are 25% of the programmed settings. Furthermore it is
possible to set the drivers to switching mode by setting bit 7 in configuration register 1 (CFG1) to 1. In this setting
the drivers are not current limited and limiting the switching speed can be done externally with resistors in the
gate lines. In this mode it is strongly recommended to set the slope registers (CURR0–3) to 0x3F to get the
maximum current setting and have the current limiting only from the external resistors.
Direct Mode (6 x Inputs Operation)
The direct mode is the default operation mode after each wake-up from sleep mode to active mode. In direct
mode, all gate-drivers can be controlled individually via the digital input pins IHSx/ILSx.
PWM Mode (3 x Inputs Operation)
DRVOFF Gate-Driver Shutoff
When the DRVOFF pin is high, the gate-driver outputs are actively pulled low with the programmed setting for
the sink current to turn off the external power FETs. Meanwhile, the IHSx/ILSx inputs can be read back through
SPI. The VDS comparators, and flag errors (if VDS is too high) are enabled which can be used to ensure
functionality of these blocks. The boost converter, the current sense amplifiers, and the internal VCC3 and VCC5
supplies are still active when DRVOFF is forced low. The input high and low thresholds of DRVOFF are related
to VCC3, and are independent of VDDIO, so the state of the DRVOFF pin is effective regardless of whether the
VDDIO level is out of limits.
Active Pulldown
When the external power FETs need to be turned off and the DRV3201-Q1 is in active mode (either by normal
control signal, DRVOFF signal, RSTN signal or by any error handling), the gate-drivers provide a low-ohmic
active pulldown. Once the gate-source voltage of the power FETs reaches less than 2 V, the programmed
current sink behavior changes into an Rdson behavior to increase the pulldown strength.
Semi-Active Pull-Down Resistor
Each high and low-side driver has a typical 500 kΩ resistor from gate to source acting as passive pulldown to
keep the external power FET turned off in unsupplied conditions. In addition a semi-active pulldown circuit is
reducing the gate impedance at a typical voltage of 2 V to about 7 kΩ. This semi-active pulldown circuit is turned
off in normal operation to avoid higher DC current consumption for the gate-driver.
Gate-Driver Shutoff Paths
Table 2 summarizes the possible states of the EN, RSTN and DRVOFF pins and the effect on the gate-drivers.
Table 2. Gate-Driver Shutoff Paths
EN
RSTN
DRVOF
F
Any Non-Masked
Error
Unpowered device (1)
0
(1)
X
X
Gate-Driver Shutoff
Logic
Semi-active pulldown + passive pulldown
X
Semi-active pulldown + passive pulldown
Reset
For 3 V < VS < 4.75 V, the VS undervoltage detection actively pulls down the gates of the external FETs. For VS < 3 V, these gates are
pulled down semi-actively.
15
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Product Folder Link(s): DRV3201-Q1
PRODUCT PREVIEW
Alternatively, the gate-drivers can be operated in PWM mode by setting bit 6 in Configuration Register 1 (CFG1)
to 1. PWM Mode controls all six gate-drivers with only three PWM signals. The valid controls in PWM mode are
the IHSx inputs. The low-side controls are derived from the corresponding IHSx signals while all safety features
remain active. In PWM mode, the ILSx inputs may be used as SPI-readable general purpose inputs.
DRV3201-Q1
SLVSBD6 – MAY 2012
www.ti.com
Table 2. Gate-Driver Shutoff Paths (continued)
EN
RSTN
DRVOF
F
Any Non-Masked
Error
1
0
X
X
Active pulldown
Reset
1
1
X
Active pulldown
Enabled
0
1 (1)
Active pulldown
Enabled
1≥0
X
Gate-Driver Shutoff
Logic
0
0
Active, controlled by inputs
Enabled
X
X
Active pulldown, afterwards device enters
sleep mode ≥ semi-active pulldown +
passive pulldown
Enabled during active pulldown, afterwards
reset in sleep mode
SAFETY
The DRV3201-Q1 has a wide range of safety features that helps the application to grant a high safety level.
Monitored Errors
The following sections describe the monitored errors. The handling of these errors is described in Configurable
Safety Mode.
Drain Source Voltage Monitoring
PRODUCT PREVIEW
The DRV3201-Q1 provides a drain-source voltage monitoring feature for each external power MOSFET. After
input pin IHSx/ILSx goes high to turn on the external power MOSFET, its drain-source voltage is monitored. If
this voltage stays higher than the VDS threshold for filter-time (tvds) then the error is raised and the status flag for
this power MOSFET is set.
The internal VDS threshold for the VDS monitoring can be set by an external analog input level on the SCTH pin,
and can be scaled in eight steps with a factor between 0 and 1 through SPI in configuration register 0 (CFG0),
bits 5:3.
The VDS comparator configuration for each gate-driver is shown in Figure 5. As shown in Figure 5, the VSH pin
is used as sense input voltage for the high-side VDS comparators. Externally, this VSH pin should be connected
to the star-point of the positive supply of the power-stages.
16
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Product Folder Link(s): DRV3201-Q1
DRV3201-Q1
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SLVSBD6 – MAY 2012
DRV3201
VSH
Battery Voltage
SCTH × Scale
GHSx
BLDC
High-Side VDSx Comp
SHSx
I_Phase
GLSx
Low-Side VDSx Comp
SCTH × Scale
Rshunt
PGND
Figure 5. VDS Comparator Configuration for Each Driver-Stage
To verify the proper operation of the VDS comparators during normal operation, either the scale factor can be
lowered through SPI, or the SCTH voltage can be externally lowered. This sets a lower VDS threshold
(depending mostly on the random comparator offset < ± 100 mV) which causes the comparators to toggle at
relative low current through the external power FETs (during normal operation without overcurrent). This is
shown in Figure 6. During this verification, the error-handling of the VDS errors can be disabled as described in
Configurable Safety Mode (configuration register 1 (CFG1), bits 3:4), such that the VDS errors are flagged in the
SPI status register 0 (STAT0) and at the ERR pin only. The SCTH pin is a high-impedance input to a MOS gate
with internal ESD protection to ground. There is no reverse pullup path present to any supply (fail-safe ESD
structure).
17
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PRODUCT PREVIEW
SLSx
DRV3201-Q1
SLVSBD6 – MAY 2012
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ILSx
SCTH × Scale
I_Phase
SCTH × Scale
Low-Side VDSx Comp signal
latched in SPI register
PRODUCT PREVIEW
Figure 6. Checking VDS Comparators During Normal Operation (Low-Side Given as Example, Principle
Also Applies to High-Side)
Shoot Through Detection and Programmable Dead Time
The DRV3201-Q1 provides a mechanism that prevents both external MOSFETs of each power-stage from
switching on at the same time connecting VS directly to GND. If the digital inputs try to force the device to switch
on high-side and low-side gate-drivers of one power-stage, the error is raised in the status register and the
bridges are switched according to Figure 7.
18
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SLVSBD6 – MAY 2012
IHSx/ILSx Inputs
IHSx
ILSx
IHSx/ILSx Outputs (Programmable Dead Time Disabled)
PRODUCT PREVIEW
IHSx
ILSx
IHSx/ILSx Outputs (Programmable Dead Time Enabled)
IHSx
ILSx
Dead Time
Dead Time
Figure 7. Driver Output During Input Failures
The dead time can be programmed in eight steps between 200 ns and 3000 ns in configuration register 0, bits
2:0. The programmed dead time is valid for all three power-stages. An internal 10 MHz oscillator is used as a
time reference for creating the dead-time steps.
The dead time can be disabled in the configurable safety mode (see Configurable Safety Mode) when operating
in direct mode. PWM mode does not support disabling the programmable dead time.
Boost Undervoltage Error
If the boost converter output voltage is below the undervoltage threshold level VVBOOST,UV (11 V–11.9 V) for tBCSD
(5 µs–6 µs), the boost undervoltage flag is set accordingly in SPI status register 1 (STAT1). Depending on the
configured safety mode (see Configurable Safety Mode), all gate-driver outputs are pulled low, and the ERR pin
is pulled low.
19
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VS Undervoltage Shutdown
If the VS voltage drops below the undervoltage threshold level VVS,UV (4.5 V–4.75 V) for tVS,SHD (5 µs–6 µs), the
VS undervoltage flag is set in SPI status register 1 (STAT1), the gate-driver outputs are pulled low, and the ERR
pin is pulled low. This happens regardless of the configured safety mode (see Configurable Safety Mode). The
SPI interface works down to 3 V. Below 3 V on VS, internal reset occurs.
VS Overvoltage Error
If the VS voltage exceeds the overvoltage threshold level VVS,OV (30 V–30.5 V) for tVS,SHD (5 µs–6 µs), the VS
overvoltage flag is set in SPI status register 1 (STAT1). Depending on the configured safety mode (see
Configurable Safety Mode), all gate-driver outputs are pulled low, and the ERR pin is pulled low.
VS Comparator Check
The VS undervoltage and overvoltage comparators can be checked by using the loss of clock (LOC) test/VS
comparator bit in configuration register 0 (CFG0). As long as this bit is set the comparators toggle and flag the
undervoltage and the overvoltage at the same time. The error handling is active, so the bridges shut down and
the ERR pin is pulled low. To reset the flags the LOC test /VS comparator bit needs to be reset and then the
flags need to be read via SPI. After this, the ERR pin goes up again. This self-check is combined with the loss of
clock self-test (see Loss of Clock).
Overtemperature Warning and Shutdown
PRODUCT PREVIEW
The thermal overload detection and protection of the device is based on five temperature sensors and two
thresholds Tmsd1 (thermal warning) and Tmsd2 (thermal global reset):
State
Global Reset
Local Shutdown
Normal Operation
Tmsd0
Tmsd1
Tmsd2
T(°C)
Figure 8. Thermal Shutdown
Normal operation of the device:
• Gate-drivers and boost converter are fully operational.
Thermal warning – overtemperature warning flag is set to 1:
• Thermal warning, stored in overtemperature warning bit in status register 0 (STAT0). This bit is reset after a
read out of this register by the MCU.
Global reset - device in shutdown:
• An internal reset is generated.
• The boost converter is stopped.
• However, the temperature monitor block monitors the temperature and does not release the reset until the
temperature drops below Tmsd0.
• Thermal hysteresis avoids any oscillation between shutdown and restart.
• The overtemperature shutdown is filtered with tSHDOWN (no unwanted shutdown by noise).
SPI Error
If the DRV3201-Q1 receives an invalid write or read access, the SPI OK bit in status register 1 (STAT1) is set to
0. This bit is set to 1 after a read out of this register by the MCU.
20
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SLVSBD6 – MAY 2012
EEPROM CRC Check
After each wake up to active mode, the DRV3201-Q1 performs an EEPROM CRC check. If the calculated CRC8
checksum does not match the CRC8 checksum stored in the EEPROM, the EEPROM Data CRC Failed flag is
set in status register 1 (STAT1).
Configuration Data CRC Check
The DRV3201-Q1 offers a security feature to permanently ensure configuration integrity employing a CRC8
checksum mechanism. The MCU can start a CRC8 checksum calculation within the DRV3201-Q1 over all
configuration registers by setting bit 0 in the CRC control register (CRCCTL) to 1. This bit stays set until the CRC
calculation is finished. There may not be any write access while the CRC engine is running, otherwise the CRC8
checksum becomes corrupt. The CRC8 checksum value calculated by the DRV3201-Q1 is stored in the CRC
calculated checksum register (CRCCALC).
The MCU itself can also calculate the expected CRC8 checksum value, based on the vector given below, and
store this expected value in the CRC expected checksum register (CRCEXP). This should be done before the
MCU initiates the CRC8 checksum calculation within the DRV3201-Q1. After the DRV3201-Q1 does the CRC
calculation, if the expected CRC stored in the CRCEXP register does not match the calculated CRC in
CRCCALC register, the Configuration Data CRC Failed flag is set in status register 1 (STAT1).
The MCU may then read back all configuration registers to search for the bit error and perform corrective actions.
PRODUCT PREVIEW
The CRC8 calculation mechanism is a generic one with following presets:
• The polynomial used is: (0 1 2 8)
• Initial value is: 11111111
See Table 3 for CRC data vector.
Table 3. CRC Data Vector
Bit Number
CRC8 Data Bus Values
[47:40]
CFG0
[39:32]
CFG1
[31:28]
CFG2
[27:22]
CURR0
[21:16]
CURR1
[15:10]
CURR2
[ 9: 4]
CURR3
[ 3: 0]
0000
Loss of Clock
If the internal clock gets stuck, the loss of clock monitor pulls the ERR pin low. During a test of this block the
ERR is also low. This self-check is combined with the VS comparator self-test (see VS Comparator Check)
Configurable Safety Mode
The DRV3201-Q1 can work in two different safety modes controlled by the external pin CSM, as described in
Table 4. This pin can be read back via SPI register RB0.
Table 4. Safety Modes
CSM
LOW
Description
Full safety mode:
All internal protection features are activated.
21
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Table 4. Safety Modes (continued)
CSM
Description
HIGH
(1)
(2)
Configurable safety mode:
Protective actions as selected in configuration register CFG_REG_1 are enabled and they set diagnostic flags, deselected
actions only set diagnostic flags without protective action.
With this mode the device can be used outside the normal operation range but below Absolute Maximum Range (see
ABSOLUTE MAXIMUM RATINGS (1) (2)) under responsibility of user.
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 voltages are with respect to network ground terminal, unless otherwise specified.
Table 5 defines the protective actions taken on certain error conditions. When the device is in full safety mode,
all internal protection features are activated, and all protective actions listed below are taken if the respective
error condition is detected. When the device is in configurable safety mode (CSM), the error conditions for which
CSM is available, the protective action and ERR pin indication (see Error Indication on ERR Pin) can be
configured with the corresponding bit in CFG1. The diagnostic flags are always set if the respective error
condition is present, regardless of the CSM setting.
Table 5. Error Conditions and Protective Actions
Error Condition
PRODUCT PREVIEW
VS undervoltage
VS overvoltage
Protective Action
Switch all gate-driver
outputs to low (active
pulldown)
Recovery
Selectable Through
CFG_REG_1 in
CSM
Flags are cleared with MCU
reading the status register or
through RESET. If the failure
remains after read out of the
register, it is immediately be
reported again.
Boost converter
undervoltage
HS VDS error
Error Indication ERR
Pin
No
Always
Yes
Selectable by
CFG_REG_1
Yes
Yes
LS VDS-error
Yes
Programmable dead time
window failure
Enforce programmable
dead time
Yes
Shoot through protection
violated
Switch high-side and lowside gate-driver outputs of
affected power-stage to low
(active pulldown). If
enabled, enforce dead time
to high-side and low-side.
No
Always
SPI error
SPI command is ignored
No
None
Configuration data CRC
error
Reported via SPI
No
None
EEPROM data CRC error
No
None
Overtemperature first
threshold
No
Always
No
Always
No
Always
Overtemperature second
threshold
Shutdown of device
LOC error
ERR pin low
After thermal recovery device
performs power on reset
Error Indication on ERR Pin
The ERR pin is an indicator for a detected error condition. It may act as interrupt to the external MCU, after
which the MCU reads all status registers to determine which error condition is detected. After entering active
mode this pin remains high as long as no error condition is detected, in case of a detected error condition the
ERR pin goes low. Error reporting occurs according to Table 6.
Table 6. Error Reporting in the Safety Modes
CSM
LOW
ERR pin configuration
(CFG1)
Do not care
Description
All error conditions are flagged on ERR pin
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Table 6. Error Reporting in the Safety Modes (continued)
CSM
HIGH
ERR pin configuration
(CFG1)
Description
1
ERR pin only shows errors for protective actions that are enabled in CSM
0
All error conditions are flagged on ERR pin
The ERR pin goes up again after a read out of the respective error flag in the status register once the respective
violation condition disappears. In case the MCU reads out the respective error flag in the status register while the
respective error condition is still present, the ERR pin shows a short positive pulse (pulse width typically 100 ns).
This behavior helps show the distinction between a loss of clock error and a VS undervoltage or overvoltage
error flag during self-tests of these safety features. After activation of these self-tests in configuration register 0
(CFG0) bit 6, the ERR pin goes down. After an MCU read out of the VS undervoltage/overvoltage flags in status
register 1 (STAT1) bits 1:0, the ERR pin should stay low if the loss of clock self-test is working properly. If the
ERR pin shows a positive pulse (pulse width typically 100 ns), this is an indication of a failure in the loss of clock
self-test.
Additional Safety Features
To verify the signal path to the DRV3201-Q1, the device allows reading back the logic level of all IHSx and ILSx
inputs from the RB0 address. These values directly reflect the state of the pin and are not registered. It is
required to ensure that the state of the IHSx and ILSx pins do not change while reading back their levels via SPI.
IHSx/ILSx Input Readback remains operational even if PWM Mode is chosen. In this case the ILSx Readback
may be used to read any logic level signal.
The edge counter allows a more robust and less time critical verification of the ILSx/IHSx signal chain and may
be more convenient to use during normal operation. This counter can be used to count the number of edges on
one or more IHSx/ILSx inputs. The MCU selects the inputs to be observed and arms the counter by writing to the
SPI register RB1. When the start bit is removed the counter stops counting edges. The obtained counter value
can be read from the SPI register RB2 and it resets by setting the CLEAR bit in SPI register RB1.
When the counter has reached its maximum value of 255 it stops counting and remains in this state.
IHSx/ILSx edge counter remains operational even if PWM Mode is chosen, and in this case it may be used to
count edges at any connected input.
Gate-Source Voltage Monitoring
The DRV3201-Q1 provides a gate-source voltage monitoring feature for the external MOSFETs. For each
external MOSFET, the VGS is monitored by a comparator with 1 V as a lower threshold, and 9 V as a higher
threshold.
For each external MOSFET, a status flag is set in SPI status register 2 (STAT2), bits 0:5. Each status bit is set to
1 when the respective VGS rises above 9 V and they are set to 0 when the respective VGS drops below 1 V.
This feature is intended for diagnostic use after startup to turn on/off the external MOSFETs and check the
respective status bits.
Ultima Ratio Support
Under certain circumstances it may be required to turn on all FETs simultaneously, which is supported by this
device. However, to minimize risk of accidental triggering two requirements need to be satisfied:
1. The MCU is required to perform an unlock sequence of three different consecutive SPI transfers.
2. When the last SPI command is sent all IHSx and ILSx inputs need to be at a high level already.
This feature is only available when operating in direct mode.
23
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PRODUCT PREVIEW
IHSx/ILSx Input Readback/Edge Counter
DRV3201-Q1
SLVSBD6 – MAY 2012
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Power-on Reset
(NPOR)
START
(0x00)
SPI Write different from
0x48
SPI Write 0x48 to the Ultima
Ratio Command Register
PRODUCT PREVIEW
1st Software
Unlocking
Sequence
Completed
(0xB7)
ERROR
(0xFF)
SPI Write different from
0x25
SPI Write 0x25 to the Ultima
Ratio Command Register
2nd Software
Unlocking
Sequence
Completed
(0xDA)
SPI Write different from
0x92 or
HSx/LSx set to low
SPI Write 0x92 to the Ultima
Ratio Command Register and
all HSx/LSx set to high
Ultima Ratio
Unlocked
(0x6D)
Figure 9. State Diagram for Unlocking Ultima Ratio
CURRENT MEASUREMENT
The two channel current measurement is measured by the voltage drop across two external shunt resistors. It
contains one shift buffer, two first and two second stages.
24
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SLVSBD6 – MAY 2012
Shift Buffer
The DRV3201-Q1 offers a unity gain amplifier that is normally used to support a shift voltage with lower output
impedance. This allows each current sense path to handle negative common-mode voltages across the external
shunt resistor. The shift voltage is applied externally on the RI pin, with the actual shift voltage buffered on the
RO pin.
The RI input pin is a high-impedance input to a MOS gate with internal ESD protection to ground. There is no
reverse pullup path present to any supply (fail-safe ESD structure).
Two First Stage Amplifiers
A first stage operational amplifier operates with an external resistor network for higher flexibility to adjust the
current measurement to the application requirements.
In the recommended application, a shift voltage that may be based on an external reference (e.g. an external
voltage regulator) can be added to move the transfer curve. Each channel of the first amplifier has its own output
going to the input of the MCU ADC.
The input pins INx and IPx pin are high-impedance inputs to a MOS gate with internal ESD protection to ground.
There is no reverse pullup path present to any supply (fail-safe ESD structure).
Two Second Stage Amplifiers
The second stage amplifiers with a separately programmable gain enable a higher resolution measurement at
low current. They can be directly connected to inputs of the MCU ADC.
The gain of the second stage amplifiers is programmable by SPI in steps two, four, six and eight using the CFG2
register.
The maximum output voltage of the O3 and O4 pins is clamped to the ADREF voltage.
ADREF Voltage Clamp
The maximum output voltage of pins O1–O4 is clamped to the voltage applied to ADREF by an active clamp.
The ADREF voltage is the reference supply voltage for the ADC in the MCU, so the outputs O1–O4 have a
maximum signal range related to the input range of the ADC in the MCU. The active clamp consumes a
maximum of 100 µA from the ADREF pin.
Current Sense Application Circuit
The standard configuration for the current sense amps are given in Figure 10.
25
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PRODUCT PREVIEW
The input of the first stage is high voltage compatible, so the device can be used to measure the voltage drop
across the low-side MOSFET for low requirement applications. The maximum output voltage of the O1 and O2
pins is clamped to the ADREF voltage.
DRV3201-Q1
SLVSBD6 – MAY 2012
www.ti.com
External
Reference
Voltage
2 Channels
RI
+
O1,2
RO
O3,4
VShift = 0.1 to 2.5V
í
R2
ADREF
I_IN
Clamp
R1
External Shunt
AGND
+
í
R1
+
1st Stage
í
2nd Stage
R4
Internal
R2
PGND
PRODUCT PREVIEW
External resistor network for
higher flexibility (A1 = 5 to 20V/V)
Application Setting Example:
Gain A1 = 20
R1 = 250
R2 = 5k
SPI Programmable Gain
A2 = 2, 4, 6, 8V/V
R3
External
Figure 10. Application Circuit for Current Sense
The output voltage at O1/2 is:
O1/ 2 = IRS
R2
+ VRO
R1
The
output
voltage
at
where g is the SPI adjusted gain in the second stage.
O3/4
is:
O3/4 = g ´ (O1/2 - VRO ) + VRO
PHASE COMPARATORS
The device contains three real time phase comparators usable for sensorless commutation and diagnostics.
Each comparator is switching at typically 75% and 25% of the supply voltage, and has an individual digital output
going to the MCU. The phase comparators are always active as long as EN is high.
SHSx
(Phase Voltage)
75% VSH
25% VSH
PHxC
(Phase Comparator Output)
tDHL
tDLH
Figure 11. Phase Comparator Rise and Fall Thresholds
Phase Comparators Application Diagram
The phase comparator configuration is given in Figure 12.
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SLVSBD6 – MAY 2012
DRV3201
VSH
Battery Voltage
GHSx
BLDC
0.75
To MCU
SHSx
PHxC
GLSx
0.25
SLSx
RShunt
Figure 12. Application Diagram for Phase Comparators
The phase comparators allow:
• Real time observation of the phase switching on node SHSx
• Measurement of the time between the Input IHSx/ILSx and the phase comparator output PHxC
• Verification of time drift in previous measurements and/or other driver-stages
As Figure 12 shows, the VSH and PGND pins are used as sense inputs to create the high-side and low-side
threshold levels for the phase comparators. Connect the VSH pin externally to the star-point of the positive
supply of the power-stages. The PGND pin is to be connected to the power-ground star-point of the powerstages. The total resistance of the internal voltage divider is typically 248 kΩ.
BOOST CONVERTER
The boost converter is based on a burst mode fixed frequency controller. During the on-time, the internal lowside boost FET is turned on until the current limit level is detected. The off-time is calculated proportionally from
an independent 2.5 MHz time-reference by sensing the supply voltage VS and the output voltage VBOOST. A
hysteretic comparator (low-level VBOOST-VS = 14 V, high level VBOOST-VS = 16 V) determines
starting/stopping the burst pulsing. The nominal switching frequency during the burst pulsing is 2.5 MHz.
The maximum current in the coil can be adjusted by the resistor Rboost_shunt such that the maximum coil
current is limited to 0.1 V/Rboost_shunt. This current limit is used by the controller to switch off the internal lowside boost FET. It is recommended to choose a coil with a current saturation level of at least 30% above the
current limit level set with the resistor Rboost_shunt.
A second internal current limit is implemented that triggers at higher currents and acts as a second level of
protection for the internal low-side boost FET in case the resistor R1 is shorted. If the Rboost_shunt is shorted,
the second current limit is used by the controller to switch off the internal low-side boost FET. Since the second
internal current limit is higher than the normal current limit set by Rboost-shunt and only meant for protecting the
internal boost FET, the external coil may saturate if the second internal current limit becomes active. To allow the
external MCU to detect this possible failure condition, the second internal current limit sets the boost
undervoltage flag (register STAT1, bit 2). This causes a shutdown of the gate-drivers depending on the
configured safety mode.
27
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PRODUCT PREVIEW
PGND
DRV3201-Q1
SLVSBD6 – MAY 2012
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To reduce noise level on the chip the boost converter can be switched off during sensitive current measurements
with the B_EN pin. As long as the disable time interval is short enough, the boost output capacitor can keep the
boost output voltage high enough. When the boost converter is disabled, the boost undervoltage monitor is active
to ensure the driver-stages are still operating correctly. During the boost undervoltage condition, the boost
switching frequency folds back to around half the normal operating frequency. This does not affect the current
limit.
Application Circuit for Boost Converter
The recommended application for the boost converter is given in Figure 13. For the best performance, a Schottky
diode and a 22 µH coil is required. The current limit for the internal FET (and the maximum current in the coil)
can be adjusted and in the recommended application it is set to 0.1 V/0.33 Ω = 300 mA.
Battery Voltage
5
22 H
1 F
VS
BOOST
SW
PRODUCT PREVIEW
B_EN
S
Controller
(toff Calc. and
Hysteretic
Regulation)
R
R/S
Latch
2nd Current Sense
(480 to 1100mA)
Boost UV
(STAT1, Bit 2)
OR
0.1V
DRV3201
GNDLS_B
330m
AGND
Star Point
on PCB
Figure 13. Recommended Application Circuit for Boost Converter
SPI INTERFACE
The SPI slave interface is used for serial communication with external SPI master (external MCU). The SPI
communication starts with the NCS falling edge, and ends with NCS rising edge. The NCS high level keeps SPI
slave interface in reset state, and SDO output 3-stated.
Address Mode Transfer
The address mode transfer is an 8-bit protocol. Both SPI slave and SPI master transmit the MSB first.
28
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SLVSBD6 – MAY 2012
1
2
3
4
5
6
7
8
SDI
R7
R6
R5
R4
R3
R2
R1
R0
X
SDO
D7
D6
D5
D4
D3
D2
D1
D0
X
NCS
SCLK
NOTE: SPI Master (MCU) and SPI Slave (DRV3201) sample received data on the falling SCLK edge, and transmit on rising SCLK edge
After the NCS falling edge, the first word of 7 bits are address bits followed by the RW bit. During the first
address transfer, the device returns the STAT1 register on SDO. Each complete 8-bit frame is processed. The
bits are ignored if NCS goes high before a multiple of 8 bits is transferred.
SPI Address Transfer Phase
Bit
Function
FIELD NAME
ADDR [6:0]
RW
D7
ADDR6
D6
ADDR5
D5
ADDR4
D4
ADDR3
D3
ADDR2
D2
ADDR1
D1
ADDR0
D0
RW
BIT DEFINITION
Register Address
RW = 1: Write access
RW = 0: Read access
When RW = 0, the SPI master performs a read access to the selected register. During the following SPI transfer,
the device returns the requested register read value on SDO, and interprets SDI bits as a next address transfer.
When RW = 1, the master performs a write access on the selected register. The slave updates the register value
during the next SPI transfer (if followed immediately) and returns the current register value on SDO.
SPI Data Transfer Phase
Bit
Function
FIELD NAME
DATA [7:0]
D7
DATA7
D6
DATA6
D5
DATA5
D4
DATA4
D3
DATA3
D2
DATA2
D1
DATA1
D0
DATA0
BIT DEFINITION
Data value for write access (8-bit)
The
table
shows
a
data
value
encoding
scheme
during
a
write
access.
It is possible to mix the two access modes (write and read access) during one SPI communication sequence
(NCS = 0). The SPI communication can be terminated after a single 8-bit SPI transfer by asserting NCS = 1. The
device returns STAT1 register (for the very first SPI transfer after power-up) or current register value addressed
during the SPI transfer address phase.
Device Data Response
Bit
Function
R7
REG7
R6
REG6
R5
REG5
R4
REG4
R3
REG3
R2
REG2
R1
REG1
R0
REG0
29
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Figure 14. Single 8-bit SPI Frame/Transfer
DRV3201-Q1
SLVSBD6 – MAY 2012
FIELD NAME
REG [7:0]
www.ti.com
BIT DEFINITION
Internal register value
All unused bits are set to zero.
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
SDI
R7
R6
R5
R4
R3
R2
R1
R0
R7
R6
R5
R4
R3
R2
R1
R0
X
SDO
D7
D6
D5
D4
D3
D2
D1
D0
D7
D6
D5
D4
D3
D2
D1
D0
X
NCS
SCLK
8-Bit SPI Transfer
8-Bit SPI Transfer
L16-Bit SPI FrameL
NOTE: SPI Master (MCU) and SPI Slave (DRV3201) sample received data on the falling SCLK edge, and transmit on rising SCLK edge
16-Bit SPI Frame Example: Write Access followed by Read Access
NCS
PRODUCT PREVIEW
SDI
SDO
ADDR1, RW = 1 (WR)
WR DATA1
ADDR2, RW = 0 (RD)
1st Transfer
2nd Transfer
3rd Transfer
Status Flags
Response to Transfer 1
Status Flags
Zero Vector
Response to Transfer 3
16-Bit SPI Frame Example: Read Access followed by Read Access
NCS
SDI
ADDR1, RW = 0 (RD)
SDO
Status Flags
1st Transfer
Zero Vector
ADDR2, RW = 0 (RD)
Response to Transfer 1
Status Flags
3rd Transfer
Zero Vector
Response to Transfer 3
16-Bit SPI Frame Example: Write Access followed by Write Access
NCS
SDI
ADDR1, RW = 1 (WR)
WR DATA1
ADDR2, RW = 1 (WR)
WR DATA2
1st Transfer
2nd Transfer
3rd Transfer
4th Transfer
SDO
Status Flags
Response to Transfer 1
Status Flags
Response to Transfer 3
16-Bit SPI Frame Example: Read Access followed by Write Access
NCS
SDI
ADDR1, RW = 0 (WR)
ADDR2, RW = 1 (WR)
WR DATA2
1st Transfer
2nd Transfer
3rd Transfer
SDO
Status Flags
Response to Transfer 1
Response to Transfer 2
Zero Vector
Status Flags
16-Bit SPI Frame Example: Read Access followed by Read Access followed by Write Access
NCS
SDI
ADDR1, RW = 0 (WR)
ADDR2, RW = 0 (RD)
ADDR3, RW = 1 (WR)
1st Transfer
2nd Transfer
3rd Transfer
WR DATA3
4th Transfer
SDO
Status Flags
Response to Transfer 1
Response to Transfer 2
Response to Transfer 3
16-Bit SPI Frame Example: Read Access followed by Read Access followed by Read Access
NCS
SDI
ADDR1, RW = 0 (WR)
ADDR2, RW = 0 (RD)
ADDR3, RW = 0 (RD)
1st Transfer
2nd Transfer
3rd Transfer
SDO
Status Flags
Response to Transfer 1
Response to Transfer 2
Zero Vector
Response to Transfer 3
Figure 15. SPI Frame examples
30
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SLVSBD6 – MAY 2012
Address
Name
RW
Reset Value
0x00
Reserved
0x01
Configuration Register 0 (CFG0)
RW
8'h3F
0x02
Configuration Register 1 (CFG1)
RW
8'h3F
0x03
Configuration Register 2 (CFG2)
RW
4'h0
0x04
HS1/2 Slope Register (CURR0)
RW
6’h3F
0x05
LS1/2 Slope Register (CURR1)
RW
6’h3F
0x06
HS3 Slope Register (CURR2)
RW
6’h3F
0x07
LS3 Slope Register (CURR3)
RW
6’h3F
0x08-0x0F
Reserved
0x10
Status Register 0 (STAT0)
RO
8’h00
0x11
Status Register 1 (STAT1)
RO
8’h00
0x12
Status Register 2 (STAT2)
RO
6’h00
0x13-0x1F
Reserved
0x20
CRC Control Register (CRCCTL)
RW
1’h0
0x21
CRC Calculated (CRCCALC)
RO
8’h0
0x22
CRC Expected (CRCEXP)
RW
8’h0
0x23
HS/LS Read Back (RB0)
RO
6’h0
0x24
HS/LS Count Control (RB1)
RW
6’h0
0x25
HS/LS Count (RB2)
RO
8’h0
0x26-0x2F
Reserved
0x30
Ultima Ratio Command (UR)
RW
8’h0
0x31-7F
Reserved
PRODUCT PREVIEW
Register Address Map
Detailed Register Definitions
Table 7. Configuration Register 0 (CFG0)space(Addr. 0x01)
Bits
R/W
Reset
Definition
7
RW
1’h0
Current capability
1: Reduced current mode (all gate charge/discharge currents are 25%)
0: Full current mode
6
RW
1’h0
Loss of clock detection test/VS comparator test
If this bit is set, the clock for LOC monitor is permanently set to high. Additionally, the VS comparators
show a VS undervoltage and a VS overvoltage at the same time in status register 1 (STAT1), bits 1:0.
Both LOC and VS undervoltage/overvoltage are indicated on the ERR pin. A way to distinguish
between LOC and VS undervoltage/overvoltage is described in VS Comparator Check.
Once the bit is cleared, the error-flag disappears after read out.
5:3
RW
3’h7
VDS monitoring scale factor VSCTH/VDS threshold
000: 0
001: 1/7
010: 2/7
011: 3/7
100: 4/7
101: 5/7
110: 6/7
111: 1 (Voltage follower)
2:0
RW
3’h7
Programmable dead time
000: 200-300 ns
001: 300-400 ns
010: 500-600 ns
011: 900-1000 ns
100: 1400-1500 ns
101: 1900-2000 ns
110: 2400-2500 ns
111: 2900-3000 ns
31
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Table 8. Configuration Register 1 (CFG1)space(Addr. 0x02)
Bits
R/W
Reset
Definition
7
RW
1’h0
0: Adjustable HS/LS currents for rising/falling edges according to registers CURR0–3
1: Unlimited HS/LS currents for rising/falling edges
6
RW
1’h0
Set PWM mode
All gate-drivers can be driven with 3 PWM signals
5
RW
1’h1
ERR pin configuration
In CSM, ERR pin only shows errors that are actually handled in CSM if this bit is set or else all errors
are flagged
4
RW
1’h1
Enable LS VDS error handling in CSM
3
RW
1’h1
Enable HS VDS error handling in CSM
2
RW
1’h1
Enable programmable dead time in CSM
1
RW
1’h1
Enable boost undervoltage handling in CSM
0
RW
1’h1
Enable VS overvoltage handling in CSM
Table 9. Configuration Register 2 (CFG2)space(Addr. 0x03)
PRODUCT PREVIEW
Bits
R/W
Reset
Definition
7:4
RO
1’h0
Reserved
3:2
RW
2’h0
Current amplifier gain for second stage second amplifier (O4/O2)
00: 2
01: 4
10: 6
11: 8
1:0
RW
2’h0
Current amplifier gain for second stage first amplifier (O3/O1)
00: 2
01: 4
10: 6
11: 8
Table 10. HS1/2 Slope Register (CURR0)space(Addr. 0x04)
Bits
R/W
Reset
Definition
7:6
RO
2’h0
Reserved
5:3
RW
3’h7
Adjust HS0/1 current for rising edge
000: 140 mA
001: 140 mA
010: 290 mA
011: 430 mA
100: 570 mA
101: 710 mA
110: 850 mA
111: 1 A
2:0
RW
3’h7
Adjust HS0/1current for falling edge
000: 140 mA
001: 140 mA
010: 290 mA
011: 430 mA
100: 570 mA
101: 710 mA
110: 850 mA
111: 1 A
32
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Product Folder Link(s): DRV3201-Q1
DRV3201-Q1
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SLVSBD6 – MAY 2012
Table 11. LS1/2 Slope Register (CURR1)space(Addr. 0x05)
Bits
R/W
Reset
Definition
7:6
RO
2’h0
Reserved
5:3
RW
3’h7
Adjust LS0/1 current for rising edge
000: 140 mA
001: 140 mA
010: 290 mA
011: 430 mA
100: 570 mA
101: 710 mA
110: 850 mA
111: 1 A
2:0
RW
3’h7
Adjust LS0/1 current for falling edge
000: 140 mA
001: 140 mA
010: 290 mA
011: 430 mA
100: 570 mA
101: 710 mA
110: 850 mA
111: 1 A
Bits
R/W
Reset
Definition
7:6
RO
2’h0
Reserved
5:3
RW
3’h7
Adjust HS2 current for rising edge
000: 140 mA
001: 140 mA
010: 290 mA
011: 430 mA
100: 570 mA
101: 710 mA
110: 850 mA
111: 1A
2:0
RW
3’h7
Adjust HS2 current for falling edge
000: 140 mA
001: 140 mA
010: 290 mA
011: 430 mA
100: 570 mA
101: 710 mA
110: 850 mA
111: 1 A
PRODUCT PREVIEW
Table 12. HS3 Slope Register (CURR2)space(Addr. 0x06)
Table 13. LS3 Slope Register (CURR3)space(Addr. 0x07)
Bits
R/W
Reset
Definition
7:6
RO
2’h0
Reserved
5:3
RW
3’h7
Adjust LS2 current for rising edge
000: 140 mA
001: 140 mA
010: 290 mA
011: 430 mA
100: 570 mA
101: 710 mA
110: 850 mA
111: 1 A
33
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SLVSBD6 – MAY 2012
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Table 13. LS3 Slope Register (CURR3)space(Addr. 0x07) (continued)
Bits
R/W
Reset
Definition
2:0
RW
3’h7
Adjust LS2 current for falling edge
000: 140 mA
001: 140 mA
010: 290 mA
011: 430 mA
100: 570 mA
101: 710 mA
110: 850 mA
111: 1 A
Table 14. Status Register 0 (STAT0)space(Addr. 0x10)
PRODUCT PREVIEW
Bits
R/W
Reset
Definition
7
RO
1’h0
Reserved
6
RO
1’h0
Over temperature warning
5
RO
1’h0
HS2 VDS error
4
RO
1’h0
HS1 VDS error
3
RO
1’h0
HS0 VDS error
2
RO
1’h0
LS2 VDS error
1
RO
1’h0
LS1 VDS error
0
RO
1’h0
LS0 VDS error
Bits
R/W
Reset
Definition
7
RO
1’h1
SPI OK flag
6
RO
1’h0
Configuration data CRC failed
5
RO
1’h0
EEPROM data CRC failed
4
RO
1’h0
Programmable dead time violated
3
RO
1’h0
Shoot through protection violated
2
RO
1’h0
Boost undervoltage
1
RO
1’h0
VS overvoltage
0
RO
1’h0
VS undervoltage
Table 15. Status Register 1 (STAT1)space(Addr. 0x11)
Table 16. Status Register 2 (STAT2)space(Addr. 0x12)
Bits
R/W
Reset
Definition
7:6
RO
2’h0
Reserved
5
RO
1’h0
HS2 VGS comparator (0 if VGS < 1 V, 1 if VGS > 9 V)
4
RO
1’h0
HS1 VGS comparator (0 if VGS < 1 V, 1 if VGS > 9 V)
3
RO
1’h0
HS0 VGS comparator (0 if VGS < 1 V, 1 if VGS > 9 V)
2
RO
1’h0
LS2 VGS comparator (0 if VGS < 1 V, 1 if VGS > 9 V)
1
RO
1’h0
LS1 VGS comparator (0 if VGS < 1 V, 1 if VGS > 9 V)
0
RO
1’h0
LS0 VGS comparator (0 if VGS < 1 V, 1 if VGS > 9 V)
34
Copyright © 2012, Texas Instruments Incorporated
Product Folder Link(s): DRV3201-Q1
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SLVSBD6 – MAY 2012
Table 17. CRC Control Register (CRCCTL)space(Addr. 0x20)
Bits
R/W
Reset
Definition
7:1
RO
7’h0
Reserved
0
RO
1’h0
Starts configuration data CRC8 calculation. Bit gets cleared when calculation is finished
To perform CRC check:
1.Calculate CRC checksum
2.Store calculated checksum in CRCEXP register
3.Set bit 0 CRC control register (CRCCTL) to 1
4.Bit gets cleared when calculation is finished
5.Failing checksum is indicated in STAT1 register
6.Calculated checksum can be read from CRCCALC register
Table 18. CRC Calculated Checksum Register (CRCCALC)space(Addr. 0x21)
Bits
R/W
Reset
Definition
7:0
RO
8’h0
Checksum generated by internal CRC engine
Bits
R/W
Reset
Definition
7:0
RW
8’h0
Checksum externally calculated by microcontroller
PRODUCT PREVIEW
Table 19. CRC Expected Checksum Register (CRCEXP)space(Addr. 0x22)
Table 20. Input Read Back (RB0)space(Addr. 0x23)
Bits
R/W
Reset
Definition
7
RO
1’h0
Reserved
6
RO
1’h0
CSM input
5
RO
1’h0
LS2 input
4
RO
1’h0
LS1 input
3
RO
1’h0
LS0 input
2
RO
1’h0
HS2 input
1
RO
1’h0
HS1 input
0
RO
1’h0
HS0 input
Table 21. HS/LS Count Control (RB1)space(Addr. 0x24)
Bits
R/W
Reset
Definition
7
RW
1’h0
Clear edge counter
This bit has priority over 6 down to 0
6
RW
1’h0
Start/stop counter
0: Counter stopped
1: Counter running
5
RW
1’h0
Enable LS2 edge count
4
RW
1’h0
Enable LS1 edge count
3
RW
1’h0
Enable LS0 edge count
2
RW
1’h0
Enable HS2 edge count
1
RW
1’h0
Enable HS1 edge count
0
RW
1’h0
Enable HS0 edge count
Table 22. HS/LS Count (RB2)space(Addr. 0x25)
Bits
R/W
Reset
Definition
7:0
RO
8’h0
HS/LS edge count
Counter stops counting at 0xFF
35
Copyright © 2012, Texas Instruments Incorporated
Product Folder Link(s): DRV3201-Q1
DRV3201-Q1
SLVSBD6 – MAY 2012
www.ti.com
Table 23. Ultima Ratio Command (UR)space(Addr. 0x30)
Bits
R/W
Reset
Definition
7:0
RO
8’h0
Ultima ratio command
See specification for command sequence
PRODUCT PREVIEW
36
Copyright © 2012, Texas Instruments Incorporated
Product Folder Link(s): DRV3201-Q1
DRV3201-Q1
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SLVSBD6 – MAY 2012
APPLICATION INFORMATION
PGND
R2a=1k:
Rshunt2=0.5m: 5W
R2a=1k:
R1a=1k:
R2b=
15k:
to uC
ADC
R2b=15k:
from uC ADC
or other ref.
voltage
from uC
IHS3 59
from TPS6538x,
use same supply
as used for uC IO
from uC
from uC
ILS3 60
from uC
ILS2 62
IHS2 61
from uC
from uC
ILS1 64
IHS1 63
R1a=1k:
Q3LS
Q3HS
PGND
Q2LS
PGND
Q2HS
from uC ADC
or other ref.
voltage
IP2 50
IN2 49
RI 53
RO 52
IP1 54
O1 55
IN1 56
O4 46
4 SHS3
GNDL 45
5 GHS3
ADREF 44
6 PGND
AMUX (GND) 43
7 SLS2
to uC ADC
to uC ADC
from TPS6538x,
use same supply
as used for uC
ADC
4.7nF
VCC3 42
DRV3201
8 GLS2
TEST (GND) 41
9 SHS2
VCC5 40
10 GHS2
GNDA 39
11 GNDA
ERR 38
12 SCTH
RSTN 37
4.7nF
to uC
from TPS6538x,
connect to NRST
from TPS6538x,
connect to ENDRV
from uC
from uC
NC 33
32 NC
31 GNDLS_B
30 SW
28 VS
29 BOOST
27 GNDA
26 SDO
24 NCS
25 SDI
B_EN 34
16 GHS1
23 GNDL
15 SHS1
Q1HS
22 SCLK
CSM 35
21 DRVOFF
EN 36
14 GLS1
20 GNDA
13 SLS1
Q1LS
19 PH3C
2.2mF
PGND
O3 47
3 GLS3
18 PH2C
2.2µ F
BLDC
Motor
O2 48
2 SLS3
17 PH1C
2.2µ F
PGND
GNDA 51
1 VSH
GNDA 57
100nF
5:
VDDIO 58
PGND
KL30
to uC
ADC
PRODUCT PREVIEW
R1b=
15k:
Rshunt1=0.5m: 5W
R1b=15k:
100µ F
(50V)
L1=B82442A1223K000
D1=SS28
QxHS, QxLS = IRFS3004PBF
Rshunt1,2 = BVR-Z-R0005
OHMS,1%,5W)
330m:
1µF
(50V)
uC
SPI
from uC
to uC
to uC
to uC
D1
L1 = 22µH
5:
INDUCTOR,SMT,22uH,10%,480mA)
(DIODE,SMT,SCHOTTKY,80V,2A)
(HEXFET,N-CHANNEL,POWER MOSFET,D2PACK)
(RES,SMT,4026,PRECISION POWER,0.0005
Figure 16. DRV3201-Q1 Typical Application Diagram
37
Copyright © 2012, Texas Instruments Incorporated
Product Folder Link(s): DRV3201-Q1
DRV3201-Q1
SLVSBD6 – MAY 2012
www.ti.com
FR
Flexray
CAN
CAN
KL15
WakeUp
CAN
Supply
CAN
FR
OUT
OUT
VBAT
BOOST
EN
EN
Relay Driver
KL30
PreRegulator
C IO
Supply
Charge
Pump
C Core
Supply
Voltage
Monitoring
NHET
3 x PHxC
3 * PowerStage
- Input Capture
- Input Capture
Power Supply
Vds
Mon
Bandgap
Ref 2
Bridge Driver
KL30
Phase
Comp
VSH
GHSx
SHSx
SPR
Switch
Networks
Safety Diagnostics
Protected
Sensor
Supply
- PWM
Voltage
Monitoring
Bridge
Driver
3 x IHSx
3 x ILSx
SLSx
Reset /
Enable
______
RESET
C ERROR
Monitor
_______
ERROR
Motor
GLSx
Sensors
x = [1..3]
ADC1
Current
CurrentSense
Sense
2x
ADC2
PRODUCT PREVIEW
Q&A
Watchdog
SPI
Ta/Tj Over
Temp
shutdown
Diagnose &
Config
TPS65381/65383
SPI
Diagnose &
Config
Bridge Error
Monitoring
Tj Over
Temp
shutdown
SPI
INT
TMS570
Error Monitoring:
- VDS Mon.
- Shoot Through
- Voltage Monitoring on
VBAT, VBOOST and
internal supplies.
- Temp. Warning
- etc.
DRV3201
Analog Sensor Signal
Digital Sensor Signal
Figure 17. Electrical Power Steering Example
POWER CONSUMPTION
The DRV3201-Q1 has been designed to drive six external power FETs with 250 nC gate charge at 30 kHz PWM
frequency. The necessary current for charging the gates of these external power FETs is delivered by the boost
converter. The three internal high-side gate-drivers and the three internal low-side gate-drivers are supplied out
of the boost converter. The following graphs show the total supply current consumption against the supply
voltage for varying boost load current.
38
Copyright © 2012, Texas Instruments Incorporated
Product Folder Link(s): DRV3201-Q1
DRV3201-Q1
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SLVSBD6 – MAY 2012
SUPPLY CURRENT
vs
SUPPLY VOLTAGE
SUPPLY CURRENT
vs
SUPPLY VOLTAGE
200
200
IBoost = 0mA
IBoost = 5mA
IBoost = 20mA
IBoost = 30mA
IBoost = 40mA
180
160
160
140
140
Supply Current (mA)
120
100
80
120
100
80
60
60
40
40
20
20
TA = 25°C
0
0
5
TA = 125°C
10
15
20
Supply Voltage (V)
25
30
0
0
G001
Figure 18. Supply Current vs. Supply Voltage for
Varying Boost Load Current at TA = 25°C
5
10
15
20
Supply Voltage (V)
25
30
G002
Figure 19. Supply Current vs. Supply Voltage for
Varying Boost Load Current at TA = 125°C
In these graphs, the quiescent current consumption from the boost converter taken by the non-switching gatedrivers is taken into account (see, parameter RGSa2 in ELECTRICAL CHARACTERISTICS). However, the current
consumption from the boost converter due to gate-driver switching is not taken into account. This gate-driver
switching current, which forms the actual load current of the boost converter, consists of two components: the
internal gate-driver switching currents, and the external FET gate charging currents.
The switching current from the internal gate-drivers (without the external power FETs) is given in parameter
VGS,HS,high in ELECTRICAL CHARACTERISTICS, for 30 kHz PWM frequency and all six gate-drivers.
The total load current Iboost is given by the sum of Equation 1 and Equation 2:
rivers switching. The expected current consumption from the boost converter due to switching gate-drivers
(without the external power FETs) can be calculated as follows:
fPWM g #FETs g lboost,swmax fPWM g #FETs g 3 mA
lboost,sw =
=
30 kHZ g 6
30 kHZ g 6
(1)
The switching current formed by charging the gates of the external FETs at the given PWM frequency can be
calculated as follows:
lboost,sw = fPWM g #FETs g Qgate
(2)
Iboost = Iboost,sw + Iboost,qg
(3)
Calculation example 1:
fPWM = 25 kHz
Qgate = 250 nC
Number of FETs = 6
Iboost,sw = 25 kHz•6•3 mA/30 kHz•6 = 2.5 mA
Iboost,qg = 25 kHz•6•250 nC = 37.5 mA
Iboost = 2.5 mA + 37.5 mA = 40 mA
Using the IBOOST = 40 mA from Figure 18 and Figure 19, the total current consumption from VS is 130 mA at
TA = 25°C and for TA = 125°C. This gives a total power consumption of 1.82 Watt at TA = 25°C and at TA =
125°C for VS = 14 V.
39
Copyright © 2012, Texas Instruments Incorporated
Product Folder Link(s): DRV3201-Q1
PRODUCT PREVIEW
Supply Current (mA)
IBoost = 0mA
IBoost = 5mA
IBoost = 20mA
IBoost = 30mA
IBoost = 40mA
180
DRV3201-Q1
SLVSBD6 – MAY 2012
www.ti.com
Calculation example 2:
fPWM = 20kHz
Qgate = 200nC
Number of FETs = 6
Iboost,sw = 20 kHz•6•3 mA/30 kHz•6 = 2 mA
Iboost,qg = 20 kHz•6•200 nC = 24 mA
Iboost = 2 mA + 24 mA = 27 mA
To estimate the total current consumption from the VS battery supply, the curve IBOOST = 30 mA from
Figure 14 and Figure 15 can be used. From this curve, it follows that for VS = 14 V, the total current consumption
from VS is 105 mA at TA = 25°C respectively 107 mA at TA = 125°C. This gives a total power consumption of
1.47 Watt at TA = 25°C respectively, 1.50 Watt at TA = 125°C for VS = 14 V.
From these examples, it can be seen how the gate-charge and the PWM frequency impact the load current for
the boost converter and the total battery current consumption in Figure 18 and Figure 19. The total power
consumption can be calculated from this.
BOOST CONVERTER
PRODUCT PREVIEW
The output current capability of the boost converter can be configured with the external Rshunt_boost resistor to
0.1 V/Rshunt_boost (please note that this resistor needs to be able to conduct the boost switching current). The
output current capability can be dimensioned to the needed current determined by the PWM switching frequency
and the gate-charge of the external power FETs. It is recommended to choose a coil having a current saturation
level of at least 30% above the current limit level set with the resistor Rboost_shunt. The operation principle of
the boost converter is based on a burst mode fixed frequency controller. During the on-time, the internal low-side
boost FET is turned on until the current limit level is detected. The off-time is calculated proportionally from a 2.5
MHz time-reference by sensing the supply voltage VS and the output voltage VBOOST. The formula for the
calculated off-time is given in Equation 4, with fboost = 2.5 MHz.
VS
t off =
VBOOST g fBOOST
(4)
For steady state, the current in the coil looks like Figure 20.
High battery
voltage at VS
Nominal battery
voltage at VS
Low battery
voltage at VS
IL
ILcurlim =
0.1V / Rboost_shunt
'Itoff =
(VBOOST-VS)*toff / L
'Iton =
VS*ton
/L
ton
toff =
VS / (VBOOST * fBOOST)
ton+toff = 1 / fBOOST
ton
toff =
VS / (VBOOST * fBOOST)
ton+toff = 1 / fBOOST
ton
toff =
VS / (VBOOST * fBOOST)
ton+toff = 1 / fBOOST
Figure 20. Coil Current Waveforms in Steady State for Nominal, High and Low Battery Voltage
From this figure, the ripple current and the boost output current can be calculated as follows:
ILripple =
IBOOST =
æ
VS
VS ö (VBOOST - VS) g VS
g ç1 ÷=
L g fBOOST è
VBOOST ø L g fBOOST g VBOOST
(5)
æ (V
- VS) g VS ö
VS
g ILcurlim - 1 g ç BOOST
÷
2
g
VBOOST
L
f
BOOST g VBOOST ø
è
(6)
40
Copyright © 2012, Texas Instruments Incorporated
Product Folder Link(s): DRV3201-Q1
DRV3201-Q1
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SLVSBD6 – MAY 2012
æ
0.1 V
fBOOST = 2.5 MHz; (VBOOST - VS) = 15 V; ILcur lim = ç
ç Rshunt _ boost
è
ö
÷
÷
ø
(7)
As can be seen from Equation 6, the boost output current capability for a given IL_curlim is the lowest for the
minimum supply voltage VS. The boost output current capability should be dimensioned (by setting IL_curlim
with external Rshunt_boost) so the needed output current (based on PWM frequency and gate-charge of the
external power FETs) can be delivered at the needed minimum supply voltage for the application. The following
equation gives IL_curlim as a function of IBOOST and VS:
ILcurlim = IBOOST g
æ (V
- VS) g VS ö
VBOOST 1
g ç BOOST
+
÷
2
VS
è L g fBOOST g VBOOST ø
(8)
To set the IL_curlim, the minimum application supply should be used in this equation and IBOOST according to
Equation 3.The minimum application supply voltage the DRV3201-Q1 can support is 4.75 V.
The nominal switching frequency during the burst pulsing is 2.5 MHz once the boost has reached steady state.
During startup of the boost, the internal time reference is slower by a factor of three, resulting in three times
longer off-times to allow the coil current to decrease sufficiently compared to Equation 4.
VBOOST-VS
16V
14V
1) When VBOOST-VS>16V, boost FET kept on untill
current limit reached. No off-time calculated untill
VBOOST-VS<14V
2) When VBOOST-VS<14V,
new off-time calculated.
Boost FET turned on after off-time passed
IL
ILcurlim =
0.1VRboost_shunt
ton
toff = VS / (VBOOST * fBOOST)
toff =
VS / (VBOOST * fBOOST)
toff = VS / (VBOOST * fBOOST)
ton+toff = 1 / fBOOST
ton
toff = VS / (VBOOST * fBOOST)
ton+toff = 1 / fBOOST
Figure 21. Boost Waveforms Showing Burst Pulsing Controlled by Hysteretic Comparator Levels
41
Copyright © 2012, Texas Instruments Incorporated
Product Folder Link(s): DRV3201-Q1
PRODUCT PREVIEW
As shown in Equation 6, the boost output current capability increases for higher supply voltage VS. If the boost
output current capability is dimensioned so it can deliver the necessary output current for the minimum supply
voltage, it actually delivers more current than needed for nominal supply voltage and the boost voltage increases.
Therefore, a hysteretic comparator (low level VBOOST-VS = 14 V, high level VBOOST-VS = 16 V) determines
starting/stopping the burst pulsing as shown in Figure 21.
PACKAGE OPTION ADDENDUM
www.ti.com
7-May-2012
PACKAGING INFORMATION
Orderable Device
Status
(1)
DRV3201QPAPQ1
PREVIEW
Package Type Package
Drawing
HTQFP
PAP
Pins
Package Qty
64
160
Eco Plan
TBD
(2)
Lead/
Ball Finish
Call TI
MSL Peak Temp
(3)
Samples
(Requires Login)
Call TI
(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)
Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability
information and additional product content details.
TBD: The Pb-Free/Green conversion plan has not been defined.
Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that
lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes.
Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and package, or 2) lead-based die adhesive used between
the die and leadframe. The component is otherwise considered Pb-Free (RoHS compatible) as defined above.
Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight
in homogeneous material)
(3)
MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature.
Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information
provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and
continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals.
TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release.
In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis.
Addendum-Page 1
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