Dialog DA9213-A Auto grade multi-phase 5a/phase buck converter Datasheet

DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
General Description
DA9213-A and DA9214-A are PMICs optimized for the supply of CPUs, GPUs, and DDR memory
rails in automotive in-vehicle infotainment systems, Advanced Driver Assistance Systems (ADAS),
navigation and telematics applications. The fast transient response (10 A/µs) and load regulation are
optimized for the latest generation of multi core application processors.
DA9213-A operates as a single four-phase buck converter delivering up to 20 A output current.
DA9214-A integrates two dual-phase buck converters, capable of delivering 2x10 A output current.
Each buck regulates a programmable output voltage in the range 0.3 - 1.57 V. With an external
resistor divider the output voltage can be set to any voltage between 1.57 V and 4.3 V. The input
voltage range of 2.8 – 5.5 V makes it suited for a wide variety of low voltage systems, including all
Li-Ion battery powered applications.
To guarantee the highest accuracy and to support multiple PCB routing scenarios without loss of
performance, a remote sensing capability is implemented in both the DA9213-A and DA9214-A.
The power devices are fully integrated, so no external FETs or Schottky diodes are needed.
A programmable soft start-up can be enabled, which limits the inrush current from the input node and
secures a slope controlled activation of the rail.
The Dynamic Voltage Control (DVC) supports adaptive adjustment of the supply voltage depending
2
on the processor load, either via direct register writes through the communication interface (I C or
SPI compatible) or via an input pin.
DA9213-A and DA9214-A feature integrated over-temperature and over-current protection for
increased system reliability without the need for external sensing components. The safety feature set
is completed by a VDDIO under voltage lockout.
2
The configurable I C address selection via GPI allows multiple instances of DA9213-A and DA9214A to be placed in an application sharing the same communication interface with different addresses.
Key Features
■
■
■
■
■
■
■
■
2.8 V to 5.5 V input voltage
1x 20 A DA9213-A
2x 10 A DA9214-A
3 MHz nominal switching frequency
Max inductor height 1.2 mm
±1 % accuracy (static)
±3 % accuracy (dynamic)
0.3 V to 1.57 V output voltage
1.57 to 4.3 V with resistor divider
■
■
■
■
■
■
■
■
■
Dynamic Voltage Control (DVC)
Automatic phase shedding
Integrated power switches
Remote sensing at point of load
2
I C/SPI compatible interface
Adjustable soft start
-40 to +105 ºC temperature range
AEC-Q100 grade 2 qualified
Package 66 VFBGA 0.5 mm pitch
Applications
■ In-car infotainment
■ Navigation and telematics
■ Automotive display clusters
■ Mobile computing
■ Advanced Driver Assistance Systems (ADAS) ■ Industrial embedded systems
Datasheet
CFR0011-120-00
Revision 1.4
1 of 62
08-May-2017
© 2017 Dialog Semiconductor
DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
VDD_B2
VDD_B1
VDD_A2
VSYS
VDD_A1
System Diagrams
1µF
4x 10µF
FBAP
IC_EN
GPI0
GPI
GPI1
GPI
GPIO2
GPIO
DIGITAL
CORE
OTP
MEMORY
4x 0.22µH
CTRL
+
DRIVE
BIAS
SUPERV
OSC
REGISTER
SPACE
PoL
4x 47µF
nIRQ
OUT
VDDIO
DVS
2/4-WIRE INTERFACE
IN
FBAN
FBBP
FBBN
nCS/GPI4
GPIO
IN
SCL/SK
SO/GPIO3
GPIO
VSS_ANA
SDA/SI
100nF
1µF
VDD_B2
4x 10µF
Buck A
IC_EN
GPI0
GPI
GPI1
GPI
GPIO2
VDD_B1
VDD_A2
VSYS
VDD_A1
Figure 1: DA9213-A System Diagram
GPIO
DIGITAL
CORE
OTP
MEMORY
CTRL
+
DRIVE
PoL
2x 47µF
BIAS
SUPERV
OSC
REGISTER
SPACE
DVS
DAC
Buck B
nIRQ
FBAP
2x 0.22µH
OUT
FBAN
FBBP
2x 0.22µH
VDDIO
2/4-WIRE INTERFACE
100nF
CTRL
+
DRIVE
PoL
IN
GPIO
IN
VSS_ANA
GPIO
2x 47µF
DVS
DAC
nCS/GPI4
SO/GPIO3
SCL/SK
SDA/SI
FBBN
Figure 2: DA9214-A System Diagram
Datasheet
CFR0011-120-00
Revision 1.4
2 of 62
08-May-2017
© 2017 Dialog Semiconductor
DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
Contents
General Description ............................................................................................................................ 1
Key Features ........................................................................................................................................ 1
Applications ......................................................................................................................................... 1
System Diagrams ................................................................................................................................ 2
Contents ............................................................................................................................................... 3
Figures .................................................................................................................................................. 5
Tables ................................................................................................................................................... 5
1
Terms and Definitions ................................................................................................................... 6
2
Pinout ............................................................................................................................................. 7
3
Absolute Maximum Ratings ....................................................................................................... 10
4
Recommended Operating Conditions ....................................................................................... 10
5
Electrical Characteristics ........................................................................................................... 11
6
Efficiency Measurements ........................................................................................................... 18
7
Functional Description ............................................................................................................... 20
7.1 DC-DC Buck Converter ....................................................................................................... 23
7.1.1
Switching Frequency ........................................................................................... 24
7.1.2
Operation Modes and Phase Selection ............................................................... 24
7.1.3
Output Voltage Selection ..................................................................................... 24
7.1.4
Soft Start Up ........................................................................................................ 25
7.1.5
Current Limit ........................................................................................................ 25
7.1.6
Variable VOUT above 1.57 V .............................................................................. 25
7.2 Ports Description ................................................................................................................. 27
7.2.1
VDDIO.................................................................................................................. 27
7.2.2
IC_EN .................................................................................................................. 27
7.2.3
nIRQ..................................................................................................................... 27
7.2.4
GPIO Extender .................................................................................................... 27
7.3 Operating Modes ................................................................................................................. 30
7.3.1
ON Mode ............................................................................................................. 30
7.3.2
OFF Mode ............................................................................................................ 30
7.4 Control Interfaces ................................................................................................................ 30
7.4.1
4-WIRE Communication ...................................................................................... 30
7.4.2
2-WIRE Communication ...................................................................................... 35
7.4.3
Details of the 2-WIRE Control Bus Protocol ........................................................ 36
7.5 Internal Temperature Supervision ....................................................................................... 39
8
Register Definitions .................................................................................................................... 40
8.1 Register Map ....................................................................................................................... 40
8.2 Register Definitions ............................................................................................................. 42
8.2.1
Register Page Control ......................................................................................... 42
8.2.2
Register Page 0 ................................................................................................... 42
Datasheet
CFR0011-120-00
Revision 1.4
3 of 62
08-May-2017
© 2017 Dialog Semiconductor
DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
8.2.3
8.2.4
9
8.2.2.1
System Control and Event ............................................................... 42
8.2.2.2
GPIO Control ................................................................................... 44
8.2.2.3
Regulators Control ........................................................................... 46
Register Page 1 ................................................................................................... 47
8.2.3.1
Regulators Settings ......................................................................... 47
Register Page 2 ................................................................................................... 52
8.2.4.1
Interface and OTP Settings (shared with DA9063) ......................... 52
8.2.4.2
OTP Fusing Registers ..................................................................... 53
8.2.4.3
Application Configuration Settings ................................................... 54
Application Information .............................................................................................................. 57
9.1 Capacitor Selection ............................................................................................................. 57
9.2 Inductor Selection ............................................................................................................... 58
10 Package Information ................................................................................................................... 59
10.1 Package Outlines ................................................................................................................ 59
11 Ordering Information .................................................................................................................. 60
Revision History ................................................................................................................................ 61
Datasheet
CFR0011-120-00
Revision 1.4
4 of 62
08-May-2017
© 2017 Dialog Semiconductor
DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
Figures
Figure 1: DA9213-A System Diagram ................................................................................................... 2
Figure 2: DA9214-A System Diagram ................................................................................................... 2
Figure 3: Connection Diagram .............................................................................................................. 7
Figure 4: 66 VFBGA Power Derating Curve........................................................................................ 11
Figure 5: 2-WIRE Bus Timing .............................................................................................................. 16
Figure 6: 4-WIRE Bus Timing .............................................................................................................. 17
Figure 7: DA9213-A Efficiency vs Load, VOUT = 1.0 V, 0-20 A ......................................................... 18
Figure 8: DA9213-A Efficiency vs Load, VIN = 3.6 V, 0-20 A ............................................................. 18
Figure 9: DA9214-A Efficiency vs Load, VOUT = 1.0 V, 0-10 A ......................................................... 19
Figure 10: DA9214-A Efficiency vs Load, VIN = 3.6 V, 0-10 A ........................................................... 19
Figure 11: Interface of DA9213-A/14-A with DA9063 and the Host Processor................................... 20
Figure 12: Typical Application of DA9213-A........................................................................................ 21
Figure 13: Typical Application of DA9214-A........................................................................................ 22
Figure 14: Concept of Control of the Buck’s Output Voltage .............................................................. 25
Figure 15: Resistive Divider from VOUT to FBAN .............................................................................. 26
Figure 16: GPIO Principle of Operation (example paths) .................................................................... 29
Figure 17: Schematic of 4-WIRE and 2-WIRE Power Manager Bus .................................................. 31
Figure 18: 4-WIRE Host Write and Read Timing (nCS_POL = ‘0’, CPOL = ‘0’, CPHA = ‘0’) ............. 32
Figure 19: 4-WIRE Host Write and Read Timing (nCS_POL= ‘0’, CPOL = ‘0’, CPHA = ‘1’) .............. 33
Figure 20: 4-WIRE Host Write and Read Timing (nCS_POL = ‘0’, CPOL = ‘1’, CPHA = ‘0’) ............. 33
Figure 21: 4-WIRE Host Write and Read Timing (nCS_POL = ‘0’, CPOL = ‘1’, CPHA = ‘1’) ............. 34
Figure 22: Timing of 2-WIRE START and STOP Condition ................................................................ 36
Figure 23: 2-WIRE Byte Write (SDA Line) .......................................................................................... 37
Figure 24: Examples of 2-WIRE Byte Read (SDA Line) ..................................................................... 37
Figure 25: Examples of 2-WIRE Page Read (SDA Line) .................................................................... 37
Figure 26: 2-WIRE Page Write (SDA Line) ......................................................................................... 38
Figure 27: 2-WIRE Repeated Write (SDA Line) .................................................................................. 38
Figure 28: DA9213-A/14-A VFBGA Package Outline Drawing ........................................................... 59
Tables
Table 1: Pin Description ........................................................................................................................ 8
Table 2: Pin Type Definition .................................................................................................................. 9
Table 3: Absolute Maximum Ratings ................................................................................................... 10
Table 4: Recommended Operating Conditions ................................................................................... 10
Table 5: Buck Converters Characteristics ........................................................................................... 11
Table 6: IC Performance and Supervision .......................................................................................... 14
Table 7: Digital I/O Characteristics ...................................................................................................... 14
Table 8: 2-WIRE Control Bus Characteristics ..................................................................................... 15
Table 9: 4-WIRE Control Bus Characteristics ..................................................................................... 17
Table 10: 4-WIRE Clock Configurations .............................................................................................. 31
Table 11: 4-WIRE Interface Summary ................................................................................................ 35
Table 12: Over-Temperature Thresholds ............................................................................................ 39
Table 13: Register Map ....................................................................................................................... 41
Table 14: Recommended Capacitor Types ......................................................................................... 57
Table 15: Recommended Inductor Types ........................................................................................... 58
Table 16: Ordering Information ........................................................................................................... 60
Datasheet
CFR0011-120-00
Revision 1.4
5 of 62
08-May-2017
© 2017 Dialog Semiconductor
DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
1
Terms and Definitions
AP
CPU
DDR
DVC
FET
GPI
GPU
IC
OTP
PCB
PMIC
POL
PWM
Datasheet
CFR0011-120-00
Application Processor
Central Processing Unit
Dual Data Rate
Dynamic Voltage Control
Field Effect Transistor
General Purpose Input
Graphic Processing Unit
Integrated Circuit
One Time Programmable memory
Printed Circuit Board
Power Management Integrated Circuit
Point Of Load
Pulse Width Modulation
Revision 1.4
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© 2017 Dialog Semiconductor
Datasheet
CFR0011-120-00
1
2
VDD_A2
2
VSS_A2
LX_A2
VDD_A2
1
D
E
Revision 1.4
7 of 62
F
LX_A2
VSS_A2
VSS_A1
VSS_A1
LX_A1
VDD_A1
C
LX_A1
VDD_A1
3
3
VDD_A2
LX_A2
VSS_A2
VSS_A1
LX_A1
VDD_A1
4
4
VDD_A2
LX_A2
VSS_A2
VSS_A1
LX_A1
VDD_A1
5
nIRQ
VSS
FBAN
FBAP
NC
7
6
VSYS
7
IC_EN
VDDIO
FBBN/
NC
nCS/
GPI4
VSS_ANA
FBBP/
NC
GPI1
GPI0/
TRK
SO/
GPIO3
GPIO2
6
SCL/
SK
5
SDA/
SI
8
8
VDD_B2
LX_B2
VSS_B2
VSS_B1
LX_B1
VDD_B1
9
9
VDD_B2
LX_B2
VSS_B2
VSS_B1
LX_B1
VDD_B1
10
10
VDD_B2
LX_B2
VSS_B2
VSS_B1
LX_B1
VDD_B1
11
11
VDD_B2
LX_B2
VSS_B2
VSS_B1
LX_B1
VDD_B1
F
E
D
C
B
A
66 balls
Sensitive Analog
Signals
Quasi Static
Digital Signals
Noisy Digital
Signals
Power Signals
High Power Noisy
Signals
High Power
Signals
see balls through package
DA9213/14
2
B
A
DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
Pinout
Figure 3: Connection Diagram
08-May-2017
© 2017 Dialog Semiconductor
DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
Table 1: Pin Description
Pin Name
Signal Name
Second
Function
Type
Description
(See
Table 2)
B1, B2, B3, B4
LX_A1
AO
Switching node for Buck A phase 1
E1, E2, E3, E4
LX_A2
AO
Switching node for Buck A phase 2
B8, B9, B10, B11
LX_B1
AO
Switching node for Buck B phase 1
E8, E9, E10, E11
LX_B2
AO
Switching node for Buck B phase 2
A1, A2, A3, A4
VDD_A1
PS
Supply voltage for Buck A phase 1
To be connected to VSYS
F1, F2, F3, F4
VDD_A2
PS
Supply voltage for Buck A phase 2
To be connected to VSYS
A8, A9, A10, A11
VDD_B1
PS
Supply voltage for Buck B phase 1
To be connected to VSYS
F8, F9, F10, F11
VDD_B2
PS
Supply voltage for Buck B phase 2
To be connected to VSYS
F7
IC_EN
DI
Integrated Circuit (IC) Enable Signal
F5
nIRQ
DO
Interrupt line towards the host
E7
VDDIO
PS
I/O Voltage Rail
C5
FBAP
AI
Positive sense node for the Buck A
D5
FBAN
AI
Negative sense node for the Buck A
C7
FBBP
AI
Positive sense node for the Buck B for
DA9214-A
NC
AO
Do not connect for DA9213-A
FBBN
AI
Negative sense node for the Buck B for
DA9214-A
NC
AO
Do not connect for DA9213-A
DI/AI
General purpose input, input track
D7
A7
GPI0
B7
GPI1
DI
General purpose input
B6
GPIO2
DIO
General purpose input/output
A5
SDA
SI
DIO
2-WIRE data, 4-WIRE data input/output
A6
SCL
SK
DI
2-WIRE clock, 4-WIRE clock
D6
nCS
GPI4
DI
4-WIRE chip select, general purpose input
C6
SO
GPIO3
DIO
4-WIRE data output, general purpose
input/output
B5
VDDCORE
AO
Regulated supply for internal circuitry.
Decouple with 150 nF (or 220 nF)
F6
VSYS
PS
Supply for IC and input for voltage
supervision
E5
VSS
VSS
E6
VSS_ANA
VSS
Datasheet
CFR0011-120-00
TRK
Revision 1.4
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08-May-2017
© 2017 Dialog Semiconductor
DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
Pin Name
Signal Name
C1, C2, C3, C4,
VSS_A1,
D1, D2, D3, D4,
C8, C9, C10, C11,
VSS_A2
VSS_B1
D8, D9, D10, D11
VSS_B2
Second
Function
Type
Description
(See
Table 2)
VSS
Connect together
Table 2: Pin Type Definition
Pin Type
Description
Pin Type
Description
DI
Digital Input
AI
Analogue Input
DO
Digital Output
AO
Analogue Output
DIO
Digital Input/Output
AIO
Analogue Input/Output
PS
Power Supply
VSS
Ground
Datasheet
CFR0011-120-00
Revision 1.4
9 of 62
08-May-2017
© 2017 Dialog Semiconductor
DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
3
Absolute Maximum Ratings
Table 3: Absolute Maximum Ratings
Parameter
Description
TSTG
Storage temperature
-65
+150
°C
TA_LIM
Limiting ambient
temperature
-40
+105
°C
Tj_MAX
Maximum junction
temperature
+150
°C
VDD_LIM
Limiting supply voltage
-0.3
5.5
V
VPIN
Limiting voltage at all
pins except above
-0.3
VDD + 0.3
(max 5.5)
V
VESD_HBM
Electrostatic discharge
voltage
2
kV
Note 1
4
Conditions (Note 1)
Min
Typ
Max
Human Body Model
Unit
Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the
device. These are stress ratings only, so functional operation of the device at these or any other
conditions beyond those indicated in the operational sections of the specification are not implied.
Exposure to absolute maximum rating conditions for extended periods may affect device reliability.
Recommended Operating Conditions
Table 4: Recommended Operating Conditions
Parameter
Description
VDD
Supply voltage
Tj_OP
Operating Junction
Temperature
VDDIO
Input/output supply
voltage
PTOT
Total power dissipation
(Note 3)
JA
Thermal resistance
junction to ambient
(Note 3)
Conditions (Note 1)
Min
Typ
2.8
1.2
Derating factor above
TA = 70 °C: 34.8 mW/°C
Max
Unit
5.5
V
125
°C
3.6
(Note 2)
V
1920
mW
28.7
°C/W
Note 1
Within the specified limits, a life time of 10 years is guaranteed
Note 2
VDDIO is not allowed to be higher than VDD
Note 3
Obtained from simulation on a 2S2P 4L JEDEC Board (EIA/JESD51-2). Influenced by PCB technology
and layout.
Datasheet
CFR0011-120-00
Revision 1.4
10 of 62
08-May-2017
© 2017 Dialog Semiconductor
DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
4.5
PD = (TJ - TA) / θJA
θJA = 28.7 °C/W
Still air (0 m/s)
▲TJ(WARN) = 125 °C
TJ(CRIT) = 140 °C
4.0
3.5
PD (W)
3.0
2.5
2.0
1.5
1.0
0.5
0.0
20
30
40
50
60
70
80
90
100
110
120
130
140
TA (°C)
Figure 4: 66 VFBGA Power Derating Curve
5
Electrical Characteristics
Table 5: Buck Converters Characteristics
Parameter
Description
Conditions
VDD
Supply voltage
VDD_x = VSYS
2.8
5.5
V
VBUCK
Buck output voltage (Note 1)
IO = 0 to IO_MAX
0.3
1.57
V
VOACC
Output voltage accuracy
Incl. static line/load reg
and voltage ripple
VBUCK ≥ 1 V
-2.0
+2.0
%
PWM mode
Min
Incl. static line/load reg
and voltage ripple
Typ
Max
±20
Unit
mV
VBUCK < 1 V
VBUCK = 1 V
-1.0
+1.0
%
-0.5
+0.5
%
VDD = 3.8 V
no load
VBUCK = 1 V
VDD = 3.8 V
no load
TA = 27 ºC
Datasheet
CFR0011-120-00
Revision 1.4
11 of 62
08-May-2017
© 2017 Dialog Semiconductor
DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
Parameter
Description
Conditions
VTR_LOAD
Load regulation transient
voltage
(Note 2)
DA9213-A
Min
Typ
Max
IO = 0 to 5 A, tr = 500 ns
PWM 4-phase
Unit
%
VBUCK ≥ 1 V
VBUCK < 1 V
±2%
±20 mV
DA9213-A
IO = 0 to 5 A, tr = 500 ns
±3.5
%
±3.5
%
15
mV
auto mode, ph shedding
VBUCK = 1 V
Load regulation transient
voltage
DA9214-A
IO = 0 to 5 A, tr = 500 ns
(Note 2)
PWM 2-phase
VBUCK = 1 V
Line regulation transient
voltage
VDD = 3 to.3.6 V
IO_MAX
Maximum output current
Per phase
5000
ILIM_MIN
Minimum current limit
BUCKA_ILIM
-20%
4000
20%
mA
per phase (programmable)
(Note 3)
BUCKB_ILIM = 0000
Maximum current limit
BUCKA_ILIM
-20%
7000
20%
mA
per phase (programmable)
(Note 3)
BUCKB_ILIM
Quiescent current
@ synchronous rectification
mode
Per phase
No load
VTR_LINE
ILIM_MAX
IQ_PWM
fSW
Switching frequency
tSTUP
Start up time
dt =10 µs
IO = IO(MAX)/2
mA
= 1111
17
mA
3
MHz
50
(Note 4)
µs
VDD = 3.7 V
BUCKA_UP_CTRL
BUCKB_UP_CTRL
= 011
RO_PD
Output pull-down resistance
For each phase at the LX
node @0.5 V,
150
200
Ω
(see BUCKx_PD_DIS)
RON_PMOS
PMOS on-resistance
incl. pin and routing
27
mΩ
19
mΩ
VDD = 3.7 V
per phase
RON_NMOS
NMOS on-resistance
incl. pin and routing
VDD = 3.7 V
per phase
PFM Mode
VBUCK_PFM
Buck output voltage in PFM
Datasheet
CFR0011-120-00
IO = 0 mA to IO_MAX
Revision 1.4
12 of 62
0.3
1.57
V
08-May-2017
© 2017 Dialog Semiconductor
DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
Parameter
Description
Conditions
IMIN_PFM
Minimum output current in
PFM
Static output voltage,
no DVC
IQ_PFM_A2
DA9214-A quiescent current
No switching
Buck A enabled
VDD = 3.7 V
(Note 5)
DA9213-A quiescent current
Buck enabled
No switching
VDD = 3.7 V
IQ_PFM_A4
Min
Typ
2
Max
Unit
mA
58
µA
72
µA
106
µA
(Note 5)
IQ_PFM_A2B2
DA9214-A quiescent current
Buck A enabled
No switching
VDD = 3.7 V
(Note 5)
Buck B enabled
Note 1
Programmable in 10 mV increments.
Note 2
Additional to the dc accuracy. Inductor value 0.22 uH. The value is measured directly at COUT(EXT). In
case of remote sensing, parasitics of PCB and external components may affect this value.
Note 3
On-time > 50 ns.
Note 4
Time from begining to end of the voltage ramp. Additional 10 µs typical delay, plus internal sync to the
enable port.
Note 5
For the total quiescent current of the IC, the IDD_ON should be added.
Datasheet
CFR0011-120-00
Revision 1.4
13 of 62
08-May-2017
© 2017 Dialog Semiconductor
DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
Table 6: IC Performance and Supervision
Parameter
Description
Conditions
IDD_OFF
Off state supply current
IC_EN = 0
Min
Typ
0.1
Max
1
Unit
µA
TA = 27 °C
IDD_ON
On state supply current
IC_EN = 1
14
µA
-50
mV
Buck A/B off
TA = 27 °C
VTH_PG
Power good threshold
voltage
VHYS_PG
Power good hysteresis
voltage
50
mV
VTH_UVLO_V
Under voltage lockout
threshold @ VDD
2.0
V
DD
VTH_UVLO_IO
Under voltage lockout
threshold @ VDDIO
VHYS_UVLO_I
Under voltage lockout
hysteresis @ VDDIO
O
referred to VBUCK
1.315
1.45
1.55
70
V
mV
TTH_WARN
Thermal warning threshold
temperature
110
125
140
°C
TTH_CRIT
Thermal critical threshold
temperature
125
140
155
ºC
TTH_POR
Thermal power on reset
threshold temperature
135
150
165
°C
fOSC
Internal oscillator
frequency
-7%
6.0
+7%
MHz
Table 7: Digital I/O Characteristics
Parameter
Description
Conditions
Min
Typ
Max
VIH_EN
HIGH level input voltage
@ pin IC_EN
VIL_EN
LOW level input voltage
@ pin IC_EN
tEN
Enable time
I/F operating
750
µs
RO_PU_GPO
Pull up resistor @ GPO
VDDIO = 1.8 V
VGPO = 0 V
100
k
RI_PD_GPI
Pull down resistor @ GPI
VDDIO = 1.8 V
VGPI = VDDIO
150
k
VIH
GPI0-4, SCL, SDA,
(2-WIRE mode)
VLDOCORE mode
VDDIO mode
1.1
Unit
V
0.35
1.75
0.7*VDDIO
V
V
HIGH level input voltage
VIL
GPI0-4, SCL, SDA,
(2-WIRE mode)
VLDOCORE mode
VDDIO mode
0.75
0.3*VDDIO
V
LOW level input voltage
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DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
Parameter
Description
VIH_4WIRE
SK, nCS, SI
Conditions
Min
Typ
Max
0.7*VDDIO
Unit
V
(4-WIRE Mode)
HIGH level input voltage
VIL_4WIRE
SK, nCS, SI
(4-WIRE Mode)
0.3*VDDIO
V
LOW level input voltage
VOH
VOL1
GPO2-3, SO (4-WIRE
mode)
HIGH level output voltage
push-pull mode
0.8*VDDIO
V
@1mA
VDDIO ≥ 1.5 V
GPO2-3, SDA (2-WIRE
mode) SO (4-WIRE
mode)
0.3
V
LOW level output voltage
@IOL = 1 mA
VOL3
SDA (2-WIRE Mode)
LOW level output voltage
@IOL = 3 mA
0.24
V
VOL20
SDA (2-WIRE Mode)
0.4
V
10
pF
LOW level output voltage
@IOL = 20 mA
CIN
CLK, SDA
2.5
(2-WIRE Mode)
input capacitance
tSP
CLK, SDA
(2-WIRE Mode)
Fast/Fast+ mode
High Speed mode
0
0
50
10
ns
Fast @ Cb<550pF
HS @ 10<Cb<100pF
20+0.1Cb
10
120
80
ns
HS @ Cb<400pF
20
160
spike suppression pulse
width
tfDA
Fall time of SDA signal
(2-WIRE Mode)
Table 8: 2-WIRE Control Bus Characteristics
Parameter
Description
tBUF
Bus free time from STOP
to START condition
CB
Bus line capacitive load
Conditions
Min
Typ
Max
0.5
Unit
µs
150
pF
1000
kHz
Standard/Fast/Fast+ Mode
fSCL
Clock frequency @ pin
SCL
0
(Note 1)
tSU_STA
START condition set-up
time
0.26
µs
tH_STA
START condition hold
time
0.26
µs
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DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
Parameter
Description
Conditions
Min
Typ
Max
Unit
tW_CL
Clock LOW duration
0.5
µs
tW_CH
Clock HIGH duration
0.26
µs
tR
Rise time
Input requirement
1000
ns
Input requirement
300
ns
@ pin CLK and DATA
tF
Fall time
@ pin CLK and DATA
tSU_D
Data set-up time
50
ns
tH_D
Data hold time
0
ns
High Speed Mode
fSCL_HS
Clock frequency @ pin
SCL
0
(Note 1)
tSU_STA_HS
START condition set-up
time
160
ns
tH_STA_HS
START condition hold
time
160
ns
tW_CL_HS
Clock LOW duration
160
ns
tW_CH_HS
Clock HIGH duration
60
ns
tR_HS
Rise time
@ pin CLK and DATA
Input requirement
160
ns
tF_HS
Fall time
@ pin CLK and DATA
Input requirement
160
ns
tSU_D_HS
Data set-up time
10
ns
tH_D_HS
Data hold time
0
ns
tSU_STO_HS
STOP condition set-up
time
160
ns
Note 1
3400
kHz
Minimum clock frequency is 10 kHz if 2WIRE_TO is enabled
Figure 5: 2-WIRE Bus Timing
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DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
Table 9: 4-WIRE Control Bus Characteristics
Parameter
Description
Label in Plot
Min
Typ
Max
Unit
CB
Bus line capacitive load
100
pF
tC
Cycle time
1
70
ns
tSU_CS
Chip select setup time
2, from CS active to first
SK edge
20
ns
tH_CS
Chip select hold time
3, from last SK edge to
CS idle
20
ns
tW_CL
Clock LOW duration
4
0.4 x tC
ns
tW_CH
Clock HIGH duration
5
0.4 x tC
ns
tSU_SI
Data input setup time
6
10
ns
tH_SI
Data input hold time
7
10
ns
tV_SO
Data output valid time
8
tH_SO
Data output hold time
9
6
ns
tW_CS
Chip select HIGH
duration
10
20
ns
22
(2) tSU_CS
(3) tH_CS
ns
(10) tW_CS
70%
nCS
30%
(5) tW_CH
(4) tW_CL
(1) tC
70%
SK
30%
(6) tSU_SI (7) tH_SI
70%
SI
30%
(8) tV_SO
(9) tH_SO
70%
30%
SO
Figure 6: 4-WIRE Bus Timing
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DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
6
Efficiency Measurements
The efficiency measurements for DA9213-A and DA9214-A are shown with phase shedding enabled
in each plot.
Figure 7: DA9213-A Efficiency vs Load, VOUT = 1.0 V, 0-20 A
Figure 8: DA9213-A Efficiency vs Load, VIN = 3.6 V, 0-20 A
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DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
Figure 9: DA9214-A Efficiency vs Load, VOUT = 1.0 V, 0-10 A
Figure 10: DA9214-A Efficiency vs Load, VIN = 3.6 V, 0-10 A
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DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
7
Functional Description
Flexible configurability and the availability of different control schemes make both DA9213-A and
DA9214-A the ideal single/dual buck companion ICs to expand the existing capabilities of a master
PMIC such as DA9063.
Due to the advanced compatibility between both DA9213-A and DA9214-A and the DA9063, they
offer several advantages when they are operated together. These advantages include:
● DA9213-A and DA9214-A can be enabled and controlled by DA9063 during the power up
sequence, thanks to DA9063’s dedicated output signals during power-up, and compatible input
controls in bothDA9213-A and DA9214-A.
● DA9213-A and DA9214-A can be used in a completely transparent way for the host processor
2
and can share the same Control Interface (same SPI chip select or I C address), thanks to the
compatible registers map. DA9213-A and DA9214-A has a dedicated register space for
configuration and control which doesn’t conflict with DA9063.
● DA9213-A and DA9214-A supports a power-good configurable port for enhanced communication
to the host processor and improved power-up sequencing.
● DA9213-A and DA9214-A can both share the same interrupt line with DA9063.
In addition, the 2-WIRE / 4-WIRE interfaces allow DA9213-A and DA9214-A to fit to many standard
PMU parts and power applications.
Vdd
nIRQ
nSHUTDOWN
SYS_EN
nOFF
PWR_EN
nONKEY
DA9063
Host
Processor
PWR1_EN
LID
OUT_32K
GPIOs
nRESET
Control IF
VCharger
GPIO9
IC_EN
DA9213-A/
DA9214-A
Control IF
nIRQ
GPI1 (voltage set)
GPI0 (enable)
Figure 11: Interface of DA9213-A/14-A with DA9063 and the Host Processor
As shown in Figure 11, a typical application case includes a host processor, a main PMIC (for
example, DA9063) and DA9213-A or DA9214-A used as companion IC for the high power core
supply.
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DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
The easiest way of controlling DA9213-A and DA9214-A is through the Control Interface. The master
initiating the communication must always be the host processor that reads and writes to the main
PMIC, and to the DA9213-A and DA9214-A registers. To poll the status of DA9213-A or DA9214-A,
the host processor must access the dedicated register area through the Control Interface. DA9213-A
and DA9214-A can additionally be controlled by means of hardware inputs.
CORE
VDDIO
DA9213-A
SCL
SDA
nIRQ
VSEL (GPI1)
EN (GPI0)
LP_MODE
DA9063
(PMIC)
VIN
VDD_A1
IC_EN
GPIO9 (seq)
VDD_A2
VDD_B1
VDD_B2
SENSE+
LX_A1
LX_A2
CPU /
GPU /
DDR
VSYS
LX_B1
VSS_ANA
LX_B2
SENSEFBAP
FBAN
VDDIO
I2C_ADDR_SEL (GPI4)
Power Good (GPIO3)
Ext Supply
Figure 12: Typical Application of DA9213-A
Figure 12 shows a typical use case of DA9213-A for the supply of CPU, GPU, or DDR rails. The IC is
enabled and disabled by the main PMIC via IC_EN port as part of its sequencer. Once the IC is
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DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
enabled, the CORE application processor enables the buck converter with the EN1 signal and
manages the output voltage selection with the VSEL signal.
The VSEL signal can be shared between the main PMIC and the DA9213-A. Three GPI/GPIOs
embedded in DA9213-A are used in this case:
● GPIO2 signals the insertion of an external charger in the application (through interrupt to the host
processor)
● GPIO3 indicates a power-good-condition, either to proceed with the power up sequence or to
enable an external supply connected to the port
● GPI4 is used for the I2C interface address hardware selection
DA9214-A
CORE
VDDIO
SCL
SDA
nIRQ
EN_A (GPI0)
EN_B (GPI1)
VIN
VDD_A1
VDD_A2
VDD_B1
SENSE+
CPU/
GPU
SENSE+
DDR
LX_A1
VDD_B2
LX_A2
SENSEVSYS
FBAP
FBAN
VSS_ANA
LX_B1
LX_B2
(LX_A3 in DA9215)
SENSEFBBP
FBBN
VDDIO
I2C_ADDR_SEL (GPI4)
VSYS
IC_EN
Figure 13: Typical Application of DA9214-A
Figure 13 shows a typical use case of DA9214-A for the simultaneous supply of a CPU and a GPU
rail. The IC is always enabled because IC_EN is shorted to the battery voltage. The CORE
application processor enables and disables the CPU/GPU and the DDR individually via dedicated
ports on DA9214-A.
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DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
7.1
DC-DC Buck Converter
DA9213-A is a four-phase 20 A high efficiency synchronous step-down DVC regulator, operating at a
high frequency of typically 3 MHz. It supplies an output voltage of typically 1.0 V for a CPU rail,
configurable in the range 0.3 – 1.57 V, with high accuracy in steps of 10 mV.
DA9214-A contains two buck converters, Buck A and Buck B, each capable of delivering 10 A.
To improve the accuracy of the delivered voltage, each buck converter is able to support a differential
nsing of the configured voltage directly at the point of load via dedicated positive and negative sense
pins.
Both Buck A and Buck B have two voltage registers each. One defines the normal output voltage,
while the other offers an alternative retention voltage. In this way different application power modes
can easily be supported. The voltage selection can be operated either via GPI or via control interface
to guarantee the maximum flexibility according to the specific host processor status in the
application.
When a buck is enabled, its output voltage is monitored and a power-good signal indicates that the
buck output voltage has reached a level higher than the VTH(PG) threshold. The power-good is lost
when the voltage drops below VTH(PG) - VHYS(PG), which is the level at which the signal is deasserted. The power good signalling should not be used in conjunction with fast start up rates,
configured in BUCKx_UP_CTRL register fields and can be individually masked during DVC
transitions using the PGA_DVC_MASK and PGB_DVC_MASK bits. For each of the buck converters
2
the status of the power-good indicator can be read back via I C from the PWRGOOD_A and
PWRGOOD_B status bits. It can be also individually assigned to either GPIO2 or GPIO3 using
BUCKA_PG_SEL and BUCKB_PG_SEL. For correct functionality, the GPIO ports need to be
2
configured as output. An I C write in GPIOx_MODE can overwrite the internal configuration so that a
new update will be automatically done only when the internal power-good indicator changes status.
The buck converters are capable of supporting DVC transitions that occur:
● When the active and selected A-voltage or B-voltage is updated to a new target value.
● When the voltage selection is changed from the A-voltage to the B-voltage (or B-voltage to the
A-voltage) using VBUCKA_SEL and VBUCKB_SEL.
The DVC controller operates in Pulse Width Modulation (PWM) mode with synchronous rectification.
When the host processor changes the output voltage, the voltage transition of each buck converter
can be individually signalled with a READY signal routed to either GPIO2 or GPIO3. The port has to
be configured as GPO and selected for the functionality via READYA_CONF or READYB_CONF. In
contrast to the power-good signal, the READY only informs the host processor about the completion
of the digital DVC ramp without confirming that the target voltage has actually been reached.
The slew rate of the DVC transition is individually programmed for each buck converter at 10mV per
(4, 2, 1 or 0.5 µs) via control bit SLEW_RATE_A and SLEW_RATE_B.
The typical supply current is in the order of 8 mA per phase (quiescent current and charge/discharge
current) and drops to <1 µA when the buck is turned off.
When the buck is disabled, a pull-down resistor (typically 150 Ω) for each phase is activated
depending of the value stored in register bits BUCKA_PD_DIS and BUCKB_PD_DIS. Phases
disabled using PHASE_SEL_A and PHASE_SEL_B will not have any pull-down. The pull-down
resistor is always disabled at all phases when DA9213-A and DA9214-A are OFF.
Datasheet
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DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
7.1.1
Switching Frequency
The switching frequency is chosen to be high enough to allow the use of a small 0.22 µH inductor
(see a complete list of coils in the Application Information, Section 9). The buck switching frequency
can be tuned using register bit OSC_TUNE. The internal 6 MHz oscillator frequency is tuned in steps
of 180 kHz. This impacts the buck converter frequency in steps of 90 kHz and helps to mitigate
possible disturbances to other HF systems in the application.
7.1.2
Operation Modes and Phase Selection
The buck converters can operate in synchronous PWM mode and PFM mode. The operating mode is
selected using register bits BUCKA_MODE and BUCKB_MODE.
An automatic phase shedding can be enabled for each buck converter in PWM mode via
EF _Ref370828148 \h \* MERGEFORMAT PH_SH_EN_A, PH_SH_EN_B, thereby automatically
reducing or increasing the number of active phases depending on the output load current. For
DA9214-A the phase shedding will automatically change between 1-phase and 2-phase operation at
a typical current of 2.0 A. For DA9213-A the phase shedding will automatically change between 1phase and 4-phase operation at a typical current of 2.5 A. The PHASE_SEL_A and PHASE_SEL_B
register fields limit the maximum number of active phases under any conditions.
If the automatic operation mode is selected on BUCKA_MODE or BUCKB_MODE, the buck
converters will automatically change between synchronous PWM mode and PFM depending on the
load current. This improves the efficiency of the converters across the whole range of output load
currents.
7.1.3
Output Voltage Selection
The switching converter can be configured using either a 2-WIRE or a 4-WIRE interface. For security
reasons, the re-programming of registers that can cause damage when wrongly programmed (for
example, the voltage settings) can be disabled by asserting the control V_LOCK. When V_LOCK is
asserted, reprogramming the registers 0xD0 to 0x14F from control interfaces is disabled.
For each buck converter two output voltages can be pre-configured inside registers VBUCKA_A and
VBUCKB_A, and registers VBUCKA_B and VBUCKB_B. The output voltage can be selected by
either toggling register bits VBUCKA_SEL and VBUCKB_SEL or by re-programming the selected
voltage control register. Both changes will result into ramped voltage transitions, during which the
READY signal is asserted. After being enabled, the buck converter will by default use the register
settings in VBUCKA_A and VBUCKB_A unless the output voltage selection is configured via the GPI
port.
If “00” has been selected in BUCKA_MODE or BUCKB_MODE, A-/B- voltage selection registers
VBUCKx_x control the operation of the PWM and PFM modes.
Regardless of the values programmed in the VBUCKx_A and VBUCKx_B registers, the registers
VBUCKA_MAX, VBUCKB_MAX will individually limit the output voltage that can be set for each of
the buck converters.
The buck converter provides an optional hardware enable/disable via selectable GPI, and configured
via control register bits BUCKA_GPI and BUCKB_GPI. A change of the output voltage from the state
of a GPI is enabled via control register bits VBUCKA_GPI and VBUCKB_GPI. After detecting a rising
or falling edge at the related GPIs, DA9213-A and DA9214-A will configure the buck converters
according to their status.
In addition to selecting between the A/B voltages, a track mode can be activated for Buck A to set the
output voltage. In the DA9213-A, the track mode is applied to the 4-phase buck converter. This
feature can be enabled on GPI0 via GPI0_PIN. The output voltage will be configured to follow the
value applied at a selected GPI pin. The voltage applied at GPI0 must be in the same range as the
Datasheet
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DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
nominal output voltage selectable for the buck rail (see VBUCKA_A and VBUCKA_B registers). In
Track Mode, only single ended remote sensing is possible.
In Track Mode, the content of the VBUCKA_SEL bit is ignored, as well as VBUCKA_A and
VBUCKA_B bits. They will become active again once the voltage track mode is disabled. The GPI0
does not generate any event in this case.
Figure 14: Concept of Control of the Buck’s Output Voltage
7.1.4
Soft Start Up
To limit in-rush current from VSYS, the buck converters can perform a soft-start after being enabled.
The start-up behavior is a compromise between acceptable inrush current from the battery and
turn-on time. In DA9213-A and DA9214-A different ramp times can be individually configured for
each buck converter on register BUCKA_UP_CTRL and BUCKB_UP_CTRL. Rates higher than 20
mV/µs may produce overshoot during the start-up phase, so they should be considered carefully.
A ramped power-down can be selected on register bits BUCKA_DOWN_CTRL and
BUCKB_DOWN_CTRL. When no ramp is selected, the output node will be discharged only by the
pull-down resistor, if enabled via BUCKA_PD_DIS and BUCKB_PD_DIS.
7.1.5
Current Limit
The integrated current limit is meant to protect DA9213-A and DA9214-A power stages and the
external coil from excessive current. The bucks’ current limit should be configured to be at least 40%
higher than the required maximum continuous output current (see table below).
When reaching the current limit, each buck converter generates an event and an interrupt to the host
processor unless the interrupt has been masked using the OCx_MASK controls. These OCA_MASK
and OCB_MASK control bits can be used to mask the generation of over-current events during DVC
transitions. An extra masking time as defined in OCx_MASK will be automatically added to the DVC
interval after the DVC has finished in order to ensure that the possible high current levels needed for
DVC do not influence the event generation.
7.1.6
Variable VOUT above 1.57 V
The whole product family is also available with an adjustable output voltage up to 4.3V. A resistive
divider from VOUT to FBAN (or FBBN) can be used to set the output voltage higher than 1.57 V, see
Figure 15. The specific variant DA921_S is optimized for variable output voltage and the VREF on
FBAN (or FBBN) is set to 1.2 V.
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DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
The value of the output voltage VOUT is set by the selection of the resistive divider shown in
equation 1. The total resistance of the divider resistors (R1+R2) should be less than 40 k.
𝑉𝑂𝑈𝑇 = (1 +
𝑅1
) ∙ 𝑉𝑅𝐸𝐹
𝑅2
Equation 1
VOUT
R1
FBAP
R2
FBAN
Figure 15: Resistive Divider from VOUT to FBAN
For example, to program the output voltage VOUT to 1.8 V, suggest 10 kΩ on R1 and 20 kΩ on R2.
Note 1
The resistors need to be properly selected since the output voltage accuracy will be directly affected
by any errors on the resistors. The voltage across FBAP and FBAN (VREF) is guaranteed, but not the
output voltage accuracy.
CAUTION
The followings are important notes that need to be considered before using resistive divider on DA9213-A and
DA9214-A:
1.
Please contact your region's Dialog representative when adopting the resistive divider technique. Dialog
need to prepare a special OTP because incorrect OTP settings may result in a different output voltage than
expected.
2.
The voltage difference between input voltage and output voltage needs to be:
above 1.2 V, VIN-VOUT > 1.2 V.
3.
4.
The total resistance (R1+R2) is less than 40 k.
It is recommended that the device is operated in PWM mode only.
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DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
7.2
Ports Description
This section describes the functionality of each input / output port.
7.2.1
VDDIO
VDDIO is an independent IO supply rail input to DA9213-A and DA9214-A that can be assigned to
the power manager interface and to the GPIOs (see control PM_IF_V and GPI_V). The rail
assignment determines the IO voltage levels and logical thresholds (see also the Digital I/O
Characteristics in Table 7).
2
An integrated under voltage lockout circuit for the VDDIO prevents internal errors by disabling the I C
communication when the voltage drops below VULO_IO. In that case the buck converters are also
disabled and cannot be re-enabled (even via input port) until the VDDIO under-voltage condition has
been resolved. At the exit of the VDDIO under voltage condition an event E_UVLO_IO is generated
and the nIRQ line is driven active if the event is not masked.
The VDDIO under-voltage circuit monitors voltages relative to a nominal voltage of 1.8V. If a different
rail voltage is being used, the under-voltage circuit can be disabled via UVLO_IO_DIS.
Note that the maximum speed at 4-WIRE interface is only available if the selected supply rail is
greater than 1.6 V.
7.2.2
IC_EN
IC_EN is a general enable signal for DA9213-A and DA9214-A turning on and off the internal circuitry
(for example, the reference, the digital core, etc.). Correct control of this port has a direct impact on
the quiescent current of the whole application. A low level of IC_EN allows the device to reach the
minimum quiescent current. The voltage at this pin is continuously sensed by a dedicated analogue
circuit.
The host processor will be allowed to start the communication with DA9213-A and DA9214-A through
the Control Interface and, for example to turn on the buck converters, a delay time of t EN after
assertion of the IC_EN pin. If the bucks are enabled via OTP (see BUCKA_EN and BUCKB_EN
controls), they will start up automatically after assertion of IC_EN.
The IC_EN activation threshold is defined with a built in hysteresis to avoid glitching transitions that
take place with unstable rising or falling edges.
7.2.3
nIRQ
The nIRQ port indicates that an interrupt-causing event has occurred and that the event/status
information is available in the related registers. The nIRQ is an output signal that can either be
push-pull or open drain (selected via IRQ_TYPE). If an active high IRQ signal is required, it can be
achieved by asserting control IRQ_LEVEL (recommended for push-pull mode).
Examples of this type of information can be critical temperature and voltage, fault conditions, status
changes at GPI ports, and so forth. The event registers hold information about the events that have
occurred. Events are triggered by a status change at the monitored signals. When an event bit is set,
the nIRQ signal is asserted unless this interrupt is masked by a bit in the IRQ mask register. The
nIRQ will not be released until all event registers with asserted bits have been read and cleared. New
events that occur during reading an event register are held until the event register has been cleared,
ensuring that the host processor does not miss them.
7.2.4
GPIO Extender
DA9213-A and DA9214-A includes a GPIO extender that offers up to five 5 V-tolerant general
purpose input/output ports. Each port is controlled via registers from the host processor.
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The GPIO3 and GPI4 ports are pin-shared with the 4-WIRE Control Interface. For instance, if
GPIO3_PIN = 01, GPI4_PIN = 01 (Interface selected), the GPIO3 and GPI4 ports will be exclusively
dedicated to output and chip-select signaling for 4-WIRE purposes. If the alternative function is
selected, all GPIOs configuration as per registers 0x58 to 0x5A and 0x145 will be ignored.
GPIs are supplied from the internal rail VDDCORE or VDDIO (selected via GPI_V) and can be
configured to be active high or active low (selected via GPIOx_TYPE). The input signals can be
debounced or directly change the state of the assigned status register GPIx to high or low, according
to the setting of GPIOx_MODE. The debouncing time is configurable via control DEBOUNCE (10 ms
default).
Whenever the status has changed to its configured active state (edge sensitive), the assigned event
register is set and the nIRQ signal is asserted (unless this nIRQ is masked, see also Figure 16).
Whenever DA9213-A and DA9214-A is enabled and enters ON mode (also when enabled changing
the setting of GPIOx_PIN) the GPI status bits are initiated towards their configured passive state.
This ensures that already active signals are detected, and that they create an event immediately after
the GPI comparators are enabled.
The buck enable signal (BUCKx_EN) can be controlled directly via a GPI, if so configured in the
BUCKA_GPI and BUCKB_GPI registers. If it is required that GPI ports do not generate an event
when configured for the HW control of the switching regulator, the relative mask bit should be set.
GPIs can alternatively be selected to toggle the VBUCKA_SEL and VBUCKB_SEL from rising and
falling edges at these inputs. Apart from changing the regulator output voltage this also provides
hardware control of the regulator mode (normal/low power mode) from the settings of BUCKA_SL_A,
BUCKA_SL_B, BUCKB_SL_A, and BUCKB_SL_B (enabled if BUCKA_MODE or BUCKB_MODE =
‘00’).
All GPI ports have the additional option of activating a 100 kΩ pull-down resistor via GPIOx_PUPD,
which ensures a well-defined level in case the input is not actively driven.
2
If enabled via ADDR_SEL_CONF, the I C address selection can be assigned to a specific GPI. An
active voltage level at the selected GPI configures the slave address of DA9213-A and DA9214-A to
IF_BASE_ADDR1 while a passive voltage level configures the slave address to IF_BASE_ADDR2. If
no GPI is selected then the IF_BASE_ADDR1 is automatically used.
If defined as an output, GPIOs can be configured to be open-drain or push-pull. If configured as
push-pull, the supply rail is VDDIO. By disabling the internal 120 kΩ pull-up resistor in open-drain
mode, the GPO can also be supplied from an external rail. The output state will be assigned as
configured by the GPIO register bit GPIOx_MODE.
A specific power-good port for each of the buck converters can be configured via BUCKA_PG_SEL
and BUCKB_PG_SEL. The respective port must be configured as GPO for correct operation. If
assigned to the same GPO, it is necessary that the power-good indicators for Buck A and Buck B are
both active (supply voltages in range) to assert the overall power-good. The signal will be released
as soon as one of the single power-good signals is not active (that is, at least one supply is out of
range).
The power good signalling should not be used in conjunction with fast start up rates, configured in
BUCKx_UP_CTRL register fields.
Once enabled via RELOAD_FUNC_EN the GPIO0 can be used as input port to operate a partial
OTP download. When the input level is changed to active, the registers 0x5D, 0x5E, 0xD1 to 0xDA
are updated to their OTP default. This allows a complete buck re-configuration that resets all the
changes done to those registers previously (soft reset). If the buck should be kept on during the soft
reset, the OTP values for the enable bits should be asserted because they are also part of the reload.
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DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
Whenever the GPIO unit is off (POR or OFF Mode) all ports are configured as open drain active high
(pass device switched off, high impedance state). When leaving POR the pull-up or pull-down
resistors will be configured from register GPIOx_PUPD.
Interrupt mask:
M_GPI0
Track Mode
Input
Reference
Buffer
GPIO0_TYPE:
Active high/low
Buck
GPI0_MODE:
Debounce on/off
Status register
Event register
Debounce
GPI
NOR
GPI0
GPIO0_PUPD
Reserved
E_GPI0
Rising or
Falling edge
GPI0_PIN
nIRQ
Reset
NOR
Reserved
Buck HW control
Event register write
100kΩ
Regulator
configure
...
BUCK_ EN
VBUCK_SEL
VDD_IO
Interrupt mask:
M_GPI3
4-WIRE
SO
GPIO3_TYPE:
Active high/low
Status register
GPIO3_MODE:
Debounce on/off
Event register
Interface
NOR
GPI3
GPI
E_GPI3
Rising or
Falling edge
Debounce
Reset
GPIO3_PIN
Event register write
GPIO3_PUPD
VDD_IO
GPIO3_PUPD
100kΩ
120kΩ
GPO (Open drain)
READY_EN
READY signal
asserted during
DVC
VDD_IO
GPO (Push-pull)
GPO3_MODE:
0 or 1
Figure 16: GPIO Principle of Operation (example paths)
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DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
7.3
7.3.1
Operating Modes
ON Mode
DA9213-A and DA9214-A are in ON Mode when the IC_EN port is higher than EN_ON and the
supply voltage is higher than VTH (UVLO)(VDD). Once enabled, the host processor can start the
communication with DA9213-A and DA9214-A via Control Interface after the tEN delay needed for
internal circuit start up.
If BUCKA_EN or BUCKB_EN is asserted when DA9213-A and DA9214-A are in ON Mode the power
up of the related buck converter is initiated. If the bucks are controlled via GPI, the level of the
controlling ports is checked when entering ON mode, so that an active level will immediately have
effect on the buck. If BUCKA_EN or BUCKB_EN are not asserted and all controlling GPI ports are
inactive, the buck converter will stay off with the output pull-down resistor enabled/disabled according
to the setting of BUCKA_PD_DIS and BUCKB_PD_DIS.
7.3.2
OFF Mode
DA9213-A and DA9214-A are in OFF Mode when the IC_EN port is lower than EN_OFF. In OFF
Mode, the bucks are always disabled and the output pull-down resistors are disabled independently
of BUCKA_PD_DIS and BUCKB_PD_DIS. All I/O ports of DA9213-A and DA9214-A are configured
as high impedance.
7.4
Control Interfaces
All the features of DA9213-A and DA9214-A can be controlled by SW through a serial control
2
interfaces. The communication is selectable to be either a 2-WIRE (I C compliant) or a 4-WIRE
connection (SPI compliant) via control IF_TYPE, which will be selected during the initial OTP read. If
4-WIRE is selected, the GPIO3 and GPI4 are automatically configured as interface pins. Data is
shifted into or out of DA9213-A and DA9214-A under the control of the host processor, which also
provides the serial clock. In a normal application case the interface is only configured once from OTP
values, which are loaded during the initial start-up of DA9213-A and DA9214-A.
DA9213-A and DA9214-A react only on read/write commands where the transmitted register address
(using the actual page bits as a MSB address range extensions) is within 0x50 to 0x67, 0xD0 to DF,
0x140 to 0x14F and (read only) 0x200 to 0x27F. Host access to registers outside these ranges will
be ignored. This means there will be no acknowledge after receiving the register address in 2-WIRE
Mode, and SO stays HI-Z in 4-WIRE Mode. During debug and production modes write access is
available to page 4 (0x200 to 0x27F). DA9213-A and DA9214-A react only on write commands
where the transmitted register address is 0x00, 0x80, 0x100 to0x106. The host processor must read
the content of those registers before writing, thereby changing only the bit fields that are not marked
as reserved (the content of the read back comes from the compatible PMIC, for example DA9063).
If the STAND_ALONE bit is asserted (OTP bit), DA9213-A and DA9214-A also react to read
commands.
7.4.1
4-WIRE Communication
In 4-WIRE Mode the interface uses a chip-select line (nCS/nSS), a clock line (SK), data input (SI)
and data output line (SO).
The DA9213-A and DA9214-A register map is split into four pages that each contain up to 128
registers. The register at address zero on each page is used as a page control register. The default
active page after turn-on includes registers 0x50 to 0x6F. Writing to the page control register
changes the active page for all subsequent read/write operations unless an automatic return to page
0 was selected by asserting bit REVERT. Unless the REVERT bit was asserted after modifying the
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DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
active page, it is recommended to read back the page control register to ensure that future data
exchange is accessing the intended registers.
All registers outside the DA9213-A and DA9214-A range are write only, that is, the DA9213-A and
DA9214-A will not answer to a read command and the data bus is tri-state (they are implicitly
directed to DA9063). In particular the information contained in registers 0x105 and 0x106 is used by
DA9213-A and DA9214-A to configure the control interface. They must be the same as the main
PMIC (DA9063), so that a write to those registers configures both the main PMIC and DA9213-A and
DA9214-A at the same time. The default OTP settings also need to be identical for a correct
operation of the system.
The 4-WIRE interface features a half-duplex operation, that is, data can be transmitted and received
within a single 16-bit frame at enhanced clock speed (up to 14 MHz). It operates at the clock
frequencies provided by the host.
VDDIO
VDDIO
VDDIO
SK
Host
SO
processor
SI
VDDIO
SK
PMIC
SI
(slave)
SO
nCS/nSS
nCS/nSS
nCS/nSS
Host
processor
VDDIO
SK
PMIC
Peripheral
SI
device
SCL
SDA
VDDIO
4-WIRE interface
2-WIRE interface
SK
SI Slave device
SO
nCS/nSS
SCL
SDA Peripheral
device
Figure 17: Schematic of 4-WIRE and 2-WIRE Power Manager Bus
A transmission begins when initiated by the host. Reading and writing is accomplished by the use of
an 8-bit command, which is sent by the host prior to the exchanged 8-bit data. The byte from the host
begins shifting in on the SI pin under the control of the serial clock SK provided from the host. The
first seven bits specify the register address (0x01 to 0x07) that will be written or read by the host. The
register address is automatically decoded after receiving the seventh address bit. The command
word ends with an R/W bit, which together with the control bit R/W_POL specifies the direction of the
following data exchange. During register writing the host continues sending out data during the
following eight SK clocks. For reading, the host stops transmitting and the 8-bit register is clocked out
of DA9213-A and DA9214-A during the consecutive eight SK clocks of the frame. Address and data
are transmitted with MSB first. The polarity (active state) of nCS is defined by control bit nCS_POL.
nCS resets the interface when inactive and it has to be released between successive cycles.
The SO output from DA9213-A and DA9214-A is normally in high-impedance state and active only
during the second half of read cycles. A pull-up or pull-down resistor may be needed at the SO line if
a floating logic signal can cause unintended current consumption inside other circuits.
Table 10: 4-WIRE Clock Configurations
Configurations
CPHA Clock
Polarity
CPOL Clock
Phase
Output Data is Updated at SK
Edge
Input Data is Registered at SK
Edge
0 (idle low)
0
Falling
Rising
0 (idle low)
1
Rising
Falling
1 (idle high)
0
Rising
Falling
1 (idle high)
1
Falling
Rising
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DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
DA9213-A and DA9214-A’s 4-WIRE interface offers two further configuration bits. Clock polarity
(CPOL) and clock phase (CPHA) define when the interface will latch the serial data bits. CPOL
determines whether SK idles high (CPOL = 1) or low (CPOL = 0). CPHA determines on which SK
edge data is shifted in and out. With CPOL = 0 and CPHA = 0, DA9213-A and DA9214-A latch data
on the SK rising edge. If the CPHA is set to 1 the data is latched on the SK falling edge. CPOL and
CPHA states allow four different combinations of clock polarity and phase. Each setting is
incompatible with the other three. The host and DA9213-A and DA9214-A must be set to the same
CPOL and CPHA states to communicate with each other.
4-WIRE WRITE
nCS
SK
SI
A6
A5
A4
A3
A2
A1
A0
R/Wn
D7
D6
D5
D4
D3
D2
D1
D0
D6
D5
D4
D3
D2
D1
D0
SO
4-WIRE READ
nCS
SK
SI
A6
SO
A5
A4
A3
A2
A1
A0
R/Wn
HI-Z
D7
latch data
Figure 18: 4-WIRE Host Write and Read Timing (nCS_POL = ‘0’, CPOL = ‘0’, CPHA = ‘0’)
Datasheet
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DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
4-WIRE WRITE
nCS
SK
SI
A6
A5
A4
A3
A2
A1
A0
R/Wn
D7
D6
D5
D4
D3
D2
D1
D0
D6
D5
D4
D3
D2
D1
D0
SO
4-WIRE READ
nCS
SK
SI
A6
A5
A4
A3
A2
A1
A0
R/Wn
HI-Z
SO
D7
latch data
Figure 19: 4-WIRE Host Write and Read Timing (nCS_POL= ‘0’, CPOL = ‘0’, CPHA = ‘1’)
4-WIRE WRITE
nCS
SK
SI
A6
A5
A4
A3
A2
A1
A0
R/Wn
D7
D6
D5
D4
D3
D2
D1
D0
D6
D5
D4
D3
D2
D1
D0
SO
4-WIRE READ
nCS
SK
SI
A6
SO
A5
A4
A3
A2
A1
A0
R/Wn
HI-Z
D7
latch data
Figure 20: 4-WIRE Host Write and Read Timing (nCS_POL = ‘0’, CPOL = ‘1’, CPHA = ‘0’)
Datasheet
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DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
4-WIRE WRITE
nCS
SK
SI
A6
A5
A4
A3
A2
A1
A0
R/Wn
D7
D6
D5
D4
D3
D2
D1
D0
D6
D5
D4
D3
D2
D1
D0
SO
4-WIRE READ
nCS
SK
SI
SO
A6
A5
A4
A3
A2
A1
A0
R/Wn
HI-Z
D7
latch data
Figure 21: 4-WIRE Host Write and Read Timing (nCS_POL = ‘0’, CPOL = ‘1’, CPHA = ‘1’)
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Auto Grade Multi-Phase 5A/Phase Buck Converter
Table 11: 4-WIRE Interface Summary
Parameters
Signal Lines
nCS
Chip select
SI Serial input data
Master out Slave in
SO Serial output data
Master in Slave out
SK
Transmission clock
Interface
Push-pull with tristate
Supply voltage
Selected from VDDIO
1.6 V to 3.3 V
Data rate
Effective read/write data
Up to 7 Mbps
Transmission
Half-duplex
MSB first
16 bit cycles
7-bit address, 1 bit read/write, 8-bit data
CPOL
Clock polarity
CPHA
Clock phase
nCS_POL
nCS is active low/high
Configuration
Note that reading the same register at high clock rates directly after writing it does not guarantee a
correct value. It is recommended to keep a delay of one frame until re-accessing a register that has
just been written (for example, by writing/reading another register address in between).
7.4.2
2-WIRE Communication
The IF_TYPE bit in the INTERFACE2 register can be used to configure the DA9213-A and DA9214A control interface as a 2-WIRE serial data interface. In this case the GPIO3 and GPI4 are free for
regular input/output functions. DA9213-A and DA9214-A has a configurable device write address
(default: 0xD0) and a configurable device read address (default: 0xD1). See control
IF_BASE_ADDR1 for details of configurable addresses. The ADDR_SEL_CONF bit is used to
configure the device address as IF_BASE_ADDR1 or IF_BASE_ADDR2 depending on the voltage
level applied at a configurable GPI port (see GPIO Extender).
The SK port functions as the 2-WIRE clock and the SI port carries all the power manager
bi-directional 2-WIRE data. The 2-WIRE interface is open-drain supporting multiple devices on a
single line. The bus lines have to be pulled HIGH by external pull-up resistors (in the 2 kΩ to 20 kΩ
range). The attached devices only drive the bus lines LOW by connecting them to ground. As a result
two devices cannot conflict if they drive the bus simultaneously. In standard/fast mode the highest
frequency of the bus is 400 kHz. The exact frequency can be determined by the application and does
not have any relation to the DA9213-A and DA9214-A internal clock signals. DA9213-A and DA9214A will follow the host clock speed within the described limitations, and does not initiate any clock
arbitration or slow down. An automatic interface reset can be triggered using control 2WIRE_TO if
the clock signal stops to toggle for more than 35 ms.
The interface supports operation compatible to Standard, Fast, Fast-Plus and High Speed mode of
2
the I C-bus specification Rev 4. Operation in high speed mode at 3.4 MHz requires mode changing in
2
order to set spike suppression and slope control characteristics to be compatible with the I C-bus
specification. The high speed mode can be enabled on a transfer by transfer basis by sending the
master code (0000 1XXX) at the beginning of the transfer. DA9213-A and DA9214-A do not make
use of clock stretching, and deliver read data without additional delay up to 3.4 MHz.
Alternatively, PM_IF_HSM configures the interface to use high speed mode continuously. In this
case, the master code is not required at the beginning of every transfer. This reduces the
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DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
communication overhead on the bus but limits the slaves attachable to the bus to compatible
devices.
The communication on the 2-WIRE bus always takes place between two devices, one acting as the
master and the other as the slave. The DA9213-A and DA9214-A will only operate as a SLAVE.
In contrast to the 4-WIRE mode, the 2-WIRE interface has direct access to two pages of the register
map (up to 256 addresses). The register at address zero on each page is used as a page control
register (with the 2-WIRE bus ignoring the LSB of control REG_PAGE). Writing to the page control
register changes the active page for all subsequent read/write operations unless an automatic return
to page 0 was selected by asserting control REVERT. Unless REVERT was asserted after modifying
the active page, it is recommended to read back the page control register to ensure that future data
exchange is accessing the intended registers.
In 2-WIRE operation DA9213-A and DA9214-A offer an alternative way to access register page 2
and page 3. It removes the need for preceding page selection writes by incrementing the device
write/read address by one (default 0xD2/0xD3) for any direct access of page 2 and page 3 (page 0
and 1 access requires the basic write/read device address with the MSB of REG_PAGE to be ‘0’).
7.4.3
Details of the 2-WIRE Control Bus Protocol
All data is transmitted across the 2-WIRE bus in groups of eight bits. To send a bit the SDA line is
driven towards the intended state while the SCL is LOW (a low on SDA indicates a zero bit). Once
the SDA has settled, the SCL line is brought HIGH and then LOW. This pulse on SCL clocks the
SDA bit into the receiver’s shift register.
A two-byte serial protocol is used containing one byte for address and one byte data. Data and
address transfer are transmitted MSB first for both read and write operations. All transmissions begin
with the START condition from the master while the bus is in IDLE state (the bus is free). It is initiated
by a high to low transition on the SDA line while the SCL is in the high state (a STOP condition is
indicated by a low to high transition on the SDA line while the SCL is in the high state).
SCL
SDA
Figure 22: Timing of 2-WIRE START and STOP Condition
The 2-WIRE bus is monitored by DA9213-A and DA9214-A for a valid SLAVE address whenever the
interface is enabled. It responds immediately when it receives its own slave address. The
acknowledge is done by pulling the SDA line low during the following clock cycle (white blocks
marked with ‘A’ in Figure 23 to Figure 27).
The protocol for a register write from master to slave consists of a start condition, a slave address
with read/write bit and the 8-bit register address followed by eight bits of data terminated by a STOP
condition. DA9213-A and DA9214-A respond to all bytes with Acknowledge. This is illustrated in
Figure 23.
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DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
S
SLAVEadr
7-bits
W
A
REGadr
1-bit
A
DATA
8-bits
Master to Slave
P
A
8-bits
Slave to Master
S = START condition
P = STOP condition
A = Acknowledge (low)
W = Write (low)
Figure 23: 2-WIRE Byte Write (SDA Line)
When the host reads data from a register it first has to write to DA9213-A and DA9214-A with the
target register address and then read from DA9213-A and DA9214-A with a Repeated START or
alternatively a second START condition. After receiving the data, the host sends No Acknowledge
and terminates the transmission with a STOP condition. This is illustrated in Figure 24.
S
SLAVEadr W A
7-bits
S
1-bit
SLAVEadr W A
7-bits
1-bit
REGadr
A Sr SLAVEadr
8-bits
7-bits
REGadr
A
P
S
A
7-bits
*
DATA
A
P
8-bits
SLAVEadr
8-bits
Master to Slave
R
1-bit
R
A
1-bit
*
DATA
A
P
8-bits
Slave to Master
S = START condition
Sr = Repeated START condition
P = STOP condition
A = Acknowledge (low)
*
A = No Acknowledge
W = Write (low)
R = Read (high)
Figure 24: Examples of 2-WIRE Byte Read (SDA Line)
Consecutive (page) read out mode is initiated from the master by sending an Acknowledge instead of
Not acknowledge after receipt of the data word. The 2-WIRE control block then increments the
address pointer to the next 2-WIRE address and sends the data to the master. This enables an
unlimited read of data bytes until the master sends a Not acknowledge directly after the receipt of
data, followed by a subsequent STOP condition. If a non-existent 2-WIRE address is read out, the
DA9213-A and DA9214-A will return code zero. This is illustrated in Figure 25.
S SLAVEadr W A
7-bits
1 bit
S SLAVEadr W
7-bits
REGadr
A Sr SLAVEadr R A
8-bits
A
REGadr
7-bits
S
A P
Master to Slave
S = START condition
Sr = Repeat START condition
P = STOP condition
8-bits
SLAVEadr R A
7-bits
8-bits
1-bit
1-bit
DATA
1-bit
A
DATA
A
8-bits
DATA
*
DATA
A
P
8-bits
A
8-bits
DATA
*
A
P
8-bits
Slave to Master
A = Acknowledge (low)
*
A = No Acknowledge
W = Write (low)
R = Read (high)
Figure 25: Examples of 2-WIRE Page Read (SDA Line)
Note that the slave address after the Repeated START condition must be the same as the previous
slave address.
Consecutive (page) write mode is supported if the Master sends several data bytes following a slave
register address. The 2-WIRE control block then increments the address pointer to the next 2-WIRE
address, stores the received data and sends an Acknowledge until the master sends the STOP
condition. This is illustrated in Figure 26.
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DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
S SLAVEadr W A
7-bits
1 bit
REGadr
A
8-bits
Master to Slave
DATA
8-bits
A
DATA
1-bit
A
8-bits
DATA
A
8-bits
……….
A
P
Repeated writes
Slave to Master
S = START condition
Sr = Repeat START condition
P = STOP condition
A = Acknowledge (low)
*
A = No Acknowledge
W = Write (low)
R = Read (high)
Figure 26: 2-WIRE Page Write (SDA Line)
Via control WRITE_MODE an alternate write mode can be configured. Register addresses and data
are sent in alternation like in Figure 27 to support host repeated write operations that access several
non-consecutive registers. Data will be stored at the previously received register address.
An update of WRITE_MODE cannot be done without interruption within a transmission frame. Thus,
if not previously selected or not set as OTP default, the activation of Repeated Write must be done
with a regular write on WRITE_MODE followed by a stop condition. The next frame after a start
condition can be written in Repeated Write.
S SLAVEadr W A
7-bits
1 bit
REGadr
8-bits
Master to Slave
A
DATA
8-bits
A
REGadr
1-bit
8-bits
A
DATA
8-bits
A
……….
A
P
Repeated writes
Slave to Master
S = START condition
Sr = Repeat START condition
P = STOP condition
A = Acknowledge (low)
*
A = No Acknowledge
W = Write (low)
R = Read (high)
Figure 27: 2-WIRE Repeated Write (SDA Line)
If a new START or STOP condition occurs within a message, the bus will return to IDLE-mode.
Datasheet
CFR0011-120-00
Revision 1.4
38 of 62
08-May-2017
© 2017 Dialog Semiconductor
DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
7.5
Internal Temperature Supervision
To protect DA9213-A and DA9214-A from damage due to excessive power dissipation, the internal
temperature is continuously monitored. There are three temperature thresholds:
Table 12: Over-Temperature Thresholds
Temperature
Threshold
Typical
Temperature
Setting
Interrupt Event
Status Bit
Masking Bit
TEMP_WARN
125 °C
E_TEMP_WARN
TEMP_WARN
M_TEMP_WARN
TEMP_CRIT
140 °C
E_TEMP_CRIT
TEMP_CRIT
M_TEMP_CRIT
TEMP_POR
150 °C
When the junction temperature reaches the TEMP_WARN threshold, DA9213-A and DA9214-A will
assert the bit TEMP_WARN and will generate the event E_TEMP_WARN. If not masked using bit
M_TEMP_WARN, the output port nIRQ will be asserted. The status bit TEMP_WARN will remain
asserted as long as the junction temperature remains higher than TEMP_WARN.
When the junction temperature increases further to TEMP_CRIT, DA9213-A and DA9214-A will
immediately disable the buck converter, assert the bit TEMP_CRIT, and will generate the event
E_TEMP_CRIT. If not masked via bit M_TEMP_CRIT, the output port nIRQ will be asserted. The
status bit TEMP_CRIT will remain asserted as long as the junction temperature remains higher than
TEMP_CRIT. The buck converter will be kept disabled as long as the junction temperature is above
TEMP_CRIT. It will not be automatically re-enabled even after the temperature drops below the valid
threshold (even if the controlling GPI is asserted). A direct write into BUCKA_EN or BUCKB_EN, or a
toggling of the controlling GPI, is needed to enable the buck converter.
Whenever the junction temperature exceeds TEMP_POR, a power on reset to the digital core is
immediately asserted, which will stops all functionalities of DA9213-A and DA9214-A. This is needed
to prevent possible permanent damage in the case of a rapid temperature increase.
Datasheet
CFR0011-120-00
Revision 1.4
39 of 62
08-May-2017
© 2017 Dialog Semiconductor
DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
8
8.1
Register Definitions
Register Map
Table 13 displays the register map, where all bits loaded from OTP are marked in bold.
Datasheet
CFR0011-120-00
Revision 1.4
40 of 62
08-May-2017
© 2017 Dialog Semiconductor
DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
Table 13: Register Map
A ddr
F unc t io n
7
6
5
4
3
2
1
0
Register Page 0
REVERT
WRITE_M ODE
Reserved
REG_P A GE
0x00
P A GE_CON
Reserved
0x50
STA TUS_A
Reserved
Reserved
Reserved
GP I4
GP I3
GP I2
GP I1
GP I0
0x51
STA TUS_B
RA M P _REA DY_B
RA M P _REA DY_A
OV_CURR_B
OV_CURR_A
TEM P _CRIT
TEM P _WA RN
P WRGOOD_B
P WRGOOD_A
0x52
EVENT_A
Reserved
E_UVLO_IO
Reserved
E_GP I4
E_GP I3
E_GP I2
E_GP I1
E_GP I0
0x53
EVENT_B
Reserved
Reserved
E_OV_CURR_B
E_OV_CURR_A
E_TEM P _CRIT
E_TEM P _WA RN
E_P WRGOODB
E_P WRGOOD_A
0x54
M A SK_A
Reserved
M _ UV LO _ IO
Reserved
M _ G P I4
M _ G P I3
M _ G P I2
M _ G P I1
M _ G P I0
0x55
M A SK_B
Reserved
Reserved
M _ O V _ C UR R _ B
M _ O V _ C UR R _ A
M _ T E M P _ C R IT
M _ T E M P _ WA R N
M _ P WR G O O D _ B
M _ P WR G O O D _ A
0x56
CONTROL_A
V _ LO C K
0x57
Reserved
Reserved
Reserved
0x58
GP IO0-1
G P I1_ M O D E
G P I1_ T Y P E
S LE W_ R A T E _ B
S LE W_ R A T E _ A
Reserved
Reserved
D E B O UN C IN G
Reserved
Reserved
G P I1_ P IN
G P I0 _ M O D E
G P I0 _ T Y P E
Reserved
G P I0 _ P IN
Reserved
0x59
GP IO2-3
G P IO 3 _ M O D E
G P IO 3 _ T Y P E
G P IO 3 _ P IN
G P IO 2 _ M O D E
G P IO 2 _ T Y P E
G P IO 2 _ P IN
0x5A
GP IO4
Reserved
Reserved
Reserved
G P I4 _ M O D E
G P I4 _ T Y P E
G P I4 _ P IN
0x5B
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
0x5C
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
0x5D
B UCKA _CONT
Reserved
V B UC KA _ G P I
V B UC KA _ S E L
B UC KA _ P D _ D IS
B UC KA _ G P I
B UC KA _ E N
0x5E
B UCKB _CONT
Reserved
V B UC KB _ G P I
V B UC KB _ S E L
B UC KB _ P D _ D IS
B UC KB _ G P I
B UC KB _ E N
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Register Page 1
0x80
P A GE_CON
REVERT
WRITE_M ODE
Reserved
REG_P A GE
B UC KB _ ILIM
B UC KA _ ILIM
0xD0
B UCK_ILIM
0xD1
B UCKA _CONF
B UC KA _ D O WN _ C T R L
B UC KA _ UP _ C T R L
0xD2
B UCKB _CONF
B UC KB _ D O WN _ C T R L
B UC KB _ UP _ C T R L
0xD3
B UCK_CONF
Reserved
Reserved
Reserved
P H _SH _EN _B
P H _SH _EN _A
P H A S E _ S E L_ B
0xD4
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
0xD5
VB UCKA _M A X
Reserved
V B UC KA _ M A X
0xD6
VB UCKB _M A X
Reserved
V B UC KB _ M A X
0xD7
VB UCKA _A
B UC KA _ S L_ A
V B UC KA _ A
0xD8
VB UCKB _B
B UC KA _ S L_ B
V B UC KA _ B
0xD9
VB UCKB _A
B UC KB _ S L_ A
V B UC KB _ A
0xDA
VB UCKB _B
B UC KB _ S L_ B
B UC KA _ M O D E
B UC KB _ M O D E
P H A S E _ S E L_ A
Reserved
V B UC KB _ B
Register Page 2
REG_P A GE
0x100
P A GE_CON
REVERT
WRITE_M ODE
Reserved
Reserved
Reserved
0x101
OTP _CONT
Reserved
Reserved
Reserved
Reserved
P C_DONE
OTP _A P P S_RD
Reserved
OTP _TIM
0x102
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
0x103
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
0x104
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
0x105
INTERFA CE
R / W_ P O L
CP HA
C P OL
nC S _ P O L
0x106
INTERFA CE2
IF _ T Y P E
P M _ IF _ H S M
P M _ IF _ F M P
P M _ IF _ V
Reserved
Reserved
Reserved
Reserved
0x140
OTP _CONT2
O T P _ C O N F _ LO C K
O T P _ A P P S _ LO C K
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
0x141
OTP _A DDR
0x142
OTP _DA TA
0x143
CONFIG_A
Reserved
Reserved
Reserved
G P I_ V
Reserved
0x144
CONFIG_B
UV LO _ IO _ D IS
P GB _D VC _M A SK
P GA _D VC _M A SK
0x145
CONFIG_C
Reserved
Reserved
Reserved
0x146
CONFIG_D
0x147
CONFIG_E
0x148
CONFIG_F
Datasheet
CFR0011-120-00
IF _ B A S E _ A D D R 1
OTP _A DDR
OTP _DA TA
B UC KB _ P G _ S E L
S T A N D _ A LO N E
2 WIR E _ T O
OC B _M A SK
G P I4 _ P UP D
B UC KA _ P G _ S E L
Reserved
Reserved
Reserved
IF _ B A S E _ A D D R 2
G P IO 3 _ P UP D
41 of 62
G P IO 2 _ P UP D
R EA D YB _C ON F
IR Q _ LE V E L
R E LO A D _ F UN C _ E N
G P I1_ P UP D
G P I0 _ P UP D
R EA D YA _C ON F
O S C _ T UN E
Reserved
Reserved
Revision 1.4
IR Q _ T Y P E
OC A _M A SK
Reserved
A D D R _ S E L_ C O N F
08-May-2017
© 2017 Dialog Semiconductor
DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
8.2
Register Definitions
8.2.1
Register Page Control
Register
Bit
0x00
PAGE_CON
Type
Label
Description
7
R/W
REVERT
Resets REG_PAGE to 000 after read/write access has
finished
6
R/W
WRITE_MODE
2-WIRE multiple write mode (Note 1)
0: Page Write Mode
1: Repeated Write Mode
5:3
R/W
(reserved)
2
IC
00x: Selects Register 0x00 to 0xFF
01x: Selects Register 0x100 to 0x17F
2:0
R/W
SPI
000: Selects Register 0x00 to 0x7F
REG_PAGE
001: Selects Register 0x80 to 0xFF
010: Selects Register 0x100 to 0x17F
>010: Reserved for production and test
Note 1
8.2.2
Not used for 4-WIRE-IF
Register Page 0
8.2.2.1
System Control and Event
The STATUS registers report the current value of the various signals at the time that it is read out.
Register
Bit
Type
Label
0x50
STATUS_A
7:5
R
(reserved)
4
R
GPI4
GPI4 level
3
R
GPI3
GPI3 level
2
R
GPI2
GPI2 level
1
R
GPI1
GPI1 level
0
R
GPI0
GPI0 level
Register
Bit
Type
Label
Description
0x51
STATUS_B
7
R
RAMP_READY_B
De-asserted during Buck A DVC, power up and power
down
6
R
RAMP_READY_A
De-asserted during Buck B DVC, power up and power
down
5
R
OV_CURR_B
Asserted as long as the current limit for Buck B is hit
4
R
OV_CURR_A
Asserted as long as the current limit for Buck A is hit
3
R
TEMP_CRIT
Asserted as long as the thermal shutdown threshold
is reached
2
R
TEMP_WARN
Asserted as long as the thermal warning threshold is
reached
Datasheet
CFR0011-120-00
Description
Revision 1.4
42 of 62
08-May-2017
© 2017 Dialog Semiconductor
DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
Register
Bit
Type
Label
Description
1
R
PWRGOOD_B
Asserted as long as the Buck B output voltage is in
range
0
R
PWRGOOD_A
Asserted as long as the Buck A output voltage is in
range
The EVENT registers hold information about events that have occurred in DA9213-A and DA9214-A.
Events are triggered by a change in the status register which contains the status of monitored
signals. When an EVENT bit is set in the event register, the IRQ signal is asserted unless the event
is masked by a bit in the mask register. The IRQ triggering event register will be cleared from the
host by writing back its read value. New events occurring during clearing will be delayed before
they are passed to the event register, ensuring that the host controller does not miss them.
Register
Bit
Type
Label
0x52
7
R
(reserved)
EVENT_A
6
R
E_UVLO_IO
5
R
(reserved)
4
R
E_GPI4
GPI4 event according to active state setting
3
R
E_GPI3
GPI3 event according to active state setting
2
R
E_GPI2
GPI2 event according to active state setting
1
R
E_GPI1
GPI1 event according to active state setting
0
R
E_GPI0
GPI0 event according to active state setting
Register
Bit
Type
Label
Description
0x53
7:6
R
(reserved)
EVENT_B
5
R
E_OV_CURR_B
OV_CURR Buck B caused event
4
R
E_OV_CURR_A
OV_CURR Buck A caused event
3
R
E_TEMP_CRIT
TEMP_CRIT caused event
2
R
E_TEMP_WARN
TEMP_WARN caused event
1
R
E_PWRGOOD_B
PWRGOOD loss at Buck B caused event
0
R
E_PWRGOOD_A
PWRGOOD loss at Buck A caused event
Register
Bit
Type
Label
Description
0x54
7
R/W
(reserved)
MASK_A
6
R/W
M_UVLO_IO
5
R/W
(reserved)
4
R/W
M_GPI4
Masks nIRQ interrupt at GPI4
3
R/W
M_GPI3
Masks nIRQ interrupt at GPI3
2
R/W
M_GPI2
Masks nIRQ interrupt at GPI2
1
R/W
M_GPI1
Masks nIRQ interrupt at GPI1
0
R/W
M_GPI0
Masks nIRQ interrupt at GPI0
Datasheet
CFR0011-120-00
Description
UVLO_IO caused the event
Mask UVLO_IO caused nIRQ
Revision 1.4
43 of 62
08-May-2017
© 2017 Dialog Semiconductor
DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
Register
Bit
Type
Label
Description
0x55
7:6
R/W
(reserved)
MASK_B
5
R/W
M_OV_CURR_B
OV_CURR Buck B caused event
4
R/W
M_OV_CURR_A
OV_CURR Buck A caused event
3
R/W
M_TEMP_CRIT
TEMP_CRIT caused event
2
R/W
M_TEMP_WARN
TEMP_WARN caused event
1
R/W
M_PWRGOOD_B
PWRGOOD Buck B caused event
0
R/W
M_PWRGOOD_A
PWRGOOD Buck A caused event
Register
Bit
Type
Label
Description
0x56
7
R/W
V_LOCK
0: Allows host writes into registers 0xD0 to 0x14F
CONTROL_A
1: Disables register 0xD0 to 0x14F re-programming
from control interfaces
6:5
R/W
SLEW_RATE_B
Buck B DVC slewing is executed at
00: 10mV every 4.0 µs
01: 10mV every 2.0 µs
10: 10mV every 1.0 µs
11: 10mV every 0.5 µs
4:3
R/W
SLEW_RATE_A
Buck A DVC slewing is executed at
00: 10mV every 4.0 µs
01: 10mV every 2.0 µs
10: 10mV every 1.0 µs
11: 10mV every 0.5 µs
0:2
R/W
DEBOUNCE
Input signals debounce time:
000: no debounce time
001: 0.1 ms
010: 1.0 ms
011: 10 ms
100: 50 ms
101: 250 ms
110: 500 ms
111: 1000 ms
8.2.2.2
GPIO Control
Register
Bit
Type
Label
Description
0x58
GPI0-1
7
R/W
GPI1_MODE
0: GPI: debouncing off
1: GPI: debouncing on
6
R/W
GPI1_TYPE
0: GPI: active low
1: GPI: active high
5:4
R/W
GPI1_PIN
3
R/W
GPI0_MODE
PIN assigned to:
Datasheet
CFR0011-120-00
00: GPI
>00: Reserved
0: GPI: debouncing off
1: GPI: debouncing on
Revision 1.4
44 of 62
08-May-2017
© 2017 Dialog Semiconductor
DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
Register
Bit
Type
Label
2
R/W
GPI0_TYPE
Description
0: GPI: active low
1: GPI: active high
PIN assigned to:
1:0
R/W
00: GPI
01: Track enable
GPI0_PIN
1x: Reserved
Register
Bit
Type
Label
Description
0x59
GPIO2-3
7
R/W
GPIO3_MODE
6
R/W
GPIO3_TYPE
0: GPI: debouncing off
GPO: Sets output to passive level
1: GPI: debouncing on
GPO: Sets output to active level
0: GPI/GPO: active low
1: GPI/GPO: active high
PIN assigned to:
5:4
R/W
00: GPI
01: Reserved
GPIO3_PIN
10: GPO (Open drain)
11: GPO (Push-pull)
3
R/W
GPIO2_MODE
2
R/W
GPIO2_TYPE
0: GPI: debouncing off
GPO: Sets output to passive level
1: GPI: debouncing on
GPO: Sets output to active level
0: GPI/GPO: active low
1: GPI/GPO: active high
PIN assigned to:
1:0
R/W
GPIO2_PIN
00: GPI
01: Reserved
10: GPO (Open drain)
11: GPO (Push-pull)
Register
Bit
Type
Label
0x5A
GPI4
7:4
R/W
(reserved)
3
R/W
GPI4_MODE
2
R/W
GPI4_TYPE
1:0
Datasheet
CFR0011-120-00
R/W
GPI4_PIN
Description
0: GPI: debouncing off
1: GPI: debouncing on
0: GPI: active low
1: GPI: active high
PIN assigned to:
00: GPI
01: Reserved
1x: Reserved
Revision 1.4
45 of 62
08-May-2017
© 2017 Dialog Semiconductor
DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
8.2.2.3
Regulators Control
Register
Bit
Type
Label
0x5D
BUCKA_CON
T
7
R/W
(reserved)
Description
Selects the GPI that specifies the target voltage of
VBUCKA. This is VBUCKA_A on active to passive
transition, VBUCKA_B on passive to active transition.
Active high/low is controlled by GPIx_TYPE.
6:5
R/W
VBUCKA_GPI
00: Not controlled by GPIO
01: GPIO1 controlled
10: GPIO2 controlled
11: GPIO4 controlled
4
R/W
VBUCKA_SEL
Buck A voltage is selected from (ramping):
0: VBUCKA_A
1: VBUCKA_B
3
2:1
R/W
R/W
BUCKA_PD_DIS
0: Enable pull-down resistor of Buck A when the buck
is disabled
1: Disable pull-down resistor of Buck A when the buck
is disabled
GPIO enables the Buck A on passive to active state
transition, disables the Buck A on active to passive
state transition
00: Not controlled by GPIO
BUCKA_GPI
01: GPIO0 controlled
10: GPIO1 controlled
11: GPIO3 controlled
0
R/W
BUCKA_EN
Register
Bit
Type
Label
0x5E
7
R/W
(reserved)
0: Buck A disabled
1: Buck A enabled
Description
BUCKB_CON
T
Selects the GPI that specifies the target voltage of
VBUCKB. This is VBUCKB_A on active to passive
transition, VBUCKB_B on passive to active transition.
Active high/low is controlled by GPIx_TYPE.
6:5
R/W
VBUCKB_GPI
00: Not controlled by GPIO
01: GPIO1 controlled
10: GPIO2 controlled
11: GPIO4 controlled
4
R/W
VBUCKB_SEL
Buck A voltage is selected from (ramping):
0: VBUCKB_A
1: VBUCKB_B
Datasheet
CFR0011-120-00
3
R/W
BUCKB_PD_DIS
2:1
R/W
BUCKB_GPI
0: Enable pull-down resistor of Buck B when the buck
is disabled
1: Disable pull-down resistor of Buck B when the buck
is disabled
GPIO enables the Buck B on passive to active state
transition, disables the Buck B on active to passive
state transition
Revision 1.4
46 of 62
08-May-2017
© 2017 Dialog Semiconductor
DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
Register
Bit
Type
Label
Description
00: Not controlled by GPIO
01: GPIO0 controlled
10: GPIO1 controlled
11: GPIO3 controlled
0
8.2.3
R/W
0: Buck B disabled
BUCKB_EN
1: Buck B enabled
Register Page 1
Register
Bit
Type
Label
Description
0x80
PAGE_CON
7
R/W
REVERT
Resets REG_PAGE to 000 after read/write access has
finished
6
R/W
WRITE_MODE
2-WIRE multiple write mode
0: Page Write Mode
1: Repeated Write Mode
5:3
R/W
(reserved)
2
IC
00x: Selects Register 0x00 to 0xFF
01x: Selects Register 0x100 to 0x17F
2:0
R/W
REG_PAGE
SPI
000: Selects Register 0x00 to 0x7F
001: Selects Register 0x80 to 0xFF
010: Selects Register 0x100 to 0x17F
>010: Reserved for production and test
8.2.3.1
Regulators Settings
Register
Bit
Type
Label
Description
0xD0
Current limit per phase:
BUCK_ILIM
0000: 4000 mA
0001: 4200 mA
0010: 4400 mA
7:4
R/W
BUCKB_ILIM
continuing through…
1001: 5800 mA
to…
1110: 6800 mA
1111: 7000 mA
Current limit per phase:
0000: 4000 mA
0001: 4200 mA
0010: 4400 mA
3:0
R/W
BUCKA_ILIM
continuing through…
1001: 5800 mA
to…
1110: 6800 mA
Datasheet
CFR0011-120-00
Revision 1.4
47 of 62
08-May-2017
© 2017 Dialog Semiconductor
DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
Register
Bit
Type
Label
Description
1111: 7000 mA
Register
Bit
Type
Label
Description
0xD1
Buck A voltage ramping during power down
BUCKA_CON
F
000: 1.25 mV/µs
001: 2.5 mV/µs
7:5
R/W
BUCKA_DOWN_
CTRL
010: 5 mV/µs
011: 10 mV/µs
100: 20 mV/µs
101: 30 mV/µs
110: 40 mV/µs
111: Reserved
Buck A voltage ramping during start up
000: 1.25 mV/µs
001: 2.5 mV/µs
4:2
R/W
BUCKA_UP_CTR
L
010: 5 mV/µs
011: 10 mV/µs
100: 20 mV/µs (Note 2)
101: 30 mV/µs
110: 40 mV/µs
111: target voltage applied immediately (no soft start)
00: PFM/PWM mode controlled via voltage A and B
registers
1:0
R/W
BUCKA_MODE
01: Automatic mode
10: Buck A always operates in PWM mode
11: Automatic mode
Note 2
Settings higher than 20 mV/µs may cause significant overshoot
Register
Bit
Type
Label
Description
0xD2
Buck B voltage ramping during power down
BUCKB_CON
F
000: 1.25 mV/µs
001: 2.5 mV/µs
7:5
R/W
BUCKB_DOWN_
CTRL
010: 5 mV/µs
011: 10 mV/µs
100: 20 mV/µs
101: 30 mV/µs
110: 40 mV/µs
111: Reserved
Buck B voltage ramping during start up
000: 1.25 mV/µs
4:2
R/W
BUCKB_UP_CTR
L
001: 2.5 mV/µs
010: 5 mV/µs
011: 10 mV/µs
100: 20 mV/µs (Note 3)
101: 30 mV/µs
110: 40 mV/µs
111: target voltage applied immediately (no soft start)
Datasheet
CFR0011-120-00
Revision 1.4
48 of 62
08-May-2017
© 2017 Dialog Semiconductor
DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
Register
Bit
1:0
Type
R/W
Label
Description
BUCKB_MODE
00: PFM/PWM mode controlled via voltage A and B
registers
01: Automatic mode
10: Buck B always operates in PWM mode
11: Automatic mode
Note 3
Settings higher than 20mV/µs may cause significant overshoot
Register
Bit
Type
Label
Description
0xD3
7:5
R/W
(reserved)
4
R/W
PH_SH_EN_B
Enable current dependent phase shedding in PWM for
Buck B
3
R/W
PH_SH_EN_A
Enable current dependent phase shedding in PWM for
Buck A
2
R/W
PHASE_SEL_B
BUCK_CONF
Phase selection for Buck B in PWM
1:0
R/W
PHASE_SEL_A
Register
Bit
Type
Label
0xD5
VBUCKA_MA
X
7
R/W
(reserved)
0: 1 phase is selected
1: 2 phases are selected
Phase selection for Buck A in PWM mode. Settings >01
apply only for DA9213-A otherwise the number of
phases is limited to max 2
00: 1 phase is selected
01: 2 phases are selected
10: 3 phases are selected (uneven 0/90/180 phase
shift)
11: 4 phases are selected
Description
Sets the maximum voltage allowed for Buck A (OTP
programmed, access only in test mode)
0000000: 0.30 V
0000001: 0.31 V
0000010: 0.32 V
6:0
R
VBUCKA_MAX
Continuing through…
1000110: 1.0 V
to…
1111101: 1.55 V
1111110: 1.56 V
1111111: 1.57 V
Register
Bit
Type
Label
0xD6
7
R/W
(reserved)
VBUCKB_MA
6:0
R
VBUCKB_MAX
Datasheet
CFR0011-120-00
Description
Sets the maximum voltage allowed for Buck B (OTP
Revision 1.4
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DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
Register
Bit
Type
Label
Description
X
programmed, access only in test mode)
0000000: 0.30 V
0000001: 0.31 V
0000010: 0.32 V
Continuing through…
1000110: 1.0 V
to…
1111101: 1.55 V
1111110: 1.56 V
1111111: 1.57 V
Register
Bit
Type
Label
Description
BUCKA_SL_A
0: Configures Buck A to PWM mode whenever
selecting A voltage setting
1: Configures Buck A to automatic mode whenever
selecting A voltage setting
0xD7
VBUCKA_A
7
R/W
0000000: 0.30 V
0000001: 0.31 V
0000010: 0.32 V
6:0
R/W
Continuing through…
1000110: 1.0 V
VBUCKA_A
to…
1111101: 1.55 V
1111110: 1.56 V
1111111: 1.57 V
Register
0xD8
VBUCKA_B
Bit
7
Type
R/W
Label
Description
BUCKA_SL_B
0: Configures Buck A to PWM mode, whenever
selecting B voltage setting
1: Configures Buck A to automatic mode, whenever
selecting B voltage setting
0000000: 0.30 V
0000001: 0.31 V
0000010: 0.32 V
6:0
R/W
VBUCKA_B
Continuing through…
1000110: 1.0 V
to…
1111101: 1.55 V
1111110: 1.56 V
1111111: 1.57 V
Datasheet
CFR0011-120-00
Revision 1.4
50 of 62
08-May-2017
© 2017 Dialog Semiconductor
DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
Register
Bit
Type
Label
Description
BUCKB_SL_A
0: Configures Buck B to PWM mode, whenever
selecting A voltage setting
1: Configures Buck B to automatic mode, whenever
selecting A voltage setting
0xD9
VBUCKB_A
7
R/W
0000000: 0.30 V
0000001: 0.31 V
0000010: 0.32 V
6:0
R/W
Continuing through…
1000110: 1.0 V
VBUCKB_A
to…
1111101: 1.55 V
1111110: 1.56 V
1111111: 1.57 V
Register
0xDA
VBUCKB_B
Bit
7
Type
R/W
Label
Description
BUCKB_SL_B
0: Configures Buck B to PWM mode, whenever
selecting B voltage setting
1: Configures Buck B to automatic mode, whenever
selecting B voltage setting
0000000: 0.30 V
0000001: 0.31 V
0000010: 0.32 V
6:0
R/W
VBUCKB_B
Continuing through…
1000110: 1.0 V
to…
1111101: 1.55 V
1111110: 1.56 V
1111111: 1.57 V
Datasheet
CFR0011-120-00
Revision 1.4
51 of 62
08-May-2017
© 2017 Dialog Semiconductor
DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
8.2.4
Register Page 2
Register
Bit
Type
Label
Description
0x100
PAGE_CON
7
R/W
REVERT
Resets REG_PAGE to 000 after read/write access has
finished
6
R/W
2-WIRE multiple write mode
0: Page Write Mode
WRITE_MODE
1: Repeated Write Mode
5:3
R/W
(reserved)
2
IC
00x: Selects Register 0x00 to 0xFF
01x: Selects Register 0x100 to 0x17F
2:0
R/W
SPI
000: Selects Register 0x00 to 0x7F
REG_PAGE
001: Selects Register 0x80 to 0xFF
010: Selects Register 0x100 to 0x17F
>010: Reserved for production and test
8.2.4.1
Interface and OTP Settings (shared with DA9063)
Register
Bit
Type
Label
Description
0x101
OTP_CONT
7:4
R/W
(reserved)
3
R/W
PC_DONE
Asserted from Power Commander software after the
emulated OTP read has finished, automatically cleared
when leaving emulated OTP read
2
R/W
OTP_APPS_RD
Reads on assertion application specific registers 0x105,
0x106, 0x143 to 0x149 and OTP_APPS_LOCK) from
OTP
1
R/W
(reserved)
0
R/W
OTP_TIM
OTP read timing:
0: normal read
1: marginal read (for OTP fuse verification)
Register
Bit
Type
Label
Description
0x105
INTERFACE
4 MSB of 2-WIRE control interfaces base address
XXXX0000
11010000 = 0xD0 write address of PM 2-WIRE
interface (page 0 and 1)
11010001 = 0xD1 read address of PM 2-WIRE
interface (page 0 and 1)
7:4
R/W
IF_BASE_ADDR1
11010010 = 0xD2 write address of PM-2-WIRE
interface (page 2 and 3)
11010011 = 0xD3 read address of PM-2-WIRE
interface (page 2 and 3)
Code ‘0000’ is reserved for unprogrammed OTP
(triggers start-up with hardware default interface
address)
3
Datasheet
CFR0011-120-00
R/W
R/W_POL
4-WIRE: Read/Write bit polarity
0: Host indicates reading access via R/W bit = ‘0’
Revision 1.4
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DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
Register
Bit
Type
Label
Description
1: Host indicates reading access via R/W bit = ‘1’
2
R/W
CPHA
4-WIRE interface clock phase (see Table 10)
1
R/W
CPOL
0
R/W
nCS_POL
0: nCS is low active
1: nCS is high active
Bit
Type
Label
Description
IF_TYPE
0: Power manager interface is 4-WIRE. Automatically
configures GPIO3 and GPI4 as interface signals. The
GPIO configuration is overruled.
4-WIRE interface clock polarity
0: SK is low during idle
1: SK is high during idle
4-WIRE chip select polarity
Register
0x106
INTERFACE2
7
R/W
1: Power manager interface is 2-WIRE
8.2.4.2
6
R/W
PM_IF_HSM
Enables continuous high speed mode on 2-WIRE
interface if asserted (no master code required)
5
R/W
PM_IF_FMP
Enables 2-WIRE interface operating with fast mode+
timings if asserted
4
R/W
PM_IF_V
0:3
R/W
(reserved)
0: Power manager interface in 2-WIRE mode is
supplied from VDDCORE (4-WIRE always from VDDIO)
1: Power manager interface in 2-WIRE mode is
supplied from VDDIO (4-WIRE always from VDDIO)
OTP Fusing Registers
Register
Bit
Type
Label
Description
0x140
OTP_CONT2
7
6
R/W
R/W
OTP_CONF_LOC
K
OTP_APPS_LOC
K
0: Registers 0x54 to 0x5E and 0xD0 to 0xDA are not
locked for OTP programming (should be selected for
unmarked evaluation samples)
1: Registers 0x54 to 0x5E and 0xD0 to 0xDA are locked
in OTP (no further fusing possible)
0: Registers 0x105, 0x106, 0x143 to 0x149 are not
locked for OTP programming (should be selected for
unmarked evaluation samples)
1: Registers 0x105, 0x106, 0x143 to 0x149 are locked
in OTP (no further fusing possible)
5:0
R/W
(reserved)
Bit
Type
Label
Description
7:0
R/W
OTP_ADDR
OTP Array address
Register
Bit
Type
Label
Description
0x142
7:0
R/W
OTP_DATA
OTP read/write data
Register
0x141
OTP_ADDR
Datasheet
CFR0011-120-00
Revision 1.4
53 of 62
08-May-2017
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DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
Register
Bit
Type
Label
Description
OTP_DATA
8.2.4.3
OTP_DATA written to OTP_ADDR selects the IC and
accepts unlock sequence (1 + 3 bytes)
Application Configuration Settings
Register
Bit
Type
Label
0x143
CONFIG_A
7:5
R/W
(reserved)
4
R/W
2WIRE_TO
3
R/W
GPI_V
Description
Enables automatic reset of 2-WIRE interface if the clock
stays low for >35 ms
0: Disabled
1: Enabled
GPIs are supplied from:
0: VDDCORE
1: VDDIO
2
R/W
(reserved)
1
R/W
IRQ_TYPE
0
R/W
IRQ_LEVEL
nIRQ output port is:
0: Push-pull
1: Open drain (requires external pull-up resistor)
nIRQ output port is:
0: Active low
1: Active high
Register
Bit
Type
Label
Description
7
R/W
UVLO_IO_DIS
Disable the UVLO for the VDDIO rail and its comparator
(suggested for rail voltages different to 1.8 V and to
save quiescent current)
PGB_DVC_MASK
Power-good configuration for Buck B
0: Power-good signal not masked during DVC
transitions
1: Power-good signal masked during DVC transitions
(keep previous status)
0x144
CONFIG_B
6
R/W
Power-good configuration for Buck A
5
R/W
PGA_DVC_MASK
0: Power-good signal not masked during DVC
transitions
1: Power-good signal masked during DVC transitions
(keep previous status)
Over Current configuration for Buck B
00: Event generation due to over current hit is always
active during DVC transitions of the Buck converter
4:3
R/W
OCB_MASK
01: Event generation due to over current hit is masked
during DVC transitions of the buck converter + 2 µs
extra masking at the end
10: Event generation due to over current hit is masked
during DVC transitions of the buck converter + 10 µs
extra masking at the end
11: Event generation due to over current hit is masked
during DVC transitions of the buck converter + 50 µs
extra masking at the end
2:1
Datasheet
CFR0011-120-00
R/W
OCA_MASK
Over Current configuration for Buck A
Revision 1.4
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DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
Register
Bit
Type
Label
Description
00: Event generation due to over current hit is always
active during DVC transitions of the buck converter
01: Event generation due to over current hit is masked
during DVC transitions of the buck converter + 2 µs
extra masking at the end
10: Event generation due to over current hit is masked
during DVC transitions of the buck converter + 10 µs
extra masking at the end
11: Event generation due to over current hit is masked
during DVC transitions of the buck converter + 50 µs
extra masking at the end
0
R/W
RELOAD_FUNC_
EN
Enable the OTP re-load function for GPIO0 when
configured as input port
Register
Bit
Type
Label
Description
0x145
CONFIG_C
7:5
R/W
(reserved)
4
R/W
GPI4_PUPD
3
R/W
0: GPI: pull-down resistor disabled
1: GPI: pull-down resistor enabled
GPIO3_PUPD
0: GPI: pull-down resistor disabled
GPO (open drain): pull up resistor disabled (external
pull-up resistor)
1: GPI: pull-down resistor enabled
GPO (open drain): pull up resistor
2
R/W
GPIO2_PUPD
0: GPI: pull-down resistor disabled
GPO (open drain): pull up resistor disabled (external
pull-up resistor)
1: GPI: pull-down resistor enabled
GPO (open drain): pull up resistor enabled
Register
1
R/W
GPI1_PUPD
0: GPI: pull-down resistor disabled
1: GPI: pull-down resistor enabled
0
R/W
GPI0_PUPD
0: GPI: pull-down resistor disabled
1: GPI: pull-down resistor enabled
Bit
Type
Label
Description
0x146
CONFIG_D
Selection of the PG signal for Buck B
00: none
7:6
R/W
BUCKB_PG_SEL
01: GPO2
10: GPO3
11: reserved
Selection of the PG signal for Buck A
5:4
R/W
BUCKA_PG_SEL
00: none
01: GPO2
10: GPO3
11: reserved
Selection of the READY signal for Buck B
3:2
R/W
READYB_CONF
00: none
01: GPO2
10: GPO3
Datasheet
CFR0011-120-00
Revision 1.4
55 of 62
08-May-2017
© 2017 Dialog Semiconductor
DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
Register
Bit
Type
Label
Description
11: reserved
Selection of the READY signal for Buck A
00: none
1:0
R/W
READYA_CONF
01: GPO2
10: GPO3
11: reserved
Register
Bit
Type
Label
Description
0: DA9213-A and DA9214-A is used as companion IC
to DA9063 or DA9063-compliant
1: DA9213-A and DA9214-A is stand alone or as
companion IC with another PMU not DA9063-compliant
0x147
CONFIG_E
7
R/W
STAND_ALONE
6:5
R/W
(reserved)
4:3
R/W
(reserved)
Tune the main 6 MHz oscillator frequency:
000: no tune
001: +180 kHz
010: +360 kHz
2:0
R/W
OSC_TUNE
011: +540 kHz
100: +720 kHz
101: +900 kHz
110: +1080 kHz
111: +1260 kHz
Register
Bit
Type
Label
Description
2
0x148
If a second I C address is to be selected on
ADR_SEL_CONF, this field configures the second
address.
CONFIG_F
4 MSB of 2-WIRE control interfaces base address
XXXX0000
11010000 = 0xD0 write address of PM 2-WIRE
interface (page 0 and 1)
7:4
R/W
IF_BASE_ADDR2
11010001 = 0xD1 read address of PM 2-WIRE
interface (page 0 and 1)
11010010 = 0xD2 write address of PM-2-WIRE
interface (page 2 and 3)
11010011 = 0xD3 read address of PM-2-WIRE
interface (page 2 and 3)
Code ‘0000’ is reserved for unprogrammed OTP
(triggers start-up with hardware default interface
address)
3:2
R
(reserved)
2
1
R/W
ADDR_SEL_CON
F
Selects the GPI for the alternative I C address
selection:
00: none
01: GPI0
10: GPI1
11: GPI4
Datasheet
CFR0011-120-00
Revision 1.4
56 of 62
08-May-2017
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DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
9
Application Information
The following recommended components are examples selected from requirements of a typical
application.
9.1
Capacitor Selection
Ceramic capacitors are used as bypass capacitors at all VDD and output rails. When selecting a
capacitor, especially for types with high capacitance at smallest physical dimension, the DC bias
characteristic has to be taken into account.
Table 14: Recommended Capacitor Types
Application
VOUT
output
bypass
Value
Size
Temp Char
Tol
V-Rate
Type
47 uF
1210
X7R +/-15 %
+/-10 %
6.3 V
Murata
GCM32ER70J476KE19
22 uF
1206
X7R +/-15 %
+/-10 %
6.3 V
Murata
GCM31CR70J226KE23
10 uF
0805
X7R +/-15 %
+/-10 %
6.3 V
Murata
GCM21BR70J106KE22
VDDx
bypass
10 uF
0805
X7R +/-15 %
+/-10 %
10 V
Murata
GCM21BR71A106KE22
VSYS
bypass
1 uF
0603
X7R +/-15 %
+/-10 %
16 V
Murata
GCM188R71C105KA64
VDDIO
bypass
100 nF
0402
X7R +/-15 %
+/-10 %
50 V
Murata
GCM155R71H104KE02
Datasheet
CFR0011-120-00
Revision 1.4
57 of 62
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© 2017 Dialog Semiconductor
DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
9.2
Inductor Selection
Inductors should be selected based upon the following parameters:
● Rated max. current: usually a coil provides two current limits: The Isat specifies the maximum
current at which the inductance drops by 30% of the nominal value. The Imax is defined by the
maximum power dissipation and is applied to the effective current.
● DC resistance: critical for the converter efficiency and should therefore be minimized.
Table 15: Recommended Inductor Types
Application
BUCK
Datasheet
CFR0011-120-00
Value
Size
Imax(dc)
Isat
Tol
DC res
Type
0.22 uH
2.5 mm x
2.0 mm x
1.0 mm
7.1 A
8.0 A
+/-20%
12 mΩ
TDK
TFM252010ALMAR22MT
AA
0.22 uH
2.5 mm x
2.0 mm x
1.2 mm
8.5 A
10 A
+/-20%
8 mΩ
TDK
TFM252012ALMAR22MT
AA
0.24 uH
2.0 mm x
1.6 mm x
1.0 mm
7.0 A
7.5 A
+/-20%
15 mΩ
TDK
TFM201610ALMAR24MT
AA
0.24 uH
2.0 mm x
1.6 mm x
1.2 mm
4.8 A
5.9 A
+/-20%
16 mΩ
TOKO DFE201612PDR24M
0.47 uH
2.5 mm x
2.0 mm x
1.0 mm
5.4 A
6.5 A
+/-20%
20 mΩ
TDK
TFM252010ALMAR47MT
AA
0.47 uH
2.5 mm x
2.0 mm x
1.2 mm
5.6 A
6.5 A
+/-20%
19 mΩ
TDK
TFM252012ALMAR47MT
AA
0.47 uH
2.5 mm x
2.0 mm x
1.2 mm
4.7 A
6.1 A
+/-20%
21 mΩ
TOKO DFE252012PDR47M
0.47 uH
2.0 mm x
1.6 mm x
1.0 mm
5.0 A
5.8 A
+/-20%
28 mΩ
TDK
TFM201610ALMAR47MT
AA
0.47 uH
2.0 mm x
1.6 mm x
1.2 mm
3.8 A
4.5 A
+/-20%
26 mΩ
TOKO DFE201612PDR47M
0.24 uH
2.0 mm x
1.6 mm x
1.2 mm
5.0 A
7.7 A
+/-20%
16 mΩ
Taiyo Yuden
MEMK2016TR24MV
0.47 uH
2.0 mm x
1.6 mm x
1.2 mm
3.8 A
5.5 A
+/-20%
28 mΩ
Taiyo Yuden
MEMK2016TR47MV
0.24 uH
2.5 mm x
2.0 mm x
1.2 mm
5.9 A
8.5 A
+/-20%
13 mΩ
Taiyo Yuden
MEMK2520TR24MV
0.47 uH
2.5 mm x
2.0 mm x
1.2 mm
4.7 A
6.2 A
+/-20%
21 mΩ
Taiyo Yuden
MEMK2520TR47MV
Revision 1.4
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DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
10 Package Information
10.1 Package Outlines
Figure 28: DA9213-A/14-A VFBGA Package Outline Drawing
Datasheet
CFR0011-120-00
Revision 1.4
59 of 62
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© 2017 Dialog Semiconductor
DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
11 Ordering Information
The ordering number consists of the part number followed by a suffix indicating the packing method.
For details and availability, please consult Dialog Semiconductor’s customer portal or your local sales
representative.
Table 16: Ordering Information
Part Number
Package
Package
Description
Comment
Package
Outline
DA9213-xxFS1-A
66 VFBGA
Tray
Auto Grade 2
Figure 28
DA9213-xxFS2-A
66 VFBGA
T&R, 5000pcs
Auto Grade 2
DA9214-xxFS1-A
66 VFBGA
Tray
Auto Grade 2
DA9214-xxFS2-A
66 VFBGA
T&R, 5000pcs
Auto Grade 2
DA9213-xxFS1-AT
66 VFBGA
Tray
Auto Grade 2
with HighTemp screening
DA9213-xxFS2-AT
66 VFBGA
T&R, 5000pcs
Auto Grade 2
with HighTemp screening
DA9214-xxFS1-AT
66 VFBGA
Tray
Auto Grade 2
with HighTemp screening
DA9214-xxFS2-AT
66 VFBGA
T&R, 5000pcs
Auto Grade 2
with HighTemp screening
Datasheet
CFR0011-120-00
Revision 1.4
60 of 62
Figure 28
08-May-2017
© 2017 Dialog Semiconductor
DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
Revision History
Revision
Date
Description
1.0
17-Nov-2016
Initial version.
1.1
10-Feb-2017
Updated specifications.
1.2
22-Feb-2017
Updated ordering information table and UVLO @VDDIO spec.
1.3
24-Mar-2017
Updated power dissipation spec. Added automotive disclamer. Added
Tj_max. Added applications info.
1.4
08-May-2017
Updated power dissipation spec. Added Theta-JA and power derating
curve.
Status Definitions
Revision
Datasheet Status
Product Status
Definition
1.<n>
Target
Development
This datasheet contains the design specifications for product
development. Specifications may be changed in any manner without
notice.
2.<n>
Preliminary
Qualification
This datasheet contains the specifications and preliminary
characterization data for products in pre-production. Specifications
may be changed at any time without notice in order to improve the
design.
3.<n>
Final
Production
This datasheet contains the final specifications for products in
volume production. The specifications may be changed at any time
in order to improve the design, manufacturing and supply. Major
specification changes are communicated via Customer Product
Notifications. Datasheet changes are communicated via
www.dialog-semiconductor.com.
4.<n>
Obsolete
Archived
This datasheet contains the specifications for discontinued products.
The information is provided for reference only.
Datasheet
CFR0011-120-00
Revision 1.4
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© 2017 Dialog Semiconductor
DA9213-A and DA9214-A
Auto Grade Multi-Phase 5A/Phase Buck Converter
Disclaimer
Suitability for use in automotive applications — This Dialog Semiconductor product has been qualified for use in automotive
applications. Unless otherwise agreed in writing, the product is not designed, authorized or warranted to be suitable for use in
life support, life-critical or safety-critical systems or equipment, nor in applications where failure or malfunction of an Dialog
Semiconductor product can reasonably be expected to result in personal injury, death or severe property or environmental
damage. Dialog Semiconductor and its suppliers accept no liability for inclusion and/or use of Dialog Semiconductor products
in such equipment or applications and therefore such inclusion and/or use is at the customer's own risk.
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Datasheet
CFR0011-120-00
Revision 1.4
62 of 62
08-May-2017
© 2017 Dialog Semiconductor