TI1 BQ51025YFPR Compliant single chip wireless power receiver Datasheet

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bq51025
SLUSBX7B – SEPTEMBER 2014 – REVISED MARCH 2015
bq51025 WPC v1.1 Compliant Single Chip Wireless Power Receiver
With Proprietary 10-W Power Delivery
1 Features
3 Description
•
The bq51025 device is a fully-contained wireless
power receiver capable of operating in the Wireless
Power Consortium (WPC) Qi protocol, which allows a
wireless power system to deliver 5 W to the system
with Qi inductive transmitters and up to 10 W when
operating with the bq500215 primary-side controller.
The bq51025 device provides a single device power
conversion (rectification and regulation) as well as the
digital control and communication as per WPC v1.1
specification. With market-leading 84% system
efficiency and adjustable output voltage, the bq51025
device allows for unparalleled system optimization.
With a maximum output voltage of 10 V, the bq51025
offers a flexible solution that offers a wireless power
solution for 2S battery application and allows optimal
thermal performance of the system. The I2C interface
allows system designers to implement new features
such as aligning a receiver on the transmitter surface
or detecting foreign objects on the receiver. The
bq51025 device complies with the WPC v1.1
communication protocol making it compatible with all
WPC transmitter solutions. The receiver allows for
synchronous rectification, regulation and control, and
communication to all exist in a market-leading form
factor, efficiency, and solution size.
1
•
•
•
•
Robust 10-W Receiver Solution Using Proprietary
Protocol With TI's 10-W bq500215 Transmitter
– Post-Regulation LDO to Protect External
Charger Input from Rectifier Output Transients;
Inductorless Solution for Lowest Height
– Adjustable Output Voltage (4.5 to 10 V) for
Coil and Thermal Optimization
– Supports 2S Battery Configuration (Non-WPC
compliant)
– Fully Synchronous Rectifier With 96%
Efficiency
– 97% Efficient Post Regulator
– 84% System Efficiency at 10 W
WPC v1.1 Compliant Communication and Control
for Compatibility With Current TX Solutions
Patented Transmitter Pad Detect Function
Improves User Experience
Power Signal Frequency Measurement Allows
Host to Determine Optimal Placement on TX
Surface
I2C Communication With Host
Device Information(1)
2 Applications
•
•
•
•
•
PART NUMBER
Smart Phones, Tablets, and Headsets
Point-of-Sale Devices
2S Battery Applications
Power Banks
Other Portable Devices
PACKAGE
bq51025
DSBGA (42)
BODY SIZE (NOM)
3.60 mm × 2.89 mm
(1) For all available packages, see the orderable addendum at
the end of the data sheet.
4 Simplified Schematic
bq51025
System
Load
AD-EN
AD
OUT
CCOMM1
C4
COMM1
CBOOT1
BOOT1
C3
AC1
100%
90%
80%
70%
HOST
TS/CTRL
COMM2
NTC
TMEM
CLAMP2
C5
CLAMP1
RMEM
Efficiency
VIREG
BOOT2
CCOMM2
CCLAMP1
R8
R9
AC2
CCLAMP2
RECT
R6
VO_REG
C2
CBOOT2
R7
RECT
C1
COIL
bq51025 System Efficiency With bq500215 TX
Controller
60%
50%
40%
WPG
PD_DET
30%
PMODE
SCL
20%
CM_ILIM
SDA
ILIM
FOD
PGND
VOUT = 10V
VOUT = 7V
VOUT = 5V
10%
0
R1
RFOD
0
1
2
3
4
5
6
Output Power (W)
7
8
9
10
D001
1
An IMPORTANT NOTICE at the end of this data sheet addresses availability, warranty, changes, use in safety-critical applications,
intellectual property matters and other important disclaimers. PRODUCTION DATA.
bq51025
SLUSBX7B – SEPTEMBER 2014 – REVISED MARCH 2015
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Table of Contents
1
2
3
4
5
6
7
8
9
Features ..................................................................
Applications ...........................................................
Description .............................................................
Simplified Schematic.............................................
Revision History.....................................................
Device Comparison Table.....................................
Pin Configuration and Functions .........................
Specifications.........................................................
1
1
1
1
2
3
3
5
8.1
8.2
8.3
8.4
8.5
8.6
5
5
5
5
6
8
Absolute Maximum Ratings ......................................
ESD Ratings..............................................................
Recommended Operating Conditions.......................
Thermal Information ..................................................
Electrical Characteristics...........................................
Typical Characteristics ..............................................
Detailed Description .............................................. 9
9.1 Overview ................................................................... 9
9.2
9.3
9.4
9.5
Functional Block Diagram .......................................
Feature Description.................................................
Device Functional Modes........................................
Register Maps .........................................................
11
12
18
21
10 Application and Implementation........................ 27
10.1 Application Information.......................................... 27
10.2 Typical Applications .............................................. 27
11 Power Supply Recommendations ..................... 39
12 Layout................................................................... 40
12.1 Layout Guidelines ................................................. 40
12.2 Layout Example .................................................... 40
13 Device and Documentation Support ................. 41
13.1 Trademarks ........................................................... 41
13.2 Electrostatic Discharge Caution ............................ 41
13.3 Glossary ................................................................ 41
14 Mechanical, Packaging, and Orderable
Information ........................................................... 41
5 Revision History
NOTE: Page numbers for previous revisions may differ from page numbers in the current version.
Changes from Revision A (September 2014) to Revision B
Page
•
Updated Features and Description to include 2S support ..................................................................................................... 1
•
Added 2S Battery Application to Applications ....................................................................................................................... 1
•
Corrected RILIM threshold for EPT 0x02 to match Electrical Characteristics ........................................................................ 15
•
Corrected section numbering for TMEM ............................................................................................................................. 29
•
Added design example section for Standalone 10-V Power Supply for 2S Charging System............................................. 35
Changes from Original (September 2014) to Revision A
•
2
Page
Updated device status from product preview to production .................................................................................................. 1
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SLUSBX7B – SEPTEMBER 2014 – REVISED MARCH 2015
6 Device Comparison Table
Device
Mode
bq51221
Dual (WPC v1.1, PMA)
More
bq51020
WPC v1.1
bq51025
WPC v1.1, Proprietary 10 W
Autonomous mode detection, I2C control, adjustable output voltage
Stand-alone solution, adjustable output voltage, highest system efficiency
I2C control, adjustable output voltage, 10-W maximum output power
7 Pin Configuration and Functions
YFP Package
42-Pin DSBGA
(Top View)
A1
PGND
A2
PGND
A3
PGND
A4
PGND
A5
PGND
A6
PGND
B1
AC1
B2
AC1
B3
AC1
B4
AC2
B5
AC2
B6
AC2
C1
BOOT1
C2
RECT
C3
RECT
C4
RECT
C5
RECT
C6
BOOT2
D1
OUT
D2
OUT
D3
OUT
D4
OUT
D5
OUT
D6
OUT
E1
CLMP1
E2
AD
E3
AD_EN
E4
SCL
E5
VIREG
E6
CLMP2
F1
COMM1
F2
FOD
F3
PMODE
F4
SDA
F5
WPG
F6
COMM2
G1
VO_REG
G2
ILIM
G3
CM_ILIM
G4
TS/CTRL
G5
TMEM
G6
PD_DET
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Pin Functions
PIN
NAME
NO.
TYPE
DESCRIPTION
B1
AC1
B2
I
B3
AC input power from receiver resonant tank
B4
AC2
B5
I
B6
AD
E2
I
Adapter sense pin
AD-EN
E3
O
Push-pull driver for dual PFET circuit that can pass AD input to the OUT pin; used for adapter MUX control
BOOT1
C1
O
BOOT2
C6
O
CLAMP1
E1
O
CLAMP2
E6
O
COMM1
F1
O
COMM2
F6
O
CM_ILIM
G3
I
Enables communication current limit when pulled low or left floating.
FOD
F2
I
Input that is used for scaling the received power message
ILIM
G2
I/O
Output current or overcurrent level programming pin
O
Output pin, used to deliver power to the load
O
Open-drain output that allows user to sense when receiver is on transmitter
—
Power and logic ground
O
Filter capacitor for the internal synchronous rectifier
Bootstrap capacitors for driving the high-side FETs of the synchronous rectifier
Open-drain FETs used to clamp the secondary voltage by providing low impedance across secondary
Open-drain FETs used to communicate with primary by varying reflected impedance
D1
D2
D3
OUT
D4
D5
D6
PD_DET
G6
A1
A2
A3
PGND
A4
A5
A6
C2
C3
RECT
C4
C5
SCL
E4
I
SDA
F4
I/O
PMODE
F3
O
Indicates receiver mode of operation: Low = Proprietary 10-W mode, High = Low-power mode. Gate drive
output for external current limit switch. Connect 5-MΩ resistor to ground. Leave floating if unused.
TMEM
G5
O
TMEM allows the capacitor to be connected to GND so energy from transmitter ping can be stored to retain
memory of state.
TS/CTRL
G4
I
Temperature sense. Can be pulled high to send end power transfer (EPT) – charge complete to TX. Can be
pulled low to send EPT – over temperature
VO_REG
G1
I
Sets the regulation voltage for output. Default value is 0.5 V.
VIREG
E5
I
Rectifier voltage feedback
WPG
F5
O
Open-drain output that allows user to sense when power is transferred to load
4
SCL and SDA are used for I2C communication. Connect to ground if not needed.
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8 Specifications
8.1 Absolute Maximum Ratings
over operating free-air temperature (unless otherwise noted) (1)
Input voltage
(2)
MIN
MAX
AC1, AC2
–0.8
20
RECT, COMM1, COMM2, OUT, CLAMP1, CLAMP2, WPG, PD_DET
–0.3
20
AD, AD-EN
–0.3
30
BOOT1, BOOT2
–0.3
20
7
UNIT
V
SCL, SDA, PMODE, CM_ILIM, FOD, TS/CTRL, ILIM, TMEM, VIREG, VO_REG
–0.3
Input current
AC1, AC2 (RMS)
2.5
A
Output current
OUT
2.5
A
Output sink current
WPG, PD_DET
15
mA
Output sink current
COMM1, COMM2
1
TJ
Junction temperature
–40
150
°C
Tstg
Storage temperature
–65
150
°C
(1)
(2)
A
All voltages are with respect to the PGND pin, unless otherwise noted.
Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. These are stress ratings
only, and functional operation of the device at these or any other conditions beyond those indicated under Recommended Operating
Conditions is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
8.2 ESD Ratings
VALUE
V(ESD)
(1)
(2)
Electrostatic discharge
Human body model (HBM) 100 pF, 1.5 kΩ
(1)
UNIT
±2000
Charged device model (CDM) (2)
V
±500
JEDEC document JEP155 states that 500-V HBM allows safe manufacturing with a standard ESD control process.
JEDEC document JEP157 states that 250-V CDM allows safe manufacturing with a standard ESD control process.
8.3 Recommended Operating Conditions
over operating free-air temperature range (unless otherwise noted)
VRECT
RECT voltage range
IOUT
Output current
IAD-EN
Sink current
ICOMM
COMMx sink current
TJ
Junction temperature
MIN
MAX
4
11
2.0
0
UNIT
V
A
1
mA
500
mA
125
ºC
8.4 Thermal Information
THERMAL METRIC (1)
YFP (DSBGA)
42 Pins
RθJA
Junction-to-ambient thermal resistance
49.7
RθJC(top)
Junction-to-case (top) thermal resistance
0.2
RθJB
Junction-to-board thermal resistance
6.1
ψJT
Junction-to-top characterization parameter
1.4
ψJB
Junction-to-board characterization parameter
6.0
(1)
UNIT
°C/W
For more information about traditional and new thermal metrics, see the IC Package Thermal Metrics application report, SPRA953.
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8.5 Electrical Characteristics
over operating free-air temperature range (unless otherwise noted) , ILOAD = IOUT
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
2.9
VUVLO
Undervoltage lockout
VRECT: 0 to 3 V
2.8
VHYS-UVLO
Hysteresis on UVLO
VRECT: 3 to 2 V
393
VRECT-OVP
Input overvoltage threshold
VRECT: 5 to 16 V
VHYS-OVP
Hysteresis on OVP
VRECT: 16 to 5 V
VRECT(REG)
Voltage at RECT pin set by
communication with primary
VRECT(TRACK)
VRECT regulation above VOUT
ILOAD-HYS
ILOAD hysteresis for dynamic
I
falling
VRECT thresholds as a % of IILIM LOAD
VRECT-DPM
Rectifier undervoltage
protection, restricts IOUT at
VRECT-DPM
VRECT-REV
Rectifier reverse voltage
protection with a supply at the
output
14.6
15.1
VILIM = 1.2 V
V
mV
15.6
1.5
V
V
Lower of VOUT +
0.2 or 11.0
VOUT + 0.120
UNIT
140
V
mV
4%
3
3.1
3.2
V
VRECT-REV = VOUT – VRECT,
VOUT = 10 V
8.8
9.2
V
VOUT ≤ 5 V, 0°C ≤ TJ ≤ 85°C
20
35
µA
215
230
Ω
QUIESCENT CURRENT
IOUT(standby)
Quiescent current at the output
when wireless power is
disabled
ILIM SHORT CIRCUIT
RILIM-SHORT
Highest value of RILIM resistor
considered a fault (short).
Monitored for IOUT > 100 mA
tDGL-Short
Deglitch time transition from
ILIM short to IOUT disable
ILIM_SC
ILIM-SHORT,OK enables the ILIM
short comparator when IOUT is
greater than this value
ILOAD: 0 to 200 mA
ILIM-SHORT,OK
Hysteresis for ILIM-SHORT,OK
comparator
ILOAD: 200 to 0 mA
20
mA
HYSTERESIS
IOUT-CL
Maximum output current limit
Maximum ILOAD that can be
delivered for 1 ms when ILIM is
shorted
3.7
A
RILIM: 200 to 50 Ω. IOUT latches
off, cycle power to reset
1
110
125
ms
140
mA
OUTPUT
VO_REG
Feedback voltage set point
KILIM
Current programming factor for
hardware short circuit
protection
IOUT_RANGE
Current limit programming
range
ICOMM
Output current limit during
communication
ILOAD = 2000 mA, VO_REG resistor
divider ratio = 9:1
0.4968
0.5019
0.5077
ILOAD = 1 mA, VO_REG resistor
divider ratio = 9:1
0.4971
0.5017
0.5079
ILOAD = 1000 mA, VO_REG resistor
divider ratio = 19:1
0.4977
0.5027
0.5091
ILOAD = 1 mA, VO_REG resistor
divider ratio = 19:1
0.4978
0.5029
0.5098
RILIM = KILIM / IILIM, where IILIM is
the hardware current limit
IOUT = 900 mA
6
842
AΩ
2300
IOUT ≥ 400 mA
IOUT – 50
100 mA ≤ IOUT < 400 mA
IOUT + 50
IOUT < 100 mA
tHOLD-OFF
V
Hold off time for the
communication current limit
during startup
mA
200
1
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Electrical Characteristics (continued)
over operating free-air temperature range (unless otherwise noted) , ILOAD = IOUT
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
TS/CTRL
VTS-Bias
TS bias voltage (internal)
ITS-Bias < 100 µA and
communication is active
(periodically driven, see tTS/CTRLMeas)
VCTRL-HI
CTRL pin threshold for a high
VTS/CTRL: 50 to 150 mV
TTS/CTRL-Meas
Time period of TS/CTRL
measurements, when TS is
being driven
TS bias voltage is only driven
when power packets are sent
VTS-HOT
Voltage at TS pin when device
shuts down
1.8
90
105
V
120
mV
1700
ms
0.38
V
155
°C
20
°C
THERMAL PROTECTION
TJ(OFF)
Thermal shutdown temperature
TJ(OFF-HYS)
Thermal shutdown hysteresis
OUTPUT LOGIC LEVELS ON WPG
VOL
Open-drain WPG pin
ISINK = 5 mA
550
mV
IOFF,STAT
WPG leakage current when
disabled
VWPG = 20 V
1
µA
COMM PIN
RDS-ON(COMM) COMM1 and COMM2
ƒCOMM
Signaling frequency on COMMx
pin for WPC
IOFF,COMM
COMMx pin leakage current
VRECT = 2.6 V
Ω
1
2.00
VCOMM1 = 20 V, VCOMM2 = 20 V
Kb/s
1
µA
CLAMP PIN
RDS-
CLAMP1 and CLAMP2
Ω
0.5
ON(CLAMP)
ADAPTER ENABLE
VAD-EN
VAD rising threshold voltage
VAD 0 V to 5 V
VAD-EN-HYS
VAD-EN hysteresis
VAD 5 V to 0 V
IAD
Input leakage current
VRECT = 0 V, VAD = 5 V
RAD_EN-OUT
Pullup resistance from AD-EN
to OUT when adapter mode is
disabled and VOUT > VAD
VAD = 0 V, VOUT = 5 V
VAD_EN-ON
Voltage difference between VAD VAD = 5 V, 0°C ≤ TJ ≤ 85°C
and VAD-EN when adapter mode
VAD = 9 V, 0°C ≤ TJ ≤ 85°C
is enabled
3.5
3.6
3.8
450
V
mV
50
μA
230
350
Ω
4
4.5
5
V
3
6
7
V
SYNCHRONOUS RECTIFIER
ISYNC-EN
IOUT at which the synchronous
rectifier enters half
synchronous mode
IOUT: 200 to 0 mA
100
mA
ISYNC-EN-HYST
Hysteresis for IOUT,RECT-EN (fullIOUT: 0 to 200 mA
synchronous mode enabled)
40
mA
VHS-DIODE
High-side diode drop when the
rectifier is in half synchronous
mode
IAC-VRECT = 250 mA, and
TJ = 25°C
0.7
V
VIL
Input low threshold level SDA
V(PULLUP) = 1.8 V, SDA
VIH
Input high threshold level SDA
V(PULLUP) = 1.8 V, SDA
VIL
Input low threshold level SCL
V(PULLUP) = 1.8 V, SCL
VIH
Input high threshold level SCL
V(PULLUP) = 1.8 V, SCL
I2C
2
I C speed
Typical
0.4
1.4
V
0.4
1.4
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V
V
100
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V
kHz
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8.6 Typical Characteristics
0.506
855
0.505
852.5
850
0.504
0.503
KILIM (A:)
VO_REG (V
847.5
0.502
0.501
845
842.5
840
837.5
0.5
835
0.499
832.5
830
0.498
0
0.2
0.4
0.6
0.8
1
1.2
1.4
1.6
1.8
IOUT (A)
0
2
200
400
600
D002
800 1000 1200 1400 1600 1800 2000
ILOAD (mA)
D003
Temperature =
25°C
Figure 2. KILIM as a Function of Load Current
Figure 1. Output Regulation as a Function of Load
2.815
0.85
2.8125
0.8
2.81
2.8075
0.75
VO_REG (V)
VUVLO (V)
2.805
2.8025
2.8
2.7975
0.7
0.65
0.6
2.795
2.7925
0.55
2.79
2.785
-40
IOUT = 1mA
IOUT = 1A
0.5
2.7875
0.45
-20
0
20
40
60
Temperature (qC)
80
100
120
0
1
2
3
4
I2C Code
D004
Figure 3. UVLO as a Function of Junction Temperature
5
6
7
D005
Figure 4. VO_REG by Different I2C Codes, Resistor Divider
Ratio = 9:1
0.505
0.5
0.495
VO_REG (V)
0.49
0.485
0.48
0.475
0.47
0.465
0.46
IOUT = 1mA
IOUT = 1A
0.455
0.45
0
I2C Code
1
D006
Figure 5. VO_REG by Different I2C Codes, Resistor Divider Ratio = 19:1
8
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SLUSBX7B – SEPTEMBER 2014 – REVISED MARCH 2015
9 Detailed Description
9.1 Overview
WPC-based wireless power systems consist of a charging pad (primary, transmitter) and the secondary-side
equipment (receiver). The coils in the charging pad and secondary equipment magnetically couple to each other
when the receiver is placed on the transmitter. Power is transferred from the primary to the secondary by
transformer action between the coils. The receiver can achieve control over the amount of power transferred by
getting the transmitter to change the field strength by changing the frequency, duty cycle, or voltage rail
energizing the primary coil.
The receiver equipment communicates with the primary by modulating the load seen by the primary. This load
modulation results in a change in the primary coil current or primary coil voltage, or both, which is measured and
demodulated by the transmitter.
In WPC, the system communication is digital (packets that are transferred from the secondary to the primary).
Differential biphase encoding is used for the packets. The bit rate is 2 kb/s. Various types of communication
packets are defined. These include identification and authentication packets, error packets, control packets,
power usage packets, and end power transfer packets, among others.
The bq51025 incorporates a two-way proprietary authentication with the bq500215 primary controller that allows
optimal power transfer and system performance up to 10-W output power while still complying with WPC v1.1
specifications.
Figure 6. Wireless Power System Indicating the Functional Integration of the bq51025
The bq51025 device integrates fully-compliant WPC v1.1 communication protocol to streamline the wireless
power receiver designs (no extra software development required). Other unique algorithms such as Dynamic
Rectifier Control are integrated to provide best-in-class system efficiency while keeping the smallest solution size
of the industry.
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Overview (continued)
As a WPC system, when the receiver (shown in Figure 6) is placed on the charging pad, the secondary coil
couples to the magnetic flux generated by the coil in the transmitter, which consequently induces a voltage in the
secondary coil. The internal synchronous rectifier feeds this voltage to the RECT pin, which in turn feeds the
LDO which feeds the output.
The bq51025 device identifies and authenticates itself to the primary using the COMMx pins, switching on and off
the COMM FETs, and hence, switching in and out COMM capacitors. If the authentication is successful, the
primary remains powered-up. Using a proprietary authentication protocol, the bq51025 determines if the 10-W
bq500215 primary controller is powering the device, in which case the bq51025 device allows operation up to 10W. If the bq51025 determines that a standard WPC-compliant transmitter is powering it, it allows operation up to
5-W. The bq51025 device measures the voltage at the RECT pin, calculates the difference between the actual
voltage and the desired voltage VRECT(REG) and sends back error packets to the transmitter. This process goes on
until the input voltage settles at VRECT(REG) MAX. During a load change, the dynamic rectifier algorithm sets the
target voltage between VRECT(REG) MAX and VRECT(REG) MIN, as shown in Table 1. This algorithm enhances the
transient response of the power supply.
After the voltage at the RECT pin is at the desired value, the pass FET is enabled. The voltage control loop
ensures that the output voltage is maintained at VOUT(REG), powering the downstream charger. The bq51025
device meanwhile continues to monitor the input voltage, and keeps sending control error packets (CEP) to the
primary, on average, every 250 ms. If a large transient occurs, the feedback to the primary speeds up to 32-ms
communication periods to converge on an operating point in less time.
10
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9.2 Functional Block Diagram
,
OUT
VREF,ILIM
VILIM
+
_
VOUT,FB
VOUT,REG
+
_
RECT
VOREG
VREF,IABS
VIABS,FB
+
_
VIN,FB
VIN,DPM
+
_
ILIM
AD
+
_
VREFAD,OVP
BOOT2
+
_
BOOT1
VREFAD,UVLO
/AD-EN
AC1
AC2
Sync
Rectifier
Control
VIREG
TS
COMM1
COMM2
DATA_
OUT
ADC
CLAMP1
VBG,REF
VIN,FB
VOUT,FB
VILIM
VIABS,FB
TS/CTRL
VIABS,REF
VIC,TEMP
VFOD
CLAMP2
Digital Control
OVP
/WPG
+
_
VFOD
VRECT
VOVP,REF
SCL
FOD
SCL
/PD_DET
SDA
SDA
50uA
CM_ILIM
TMEM
5W_MODE
PMODE
PMODE
PGND
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9.3 Feature Description
9.3.1 Dynamic Rectifier Control
The Dynamic Rectifier Control algorithm offers the end-system designer optimal transient response for a given
maximum output current setting. This is achieved by providing enough voltage headroom across the internal
regulator (LDO) at light loads in order to maintain regulation during a load transient. The WPC system has a
relatively slow global feedback loop where it can take up to 150 ms to converge on a new rectifier voltage target.
Therefore, a transient response depends on the loosely-coupled transformer's output-impedance profile. The
Dynamic Rectifier Control allows for a 1.5-V change in rectified voltage before the transient response is observed
at the output of the internal regulator (output of the bq51025 device). A 1-A application allows up to a 2-Ω output
impedance. Figure 13 shows the Dynamic Rectifier Control behavior during active power transfer.
9.3.2 Dynamic Power Scaling
The Dynamic Power Scaling feature allows for the loss characteristics of the bq51025 device to be scaled based
on the maximum expected output power in the end application. This effectively optimizes the efficiency for each
application. This feature is achieved by scaling the loss of the internal LDO based on a percentage of the
maximum output current. Note that the maximum output current is set by the KILIM term and the RILIM resistance
(where RILIM = KILIM / IILIM). The flow diagram in Figure 13 shows how the rectifier is dynamically controlled
(Dynamic Rectifier Control) based on the voltage level at the ILIM pin (VILIM). This voltage represents a fixed
percentage of the IILIM setting. Table 1 summarizes how the rectifier behavior is dynamically adjusted based on
two different RILIM settings. Table 1 is shown for IMAX, which is the maximum operating output current and is
typically lower than IILIM (about 20% lower). See RILIM Calculations for more details on how to set IILIM.
Table 1. Dynamic Rectifier Regulation (1)
Output Current
Percentage
(Low-Power Mode)
(1)
(2)
Output Current
Percentage
(Proprietary Mode)
Low Power (5-W)
Mode
RILIM = 700 Ω
IILIM = 0.6 A
(IMAX = 0.5 A)
Low Power (5-W)
Mode
RILIM = 700 Ω
IILIM = 1.2 A
(IMAX = 1 A)
Proprietary 10-W
Mode
RILIM = 495 Ω
IILIM = 1.7 A
(IMAX = 1.4 A)
VRECT
(2)
0 to 10%
0 to 5%
0 to 0.05 A
0 to 0.05 A
0 to 0.070 A
VOUT + 2.0
10 to 20%
5 to 10%
0.05 to 0.1 A
0.05 to 0.1 A
0.070 to 0.14 A
VOUT + 1.6
20 to 40%
10 to 20%
0.1 to 0.2 A
0.1 to 0.2 A
0.14 to 0.28 A
VOUT + 0.6
>40%
>20%
>0.2 A
>0.2 A
>0.28 A
VOUT + 0.12
ROS = Open. The relation between VILIM and ILIM has some dependency on the ROS value.
VRECT is regulated to a maximum of 11 V.
Table 1 shows the shift in the Dynamic Rectifier Control behavior based on the two different RILIM settings. With
the rectifier voltage (VRECT) as the input to the internal LDO, this adjustment in the Dynamic Rectifier Control
thresholds dynamically adjusts the power dissipation across the LDO where,
PDIS
VRECT VOUT ˜ IOUT
(1)
Figure 22 shows how the Dynamic Power Scaling feature reduces the VRECT with increased load, allowing the
post-regulation LDO to have maximum headroom at low load conditions for better load transient performance
and minimal power dissipation at high loads. Note that this feature balances efficiency with optimal system
transient response.
9.3.3 VO_REG Calculations
The bq51025 device allows the designer to set the output voltage by setting a feedback resistor divider network
from the OUT pin to the VO_REG pin, as seen in Figure 7. Select the resistor divider network so that the voltage
at the VO_REG pin is 0.5 V (default setting) at the desired output voltage. The target VO_REG voltage can be
changed through I2C by changing Table 4
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OUT
R7
VO_REG
R6
Figure 7. VO_REG Network
Choose the desired output voltage VOUT and R6:
0.5 V
K VO
VOUT
R6
(2)
K VO u R7
1 K VO
(3)
9.3.4 RILIM Calculations
The bq51025 device includes a means of providing hardware overcurrent protection (IILIM) through an analog
current regulation loop. The hardware current limit provides an extra level of safety by clamping the maximum
allowable output current (for example, current compliance). The RILIM resistor size also sets the thresholds for the
dynamic rectifier levels providing efficiency tuning per each application’s maximum system current. The
calculation for the total RILIM resistance is as follows:
KILIM
RILIM
IILIM
(4)
51
5ILIM ± 5FOD
(5)
The RILIM allows for the ILIM pin to reach 1.2 V when operating in proprietary mode (up to 10-W output power)
when the output current is equal to IILIM. When the receiver operates in standard WPC low-power mode, the ILIM
pin voltage threshold is changed from 1.2 to 0.6 V, setting the low-power mode current limit to half of that at the
proprietary mode setting.
In the case where having the current limit change by a factor of two between modes is not desired, the two
current limit levels may be independently controlled in two ways:
• By programming the IO_REG level through I2C
• By changing the effective RILIM value for each mode by using an external switch controlled by the PMODE pin
To adjust the current limit for each mode through I2C, RILIM is chosen using Equation 4 where IILIM is the current
limit for proprietary mode (that is, higher current setting). The host should first set the desired current limit value
for low-power mode as a percentage of IILIM through the IO_REG bits and then disable the 2X current scaling by
setting the I2C_ILIM bit in Table 5 and Table 6 respectively to enable programmability. By default, IO_REG is set
to the highest current setting allowed by RILIM (that is, 100% of IILIM).
If I2C control is not available, the current limit for low power and proprietary modes can be set independently by
shorting a portion of the R1 resistance using an external switch as shown in Figure 8. RILIM is calculated using
Equation 4, where IILIM is the desired current limit for proprietary mode. The resistance to set the current limit in
low-power mode, RILIM_LP is calculated by Equation 6.
RILIM-LP
KILIM
2 u IILIM-LP
where IILIM_LP is the desired current limit value in low-power mode
(6)
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The value for R1_A is given by RILIM_LP – RFOD. The value of R1_B is then RILIM – R1_A – RFOD. Note that with this
method IILIM must be less than 2 × IILIM_LP
PMODE
FOD
ROS
RECT
ILIM
R1_A
R1_B
RFOD
Figure 8. Current Limit Setting for bq51025 Using External Switch
When choosing IILIM, consider the following two possible operating conditions:
• If the user's application requires an output current equal to or greater than the external IILIM that the circuit is
designed for (input current limit on the charger where the receiver device is tied higher than the external IILIM),
ensure that the downstream charger is capable of regulating the voltage of the input into which the receiver
device output is tied to by lowering the amount of current being drawn. This ensures that the receiver output
does not drop to zero. Such behavior is referred to as VIN DPM in TI chargers. Unless such behavior is
enabled on the charger, the charger pulls the output of the receiver device to ground when the receiver
device enters current regulation.
• If the user's applications are designed to extract less than the IILIM, typical designs should leave a design
margin of at least 10%, so that the voltage at ILIM pin reaches 1.2 V when 10% more than maximum current
is drawn from the output. Such a design would have input current limit on the charger lower than the external
ILIM of the receiver device.
However, in both cases, the charger must be capable of regulating the current drawn from the device to allow the
output voltage to stay at a reasonable value. This same behavior is also necessary during the WPC
communication. The following calculations show how such a design is achieved:
KILIM
RILIM
1.1 u IILIM
(7)
51
5ILIM ± 5FOD
where ILIM is the hardware current limit
(8)
When referring to the application diagram shown in Typical Applications, RILIM is the sum of the R1 and RFOD
resistance (that is, the total resistance from the ILIM pin to GND). RFOD is chosen according to the application. To
obtain the tool for calculating RFOD, contact your TI representative. Use RFOD to allow the receiver implementation
to comply with WPC v1.1 requirements related to received power accuracy.
9.3.5 Adapter Enable Functionality
The bq51025 device can also help manage the multiplexing of adapter power to the output and can shut off the
TX when the adapter is plugged in and is above the VAD-EN. After the adapter is plugged in and the output turns
off, the RX device sends an EPT to the TX. In this case, the AD_EN pins are then pulled to approximately 4 V
below AD, which allows the device to turn on the back-to-back PMOS connected between AD and OUT (see
Figure 32).
Both the AD and AD-EN pins are rated at 30 V, while the OUT pin is rated at 20 V. Note that it is required to
connect a back-to-back PMOS between AD and OUT so that voltage is blocked in both directions. Also, when
AD mode is enabled, no load can be pulled from the RECT pin because this could cause an internal device
overvoltage in the bq51025 device.
14
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9.3.6 Turning Off the Transmitter
The WPC v1.1 specification allows the receiver to turn off the transmitter and put the system in a low-power
standby mode. There are two different ways to accomplish this with the bq51025 device. The EPT charge
complete (WPC) can be sent to the TX by pulling the TS pin high (above 1.4 V). The bq51025 device will then
sense this and send the appropriate signal to the TX, thus putting the TX in a low-power standby mode.
9.3.6.1 WPC v1.1 EPT
The WPC allows for a special command to terminate power transfer from the TX-termed EPT packet. The WPC
v1.1 specifies the following reasons and their corresponding data field value in Table 2.
Table 2. EPT Codes in WPC
(1)
(2)
Reason
Value
Condition (1)
Unknown
0x00
AD > 3.6 V
Charge complete
0x01
TS/CTRL > 1.4 V
Internal fault
0x02
TJ > 150°C or RILIM < 215 Ω
Over temperature
0x03
TS < VHOT, or TS/CTRL < 100 mV
(2)
Over voltage
0x04
VRECT voltage does not converge and stays higher than target
Battery failure
0x06
Not sent
Reconfigure
0x07
Not sent
No response
0x08
Not sent
The Condition column corresponds to the case where the bq51025 device sends the WPC EPT
command.
The TS < VTS-HOT condition refers to using an external thermistor for temperature control. The
TS/CTRL <100-mV condition refers to driving the TS/CTRL pin from external GPIO.
9.3.7 Communication Current Limit
Communication current limit is a feature that allows for error-free communication to happen between the RX and
TX in the WPC mode. This is done by decoupling the coil from the load transients by limiting the output current
during communication with the TX. The communication current limit is set according to Table 3. The
communication current limit can be enabled by pulling CM_ILIM pin low or disabled by pulling the CM_ILIM pin
high (>1.4 V) . An internal pulldown enables communication current limit when the CM_ILIM pin is left floating.
Table 3. Communication Current Limit
IOUT
Communication Current Limit
0 mA < IOUT < 100 mA
None
100 mA < IOUT < 400 mA
IOUT + 50 mA
400 mA < IOUT < Max current
IOUT – 50 mA
When the communication current limit is enabled, the amount of current that the load can draw is limited. If the
charger in the system does not have a VIN-DPM feature, the output of the receiver collapses if communication
current limit is enabled. Please note that power dissipation within the device will increase during current limiting,
lowering overall system efficiency. To disable communication current limit, pull CM_ILIM pin high.
9.3.8
PD_DET and TMEM
PD_DET is an open-drain pin that goes low based on the voltage of the TMEM pin. When the voltage of TMEM
is higher than 1.6 V, PD_DET is low. The voltage on the TMEM pin depends on capturing the energy from the
digital ping from the transmitter and storing it on the C5 capacitor in Figure 9. After the receiver sends an EPT
(charge complete), the transmitter shuts down and goes into a low-power mode. However, it continues to check if
the receiver would like to renegotiate a power transfer by periodically performing the digital ping. The energy
from the digital ping can be stored on the TMEM pin until the next digital ping refreshes the capacitor. The
designer can choose a bleedoff resistor, RMEM, in parallel with C5 that sets the time constant so that the TMEM
pin will fall below 1.6 V once the next ping timer expires. The duration between digital pings is indeterminate and
depends on each transmitter manufacturer.
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TMEM
RMEM
C5
Figure 9. TMEM Configuration
Set capacitor on C5 = TMEM to 2.2 µF. Resistor RMEM across C5 can be set by understanding the duration
between digital pings (tping). Set the resistor such that:
t ping
4uC5
R MEM
(9)
PD_DET typically requires a pullup resistor to an external source. A higher current through the PD_DET pin may
affect the output regulation of the device. To improve regulation, TI recommends pullup resistor values in the
range of 15 to 100 kΩ.
9.3.9 TS/CTRL
The bq51025 device includes a ratiometric external temperature sense function. The temperature sense function
has a low ratiometric threshold which represents a hot condition. TI recommends an external temperature sensor
to provide safe operating conditions for the receiver product. This pin is best used for monitoring the surface that
can be exposed to the end user (for example, place the negative temperature coefficient (NTC) resistor closest to
the user touch point on the back cover). A resistor in series or parallel can be inserted to adjust the NTC to
match the trip point of the device. The implementation in Figure 10 shows the series-parallel resistor
implementation for setting the threshold at which VTS-HOT is reached. When the VTS-HOT threshold is reached, the
device will send an EPT – overtemperature signal for a WPC transmitter.
VTSB
(1.8 V)
R2
20 k
TS/CTRL
R1
NTC
R3
Figure 10. NTC Resistor Setup
Figure 10 shows a parallel resistor setup that can be used to adjust the trip point of VTS-HOT. After the NTC is
chosen and RNTCHOT at VTS-HOT is determined from the data sheet of the NTC, use Equation 10 to calculate R1
and R3. In many cases, depending on the NTC resistor, R1 or R3 can be omitted. To omit R1, set R1 to 0, and to
omit R3, set R3 to 10 MΩ in the calculation.
RNTCHOT R1 u R3
VTSHOT
1.8 V u
RNTCHOT R1 R3
RNTCHOT R1 u R3
RNTCHOT R1 R3
16
R2
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9.3.10 PMODE Pin
Connect a 5-MΩ resistor to ground in order to use PMODE to indicate the receiver mode of operation. PMODE is
high when in low-power mode and low in proprietary mode. This pin may be used to control the gate of an
NMOS switch to change the RILIM, and hence, the current limit based on the maximum power allowed by the
transmitter (10 W for bq500215, 5 W or less otherwise). This pin may be left floating if not used. and show the
PMODE behavior during startup.
9.3.11 I2C Communication
The bq51025 device allows for I2C communication with the internal CPU. The I2C address for the device is 0x6C.
In case the I2C is not used, ground SCL and SDA. See Register Maps for more information.
9.3.12 Input Overvoltage
If the input voltage suddenly increases in potential for some condition (for example, a change in position of the
equipment on the charging pad), the voltage-control loop inside the bq51025 device becomes active, and
prevents the output from going beyond VOUT(REG). The receiver then starts sending back error packets every 32
ms until the input voltage comes back to an acceptable level, and then maintains the error communication every
250 ms.
If the input voltage increases in potential beyond VRECT_OVP, the device switches off the LDO and informs the
primary to terminate power. In addition, a proprietary voltage protection circuit is activated by means of CCLAMP1
and CCLAMP2 that protects the device from voltages beyond the maximum rating of the device.
9.3.13 Alignment Aid Using Frequency Information
The bq51025 device provides the host through I2C with power signal frequency information that would enable it
to determine the optimal alignment position on the charging surface of a frequency-controlled transmitter. For
these WPC transmitters, the power signal frequency increases as the coupling between the primary and
secondary coils increases. By finding the position in the charging pad that has the highest frequency, the host
can determine that the best possible alignment with the transmitter coil has been achieved.
The bq51025 continuously stores a measurement of the power signal frequency in I2C register 0xFB to provide
the host the information it needs to determine optimal placement. The power signal frequency is given by:
u &RGH 0.982
T AC
where ƒAC is the power signal frequency measured at the AC pins in kHz and code is the decimal value in
the 0xFB register
(11)
Figure 11 shows the expected register values across the frequency range.
80
I2C Code (Decimal)
70
60
50
40
30
100
105 110
115
120 125 130 135 140
145 150 155 160 165 170
Frequency (kHz)
175 180 185 190
195 200 205
210
D014
2
Figure 11. I C Code vs Power Signal Frequency
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9.4 Device Functional Modes
At startup operation, the bq51025 device must comply with proper handshaking to be granted a power contract
from the WPC transmitter. The transmitter initiates the handshake by providing an extended digital ping after
analog ping detects an object on the transmitter surface. If a receiver is present on the transmitter surface, the
receiver then provides the signal strength, configuration, and identification packets to the transmitter (see volume
1 of the WPC specification for details on each packet). These are the first three packets sent to the transmitter.
The only exception is if there is a true shutdown condition on the AD or TS/CTRL pins where the receiver shuts
down the transmitter immediately. See Table 2 for details. After the transmitter has successfully received the
signal strength, configuration, and identification packets, the receiver is granted a power contract and is then
allowed to control the operating point of the power transfer. With the use of the bq51025 device Dynamic
Rectifier Control algorithm, the receiver informs the transmitter to adjust the rectifier voltage to approximately 8 V
prior to enabling the output supply. For startup flow diagram details, see Figure 12.
To operate in 10-W mode, the bq51025 device performs a proprietary handshaking procedure with the
transmitter. If the transmitter (bq500215) responds to the bq51025 handshake, a 10-W power contract is granted
and the bq51025 operates in 10-W mode, setting the proper output current limit and control. If there is no
response from the transmitter, the bq51025 device defaults to 5-W mode operation.
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Device Functional Modes (continued)
Tx Powered
without Rx
Active
Tx Extended Digital Ping
AD/TS-CTRL EPT
Condition?
Yes
Send EPT packet with
reason value
No
Signal Stength,
Identification & Configuration
Received by Tx?
No
Yes
No
Is Transmitter bq500215?
Yes
10-W Power Contract
Established. All
proceeding control is
dictated by the Rx.
WPC Power Contract
Established. All
proceeding control is
dictated by the Rx.
Yes
VRECT < 8 V?
Send control error packet
to increase VRECT
No
Startup operating point
established. Enable the
Rx output.
Rx Active
Power Transfer
Stage
Figure 12. Wireless Power Startup Flow Diagram on WPC TX
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Device Functional Modes (continued)
After the startup procedure is established, the receiver enters the active-power transfer stage (considered the
main loop of operation). The Dynamic Rectifier Control algorithm determines the rectifier voltage target based on
a percentage of the maximum output current level setting (set by KILIM and RILIM). The receiver sends control
error packets to converge on these targets. As the output current changes, the rectifier voltage target dynamically
changes. As a note, the feedback loop of the WPC system is relatively slow, it can take up to 150 ms to
converge on a new rectifier voltage target. It should be understood that the instantaneous transient response of
the system is open loop and dependent on the receiver coil output impedance at that operating point. The main
loop also determines if any conditions in Table 2 are true in order to discontinue power transfer. Figure 13 shows
the active-power transfer loop.
Rx Active
Power Transfer
Stage
Rx Shutdown
conditions per the EPT
Table?
Yes
Send EPT packet with
reason value
Tx Powered
without Rx
Active
No
Yes
Is VILIM < 0.05 V?
VRECT target = Minimum of
(VOUT + 2 V) or 11V. Send
control error packets to
converge.
No
Yes VRECT target = VOUT + 1.6 V.
Send control error packets
to converge.
Is VILIM < 0.1 V?
No
Yes VRECT target = VOUT + 0.6 V.
Send control error packets
to converge.
Is VILIM < 0.2 V?
No
VRECT target = VOUT + 0.12 V.
Send control error packets to
converge.
Measure Received Power
and Send Value to Tx
Figure 13. Active Power Transfer Flow Diagram on WPC TX
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9.5 Register Maps
Locations 0x01 and 0x02 can be written at any time. Locations 0xE0 to 0xFF are only functional when VRECT >
VUVLO. When VRECT goes below VUVLO, locations 0xE0 to 0xFF are reset.
9.5.1 Wireless Power Supply Current Register 1
Table 4. Wireless Power Supply Current Register 1 (READ / WRITE)
Memory Location: 0x01, Default State: 00000001
BIT
(1)
NAME
READ / WRITE
FUNCTION
B7 (MSB)
Read / Write
Not used
B6
Read / Write
Not used
B5
Read / Write
Not used
B4
Read / Write
Not used
B3
Read / Write
Not used
450, 500, 550, 600, 650, 700, 750, or 800 mV (1)
Changes VO_REG target
Default value 001
B2
VOREG2
Read / Write
B1
VOREG1
Read / Write
B0
VOREG0
Read / Write
Maximum output voltage is limited to 10 V. Maximum VO_REG setting is 0.5 V when default output voltage is set to 10 V with external
resistor divider (19:1 ratio)
9.5.2 Wireless Power Supply Current Register 2
Table 5. Wireless Power Supply Current Register 2 (READ / WRITE)
Memory Location: 0x02, Default State: 00000111
BIT
NAME
READ / WRITE
B7 (MSB)
JEITA
Read / Write
Not used
Read / Write
Not used
B6
B5
ITERM2
Read / Write
B4
ITERM1
Read / Write
B3
ITERM0
Read / Write
B2
IOREG2
Read / Write
B1
IOREG1
Read / Write
B0
IOREG0
Read / Write
FUNCTION
Not used.
10%, 20%, 30%, 40%, 50%, 60%, 80%, and 100% of IILIM current
based on configuration
000, 001, ….111
9.5.3 Wireless Power Supply Current Register 3
Table 6. Wireless Power Supply Current Register 3 (READ / WRITE)
Memory Location: 0xF0, Reset State: 00000000
BIT
NAME
READ / WRITE
B7
Reserved
Read/Write
B6
Reserved
Read / Write
B5
Reserved
Read / Write
B4
Reserved
Read / Write
B3
Reserved
Read / Write
B2
Reserved
Read / Write
B1
I2C_ILIM
Read / Write
B0
Reserved
Read / Write
FUNCTION
Set bit to 1 to disable 2× current limit scaling between low-power and
proprietary modes. Must be set to 1 to correctly adjust the current limit
for each mode through I2C
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9.5.4 I2C Mailbox Register
Table 7. I2C Mailbox Register (READ / WRITE)
Memory Location: 0xE0, Reset State: 10000000
BIT
NAME
READ / WRITE
B7
USER_PKT_DONE
Read/Write
USER_PKT_ERR
Read
B4
FOD Mailer
Read / Write
Not used
B3
ALIGN Mailer
Read / Write
Setting this bit to 1 enables alignment aid mode where the CEP = 0 is
sent until this bit is set to 0 (or CPU reset occurs)
B2
FOD Scaler
Read / Write
Not used, write to 0 if register is written
B1
Reserved
Read / Write
B0
Reserved
Read / Write
B6
B5
FUNCTION
Set bit to 0 to send proprietary packet with header in 0xE2.
CPU checks header to pick relevant payload from 0xF1 to 0xF4
This bit will be set to 1 after the user packet with the header in register
0xE2 is sent.
00
01
10
11
= No error in sending packet
= Error: No transmitter present
= Illegal header found: packet will not be sent
= Error: Not defined yet
9.5.5 I2C Mailbox Register 2
Table 8. I2C Mailbox Register 2 (READ / WRITE)
Memory Location: 0xEF, Reset State: 00000000
BIT
NAME
READ / WRITE
B7
PMODE
Read
B6
Reserved
Read / Write
B5
Reserved
Read / Write
B4
Reserved
Read / Write
B3
Reserved
Read / Write
B2
Reserved
Read / Write
B1
Reserved
Read / Write
B0
Reserved
Read / Write
FUNCTION
Power mode
0 = Low-power mode 5 W
1 = Proprietary 10 W
9.5.6 I2C Mailbox Register 3
Table 9. I2C Mailbox Register 3 (READ)
Memory Location: 0xFB, Reset State: 00000000
22
BIT
NAME
READ / WRITE
B7
FREQ7
Read
B6
FREQ6
Read
B5
FREQ5
Read
B4
FREQ4
Read
B3
FREQ3
Read
B2
FREQ2
Read
B1
FREQ1
Read
B0
FREQ0
Read
FUNCTION
Power signal frequency. See Equation 11 for calculation.
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9.5.7 Wireless Power Supply FOD RAM
Table 10. Wireless Power Supply FOD RAM (READ / WRITE)
Memory Location: 0xE1, Reset State: 00000000 (1)
(1)
BIT
NAME
READ / WRITE
B7 (MSB)
ESR_ENABLE
Read / Write
FUNCTION
Enables I2C based ESR in received power, Enable = 1, Disable = 0
B6
OFF_ENABLE
Read / Write
Enables I2C based offset power, Enable = 1, Disable = 0
B5
RoFOD5
Read / Write
B4
RoFOD4
Read / Write
B3
RoFOD3
Read / Write
000 = 0 mW
001 = 78 mW
010 = 156 mW
011 = 234 mW
100 = 312 mW
101 = 390 mW
110 = 468 mW
111 = 546 mW
The value is added to received power
message
B2
RsFOD2
Read / Write
B1
RsFOD1
Read / Write
101 = ESR
110 = ESR
111 = ESR x 0.5
B0
RsFOD0
Read / Write
000 = ESR
001 = ESR
010 = ESR × 2
011 = ESR × 3
100 = ESR × 4
A non-zero value changes the I2R calculation resistor and offset in the received power calculation by a factor shown in the table.
9.5.8 Wireless Power User Header RAM
Table 11. Wireless Power User Header RAM (WRITE)
Memory Location: 0xE2, Reset State: 00000000 (1)
(1)
BIT
READ / WRITE
B7 (MSB)
Read / Write
B6
Read / Write
B5
Read / Write
B4
Read / Write
B3
Read / Write
B2
Read / Write
B1
Read / Write
B0
Read / Write
Must write a valid WPC v1.1 Proprietary Packet Header to enable proprietary package. Reserved headers (Control Error Packet,
Received Power Packet, and so forth) may not be used. As soon as mailer (0xE0) is written, payload bytes are sent on the next
available communication slot as determined by CPU. When payload is sent, the mailer (USER_PKT_DONE) is set to 1.
9.5.9 Wireless Power USER VRECT Status RAM
Table 12. Wireless Power USER VRECT Status RAM (READ)
Memory Location: 0xE3, Reset State: 00000000
Range – 0 to 12 V
This register reads back the VRECT voltage with LSB = 46 mV
BIT
NAME
READ / WRITE
B7 (MSB)
VRECT7
Read
B6
VRECT6
Read
B5
VRECT5
Read
B4
VRECT4
Read
B3
VRECT3
Read
B2
VRECT2
Read
B1
VRECT1
Read
B0
VRECT0
Read
FUNCTION
LSB = 46 mV
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9.5.10 Wireless Power VOUT Status RAM
Table 13. Wireless Power VOUT Status RAM (READ)
Memory Location: 0xE4, Reset State: 00000000
This register reads back the VOUT voltage with LSB = 46 mV
BIT
NAME
Read / Write
B7 (MSB)
VOUT7
Read / Write
B6
VOUT6
Read / Write
B5
VOUT5
Read / Write
B4
VOUT4
Read / Write
B3
VOUT3
Read / Write
B2
VOUT2
Read / Write
B1
VOUT1
Read / Write
B0
VOUT0
Read / Write
FUNCTION
LSB = 46 mV
9.5.11 Wireless Power Proprietary Mode REC PWR MSByte Status RAM
Table 14. Wireless Power Proprietary Mode REC PWR MSByte Status RAM (READ) (1)
Memory Location: 0xE7, Reset State: 00000000
This register reads back the MSByte for received power in Proprietary 10-W Mode only
(1)
BIT
Read / Write
B7 (MSB)
Read / Write
B6
Read / Write
B5
Read / Write
B4
Read / Write
B3
Read / Write
B2
Read / Write
B1
Read / Write
B0
Read / Write
For proprietary mode, Received power (mW) = (10000/128) × REC PWR MSByte + (10000 / (256 × 128)) × REC PWR LSByte
9.5.12 Wireless Power REC PWR LSByte Status RAM
Table 15. Wireless Power REC PWR LSByte Status RAM (READ) (1)
Memory Location: 0xE8, Reset State: 00000000
(1)
24
BIT
Read / Write
B7 (MSB)
Read / Write
B6
Read / Write
B5
Read / Write
B4
Read / Write
B3
Read / Write
B2
Read / Write
B1
Read / Write
B0
Read / Write
This register reads back the received power in low-power mode with LSB = 39 mW. In proprietary mode, this register reads back the
LSByte for received power.
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9.5.13 Wireless Power Prop Packet Payload RAM Byte 0
Table 16. Wireless Power Prop Packet Payload RAM Byte 0 (WRITE)
Memory Location: 0xF1, Reset State: 00000000
BIT
Read / Write
B7 (MSB)
Read / Write
B6
Read / Write
B5
Read / Write
B4
Read / Write
B3
Read / Write
B2
Read / Write
B1
Read / Write
B0
Read / Write
9.5.14 Wireless Power Prop Packet Payload RAM Byte 1
Table 17. Wireless Power Prop Packet Payload RAM Byte 1 (WRITE)
Memory Location: 0xF2, Reset State: 00000000
BIT
Read / Write
B7 (MSB)
Read / Write
B6
Read / Write
B5
Read / Write
B4
Read / Write
B3
Read / Write
B2
Read / Write
B1
Read / Write
B0
Read / Write
9.5.15 Wireless Power Prop Packet Payload RAM Byte 2
Table 18. Wireless Power Prop Packet Payload RAM Byte 2 (WRITE)
Memory Location: 0xF3, Reset State: 00000000
BIT
Read / Write
B7 (MSB)
Read / Write
B6
Read / Write
B5
Read / Write
B4
Read / Write
B3
Read / Write
B2
Read / Write
B1
Read / Write
B0
Read / Write
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9.5.16 Wireless Power Prop Packet Payload RAM Byte 3
Table 19. Wireless Power Prop Packet Payload RAM Byte 3 (WRITE)
Memory Location: 0xF4, Reset State: 00000000
26
BIT
Read / Write
B7 (MSB)
Read / Write
B6
Read / Write
B5
Read / Write
B4
Read / Write
B3
Read / Write
B2
Read / Write
B1
Read / Write
B0
Read / Write
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10 Application and Implementation
NOTE
Information in the following applications sections is not part of the TI component
specification, and TI does not warrant its accuracy or completeness. TI’s customers are
responsible for determining suitability of components for their purposes. Customers should
validate and test their design implementation to confirm system functionality.
10.1 Application Information
The bq51025 device complies with WPC v1.1 standard. There are several tools available for the design of the
system. Obtain these tools by checking the product page at www.ti.com. The following sections detail how to
design a WPC v1.1 mode RX system.
10.2 Typical Applications
10.2.1 WPC v1.1 Power Supply 7-V Output With 1.4-A Maximum Current With I2C
System
Load
Q1
bq51025
AD-EN
AD
OUT
CCOMM1
C4
COMM1
CBOOT1
BOOT1
C1
C3
AC1
COIL
R8
VIREG
BOOT2
HOST
TS/CTRL
COMM2
CCOMM2
CCLAMP1
R6
R9
AC2
CCLAMP2
RECT
VO_REG
C2
CBOOT2
R7
RECT
NTC
TMEM
CLAMP2
C5
CLAMP1
RMEM
WPG
PD_DET
PMODE
SCL
CM_ILIM
SDA
ILIM
R1
FOD
RFOD
PGND
ROS RECT
Figure 14. Schematic Using bq51025
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Typical Applications (continued)
10.2.1.1 Design Requirements
Table 20. Design Parameters
DESIGN PARAMETER
EXAMPLE VALUE
VOUT
7V
IOUT MAXIMUM
1.4 A
10.2.1.2 Detailed Design Procedure
To start the design procedure, determine the following:
• Output voltage
• Maximum output current
10.2.1.3 Output Voltage Set Point
The output voltage of the bq51025 device can be set by adjusting a feedback resistor divider network. The
resistor divider network is used to set the voltage gain at the VO_REG pin. The device is intended to operate
where the voltage at the VO_REG pin is set to 0.5 V. This value is the default setting and can be changed
through I2C. In Figure 15, R6 and R7 are the feedback network for the output voltage sense.
OUT
C4
R7
R6
VO_REG
Figure 15. Voltage Gain for Feedback
K VO
R6
0.5 V
VOUT
(12)
K VO u R7
1 K VO
(13)
Choose R7 to be a standard value. In this case, take care to choose R6 and R7 to be fairly large values so as to
not dissipate an excessive amount of power in the resistors and thereby lower efficiency.
KVO is set to be 0.5 / 7 = 1/14, choose R7 to be 130 kΩ, and thus R6 to be 10 kΩ.
After R6 and R7 are chosen, the same values should be used on the VI_REG resistor divider (R9 and R8). This
allows the device to regulate the rectifier voltage properly and accurately track the output voltage.
10.2.1.4 Output and Rectifier Capacitors
Set C4 between 1 and 4.7 µF. This example uses 3.3 µF.
Set C3 between 22 and 44 µF. This example uses 44 µF to minimize output ripple.
28
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10.2.1.5 TMEM
Set C5 to 2.2 µF. To determine the bleedoff resistor, the WPC transmitters (for which the PD_DET is being set
for) needs to be determined. After the ping timing (time between two consecutive digital pings after EPT charge
complete is sent) is determined, the bleedoff resistor RMEM can be determined. This example uses TI transmitter
EVMs as the use case. In this case, the time between pings is 5 s. To set the time constant using Equation 9,
RMEM is set to 560 kΩ.
10.2.1.6 Maximum Output Current Set Point
ILIM
FOD1
R1
ROS
RECT
RFOD
Figure 16. Current Limit Setting for bq51025
The bq51025 device includes a means of providing hardware overcurrent protection by means of an analog
current regulation loop. The hardware current limit provides a level of safety by clamping the maximum allowable
output current (for example, a current compliance). The RILIM resistor size also sets the thresholds for the
dynamic rectifier levels, and thus providing efficiency tuning per each application’s maximum system current. The
calculation for the total RILIM resistance is as follows:
KILIM
RILIM
IILIM
(14)
51
5ILIM ± 5FOD
(15)
The RILIM allows for the ILIM pin to reach 1.2 V at an output current equal to IILIM in 10-W mode and reach 0.6 V
in 5-W mode. When choosing IILIM, consider two possible operating conditions:
• If the application requires an output current equal to or greater than external ILIM that the circuit is designed
for (input current limit on the charger where the RX is delivering power to is higher than the external ILIM),
ensure that the downstream charger is capable of regulating the voltage of the input into which the RX device
output is tied to by lowering the amount of current being drawn. This ensures that the RX output does not
collapse. Such behavior is referred to as VIN DPM in TI chargers. Unless such behavior is enabled on the
charger, the charger pulls the output of the RX device to ground when the RX device enters current
regulation.
• If the applications are designed to extract less than the IMAX, typical designs should leave a design margin of
at least 20% so that the voltage at ILIM pin reaches 1.2 V when 20% more than maximum current of the
system (IMAX) is drawn from the output of the RX. Such a design would have input current limit on the charger
lower than the external current limit of the RX device.
In both cases, however, the charger must be capable of regulating the current drawn from the device to allow the
output voltage to stay at a reasonable value. This same behavior is also necessary during the WPC v1.1
Communication. See Communication Current Limit for more details. The following calculations show how such a
design is achieved:
KILIM
RILIM
1.2 u I ILIM
(16)
51
5ILIM ± 5FOD
(17)
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When referring to the application diagram shown in Figure 16, RILIM is the sum of the R1 and RFOD resistance
(that is, the total resistance from the ILIM pin to GND). RFOD is chosen according to the FOD application note that
can be obtained by contacting your TI representative. This is used to allow the RX implementation to comply with
WPC v1.1 requirements related to received power accuracy.
Also note that in many applications, the resistor ROS is necessary to comply with WPC V1.1 requirements. In
such a case, the offset on the FOD pin from the voltage on RFOD can cause a shift in the calculation that can
reduce the expected current limit. Therefore, it is always a good idea to check the output current limit after FOD
calibration is performed according to the FOD section. Unfortunately, because the RECT voltage is not
deterministic, and depends on transmitter operation to a certain degree, it is not possible to determine R1 with
ROS present in a deterministic manner.
In this example, set maximum current for the example to be 1.4 A at 10 W and 700 mA at 5-W mode. Set IILIM =
1.7 A to allow for the 20% margin.
RILIM
842
1.7A
495Ö
(18)
10.2.1.7 I2C
The I2C lines are used to communicate with the device. To enable the I2C, they can be pulled up to an internal
host bus. The device address is 0x6C.
10.2.1.8 Communication Current Limit
Communication current limit allows the device to communicate with the transmitter in an error-free manner by
decoupling the coil from load transients on the OUT pin during WPC communication. In some cases, this
communication current limit feature is not desirable. In this design, the user enables the communication current
limit by tying the CM_ILIM pin to GND. If this is not needed, the CM_ILIM pin can be tied to the OUT pin to
disable the communication current limit. In this case, take care that the voltage on the CM_ILIM pin does not
exceed the maximum rating of the pin.
10.2.1.9 Receiver Coil
The receiver coil design is the most open part of the system design. The choice of the receiver inductance,
shape, and materials all intimately influence the parameters themselves in an intertwined manner. This design
can be complicated and involves optimizing many different aspects; refer to the EVM user's guide (SLUUBSS).
The typical choice of the inductance of the receiver coil for a 10-W, 7-V solution is between 15 and 16 µH.
10.2.1.10 Series and Parallel Resonant Capacitors
Resonant capacitors, C1 and C2, are set according to WPC specification.
The equations for calculating the values of the resonant capacitors are shown:
-1
2
é
ù
C1 = ê fS ´ 2p ´ L'S ú
ë
û
-1
é
2
1ù
C2 = ê fD ´ 2p ´ LS ú
C1 ûú
ëê
(
)
(
)
(19)
Because the bq51025 can provide up to 10 W of output power, TI highly recommends that the resonant
capacitors have very-low ESR and dissipate as little power as possible for better thermal performance. TI highly
recommends NP0/C0G ceramic material capacitors.
10.2.1.11 Communication, Boot, and Clamp Capacitors
Set CCOMMx to a value ranging from C1 / 8 to C1 / 3. The higher the value of the communication capacitors, the
easier it is to comply with the WPC specification. However, higher capacitors do lower the overall efficiency of
the system. Make sure these are X7R ceramic material and have a minimum voltage rating of 25 V.
Set CBOOTx as 15 nF. Make sure these are X7R ceramic material and have a minimum voltage rating of 25 V.
Set CCLAMPx as 470 nF. Make sure these are X7R ceramic material and have a minimum voltage rating of 25 V.
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10.2.1.12 Application Curves
CM_ILIM = High
CH1 = VRECT
CH3 = PMODE
CH2 = VOUT
CH4 = ILOAD
CM_ILIM = High
Figure 17. 7-V RX Start-Up With 9-Ω Load on a 5-W WPC
TX
CM_ILIM = High
CH1 = VRECT
CH2 = VOUT
CH4 = ILOAD
CM_ILIM = High
RILIM = 495:
RILIM = 700:
VRECT (V)
VILIM (V)
0.8
0.4
0.2
VOUT = 7V
ROS = Open
0
0
0.2
0.4
0.6
0.8
1
IOUT (A)
1.2
1.4
1.6
1.8
CH2 = VOUT
CH4 = ILOAD
9.5
9.25
9
8.75
8.5
8.25
8
7.75
7.5
7.25
7
6.75
6.5
6.25
6
RILIM = 495:
RILIM = 700:
0
D007
Figure 21. ILIM Voltage as a Function of Load Current
CH1 = VRECT
Figure 20. 1450- to 0-mA Load Dump with 7-V RX on
bq500215 TX
1.2
0.6
CH2 = VOUT
CH4 = ILOAD
Figure 18. 7-V RX Start-Up With 5-Ω Load on a bq500215
TX
Figure 19. 0- to 1450-mA Step with 7-V RX on bq500215 TX
1
CH1 = VRECT
CH3 = PMODE
0.2
0.4
0.6
0.8
IOUT (A)
1
1.2
1.4
D008
Figure 22. Rectifier Regulation as a Function of RILIM on
bq500215 TX, 7-V RX
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90%
90%
80%
80%
70%
70%
60%
60%
Efficiency
100%
Efficiency
100%
50%
40%
50%
40%
30%
30%
bq500210
bq500211
bq500412
20%
10%
VOUT = 5V
VOUT = 7V
VOUT= 10V
20%
10%
0
0
0
0.08 0.16 0.24 0.32
0.4 0.48 0.56 0.64 0.72
IOUT (A)
0
0.8
1
2
3
4
D011
CM_ILIM = High
5
6
POUT (W)
7
8
9
10
D0012
CM_ILIM = High
Figure 23. Efficiency on Various 5-W WPC TX, 7-V RX
Figure 24. Efficiency on 10-W bq500215 TX
200
7.1
bq500412 (A6)
bq500212A (A11)
190
7.08
7.06
180
7.04
170
VOUT (V)
Frequency (kHz)
Wurth 760 308 201 coil
Vishay IWAS4832FEEB150J50
Vishay IWAS4832FEEB150J50
160
150
140
7.02
7
6.98
6.96
130
6.94
120
6.92
110
6.9
0
0.08 0.16 0.24 0.32
0.4 0.48 0.56 0.64 0.72
IOUT (A)
0.8
0
0.2
D010
Figure 25. Frequency Range of 7-V, 5-W Mode on a WPC
TX
0.4
0.6
0.8
IOUT (A)
1
1.2
1.4
1.6
D009
Figure 26. Output Regulation on bq500215 TX
10
9
8
VRECT (V)
7
6
5
4
3
2
1
0
1
2
3
4
5
6
VOUT (V)
7
8
9
10
Figure 27. VRECT Foldback in Current Limit on a WPC TX
32
CH1 = VRECT
CH3 = AD_EN
D013
CH2 = VOUT
CH4 = AD
Figure 28. AD_EN Functionality upon 5-V USB Connection,
10-V RX, No Load
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12000
0
10000
-6
8000
-12
6000
-18
4000
-24
Min
Max
Difference
2000
0
0
CH1 = VRECT
CH3 = AD_EN
0.2
0.4
CH2 = VOUT
CH4 = AD
Figure 29. AD_EN Functionality upon 5-V USB Removal,
10-V RX, 1-A Load
0.6
0.8
ILOAD(A)
1
1.2
-30
-36
1.4
Difference between Max and Min Value (mW)
SLUSBX7B – SEPTEMBER 2014 – REVISED MARCH 2015
Reported Received Power (mW)
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D015
Figure 30. Received Power Variation (mW) vs IOUT (mA) on
a WPC TX
CH2 = VTS
Figure 31. TS Voltage Bias Without TS Resistor
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10.2.2 Standalone 10-V WPC v1.1 Power Supply With 1-A Maximum Output Current in System Board
When the bq5102x device is implemented as an embedded device on the system board, the same design
procedure as for an I2C system should be used, but the I2C pins are to be connected to ground.The VO_REG
and VIREG resistor dividers are chosen to achieve 10-V output and RILIM is chosen to allow a maximum current
of 1 A (IILIM = 1.2 A for 20% margin). Refer to WPC v1.1 Power Supply 7-V Output With 1.4-A Maximum Current
With I2C for details on how these resistor values are calculated.
A typical coil inductance for 10-V is between 15 and 17 µH. It is important to note that even if the same receiver
coil and tuning as for a 7-V RX solution are used (see Receiver Coil and Series and Parallel Resonant
Capacitors), the RFOD and ROS values need to be updated to accurately determine the received power.
System
Load
Q1
bq51025
AD-EN
AD
OUT
CCOMM1
C4
COMM1
CBOOT1
BOOT1
C1
C3
AC1
COIL
R8
VIREG
BOOT2
HOST
TS/CTRL
COMM2
CCOMM2
CCLAMP1
R6
R9
AC2
CCLAMP2
RECT
VO_REG
C2
CBOOT2
R7
RECT
NTC
TMEM
CLAMP2
C5
CLAMP1
PD_DET
PMODE
WPG
SCL
CM_ILIM
ILIM
R1
RMEM
FOD
RFOD
R10
SDA
PGND
ROS RECT
Figure 32. bq51025 Embedded in a System Board
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10.2.3 Standalone 10-V Power Supply With 1-A Maximum Output Current for 2S Charging System
For the bq51025 to work properly as a supply to a 2S charger, the bq51025 output voltage must not drop below
the minimum input charging voltage of the charger, which may be around 9 V depending on the charger IC. In a
WPC tuned Rx/TX system, the power delivered to the load may change during Rx/Tx communication due to the
capacitive modulation when CCOMM1 and CCOMM2 are connected form AC1 and AC2 pins to ground. If the power
delivered to the load decreases, the VRECT voltage will drop and so may VOUT. if the charger IC does not have
input DPM. If the power delivered to the load does not change or increases for a given current, the VRECT
voltage will increase and the bq51025 will regulate the voltage.
NOTE
The following design example is for a 2S charging system where the charger IC does not
have input DPM feature.
bq51025
AD-EN
System
Load
AD
OUT
CCOMM1
C4
COMM1
R7
CBOOT1
BOOT1
C1
RECT
DCLAMP
RECT
C3
AC1
R6
R8
VO_REG
COIL
R9
VIREG
AC2
CBOOT2
BOOT2
HOST
TS/CTRL
COMM2
CCOMM2
OUT
NTC
TMEM
CLAMP2
C5
CLAMP1
RMEM
PD_DET
PMODE
WPG
SCL
CM_ILIM
D1
ILIM
R1
FOD
RFOD
SDA
PGND
ROS RECT
Figure 33. bq51025 Embedded in a 2S Battery System Board
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10.2.3.1 Design Requirements
Table 21. Design Parameters
DESIGN PARAMETER
EXAMPLE VALUE
VOUT
10 V
IOUT MAXIMUM
1A
10.2.3.2 Detailed Design Procedure
To start the design procedure, determine the following:
• Output voltage
• Maximum output current
10.2.3.3 Output Voltage Set Point
The output voltage of the bq51025 device can be set by adjusting a feedback resistor divider network as
described in Output Voltage Set Point. The ratio of VO_REG and VIREG resistor dividers are chosen to achieve
10-V based on the 0.5-V feedback voltage. Following Equation 12 and Equation 13, R6 and R7 are selected to
be 11.3KΩ- and 215-kΩ, respectively. The same values are used on R9 and R8 in the VIREG divider.
10.2.3.4 Output and Rectifier Capacitors
Set C4 to at least 3.3 µF.
Set C3 to at least 44 µF to minimize output ripple. Use capacitors rated for 25 V or higher.
10.2.3.5 TMEM
Follow procedure described in TMEM.
10.2.3.6 Maximum Output Current Set Point
Follow the procedure described in Maximum Output Current Set Point.
10.2.3.7 I2C
Connect I2C lines to ground.
10.2.3.8 Communication Current Limit
Communication current limit must be disabled. Connect CM_ILIM pin to voltage supply making sure it does not
exceed maximum absolute rating for the pin. If only the battery voltage is available, use a 5-V Zener diode (D1)
to clamp the voltage.
10.2.3.9 Receiver Coil
The receiver coil design is the most open part of the system design. The choice of the receiver inductance,
shape, and materials all intimately influence the parameters themselves in an intertwined manner. This design
can be complicated and involves optimizing many different aspects. The typical choice of the inductance of the
receiver coil for a 10-W, 10-V solution is between 15 and 16 µH.
10.2.3.10 Series Resonant Capacitors
In order for the bq51025 to work properly as a supply to a 2S charger, the bq51025 output voltage must not drop
below the minimum input charging voltage of the charger, which may be around 9 V depending on the charger
IC. In a WPC tuned Rx/Tx system, the power delivered to the load may change during Rx/Tx communication due
to the capacitive modulation when CCOMM1 and CCOMM2 are connected from AC1 and AC2 pins to ground. If the
power delivered to the load decreases, the VRECT voltage will drop and so may VOUT if the charger IC does not
have VIN-DPM function. If the power delivered to the load does not change or increases for a given current, the
VRECT voltage will increase and the bq51025 will regulate the voltage to a fixed value. The following section
discusses the tuning procedure to ensure that the output voltage level is maintained during communication when
operating with a bq51025 based transmitter.
36
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10.2.3.10.1 Tuning Procedure
NOTE
The following tuning procedure results in a system that is not compliant with WPC
specification and is only designed to operate with a given bq500215 based transmitter.
1. Measure the effective self-inductance of the bq500215 based transmitter (primary) coil, LP' , and receiver
(secondary) coil, LS'. The measurements must be done on the final charging system setup (that is, battery
and any other friendly metal of the device is included as well as any cover material that determines the
distance between the coil and charging surface). Make the measurement at the optimal alignment position.
2. Measure the mutual inductance, LM and calculate the coupling factor given by:
k
LM
LS ' LP '
(20)
3. A first-order approximation of the series capacitance is given by:
1
C1
( 2S f ) 2 LS ' (1 k 2 ) k 2 LS '
4S f
C P LP '
(21)
Where f is the operating frequency of the transmitter, which is 130 kHz and CP is the transmitter resonant
capacitance which is 247 nF.
4. Make sure C1 as well as CCOMM1 and CCOMM2 are populated and place the receiver with best possible
alignment on the transmitter and start power transfer. Using an oscilloscope, monitor the VRECT voltage
during communication at maximum load. If VRECT decreases during communication, increase C1 until the
voltage remains flat. Note that the larger the VRECT voltage increase is during communication at maximum
load, the larger the losses on the device. The voltage increase in VRECT is larger with lower load and lower
coupling, so it is important to keep the VRECT voltage as low as possible during communication at maximum
load and coupling to maximize efficiency across charging area and load range. Figure 35 and Figure 36
show how the VRECT voltage behavior after tuning
10.2.3.11 Communication, Boot, and Clamp Capacitors
Set CCOMMx to a value ranging from C1 / 8 to C1 / 3. Make sure these are X7R ceramic material and have a
minimum voltage rating of 25 V. For this example 56-nF capacitors are chosen.
Set CBOOTx as 15 nF. Make sure these are X7R ceramic material and have a minimum voltage rating of 25 V.
CCLAMPx is not populated since a external clamping diode is used.
10.2.3.12 VRECT Clamp
Connect a 12-V Zener diode (DCLAMP) from VRECT to ground. This diode prevents the rectifier voltage from
overshoot above VRECT-OVP level, preventing unwanted resets during large load transients during communication.
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10.2.3.13 Application Curves
CH1 = VRECT
CH1 = VRECT
CH2 = VOUT
CH4 = ILOAD
Figure 35. 10-V Tuned RX VOUT at Center Position
With 1-A Load
Figure 34. 10-V Tuned RX Start-Up With 1-A Load
CH1 = VRECT
CH2 = VOUT
CH4 = ILOAD
CH2 = VOUT
CH4 = ILOAD
CH1 = VRECT
Figure 36. 10-V Tuned RX VOUT at Center Position With
No load
CH2 = VOUT
CH4 = ILOAD
Figure 37. 1-A to 0-mA Load Dump
With 10-V Tuned RX
100%
90%
80%
Efficiency
70%
60%
50%
40%
30%
20%
10%
CH1 = VRECT
CH2 = VOUT
CH4 = ILOAD
0
0
Figure 38. 100-mA to 1-A Load Transient With 10-V Tuned
RX
38
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0.1
0.2
0.3
0.4
0.5 0.6
IOUT (A)
0.7
0.8
0.9
1
D016
Figure 39. Efficiency With 10-V Tuned RX
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11 Power Supply Recommendations
These devices are intended to be operated within the ranges shown in the Recommended Operating Conditions.
Because the system involves a loosely coupled inductor setup, the voltages produced on the receiver are a
function of the inductances and the available magnetic field. Ensure that the design in the worst case keeps the
voltages within the Absolute Maximum Ratings.
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12 Layout
12.1 Layout Guidelines
•
•
•
•
•
•
Keep the trace resistance as low as possible on AC1, AC2, and OUT.
Detection and resonant capacitors need to be as close to the device as possible.
COMM, CLAMP, and BOOT capacitors need to be placed as close to the device as possible.
Via interconnect on GND net is critical for appropriate signal integrity and proper thermal performance.
High-frequency bypass capacitors need to be placed close to RECT and OUT pins.
ILIM and FOD resistors are important signal paths and the loops in those paths to GND must be minimized.
Signal and sensing traces are the most sensitive to noise; the sensing signal amplitudes are usually
measured in mV, which is comparable to the noise amplitude. Make sure that these traces are not being
interfered by the noisy and power traces. AC1, AC2, BOOT1, BOOT2, COMM1, and COMM2 are the main
source of noise in the board. These traces should be shielded from other components in the board. It is
usually preferred to have a ground copper area placed underneath these traces to provide additional
shielding. Also, make sure they do not interfere with the signal and sensing traces. The PCB should have a
ground plane (return) connected directly to the return of all components through vias (two vias per capacitor
for power-stage capacitors, one via per capacitor for small-signal components.
For a 1.4-A fast-charge current application, the current rating for each net is as follows:
• AC1 = AC2 = 2.2 A
• OUT = 2.5 A
• RECT = 200 mA (RMS)
• COMMx = 600 mA
• CLAMPx = 1000 mA
• All others can be rated for 10 mA or less.
12.2 Layout Example
AD is also a
power trace.
Keep the trace
resistance as
low as possible
on AC1, AC2,
and OUT.
Isolate noisy
traces using
GND trace.
Place signal and
sensing
components as
close as possible
to the IC.
Place detection
and resonant
capacitors Cd
and Cs here.
It is always a good
practice to place high
frequency bypass
capacitors next to RECT
and OUT.
The via interconnect is important and
must be optimized near the power pad
of the IC and the GND for good thermal
dissipation.
Place COMM,
CLAMP, and
BOOT capacitors
as close as
possible to the IC
terminals.
Figure 40. Layout Recommendation
40
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13 Device and Documentation Support
13.1 Trademarks
All trademarks are the property of their respective owners.
13.2 Electrostatic Discharge Caution
These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam
during storage or handling to prevent electrostatic damage to the MOS gates.
13.3 Glossary
SLYZ022 — TI Glossary.
This glossary lists and explains terms, acronyms, and definitions.
14 Mechanical, Packaging, and Orderable Information
The following pages include mechanical, packaging, and orderable information. This information is the most
current data available for the designated devices. This data is subject to change without notice and revision of
this document. For browser-based versions of this data sheet, refer to the left-hand navigation.
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PACKAGE OPTION ADDENDUM
www.ti.com
13-Nov-2014
PACKAGING INFORMATION
Orderable Device
Status
(1)
Package Type Package Pins Package
Drawing
Qty
Eco Plan
Lead/Ball Finish
MSL Peak Temp
(2)
(6)
(3)
Op Temp (°C)
Device Marking
(4/5)
BQ51025YFPR
ACTIVE
DSBGA
YFP
42
3000
Green (RoHS
& no Sb/Br)
SNAGCU
Level-1-260C-UNLIM
-40 to 125
BQ51025
BQ51025YFPT
ACTIVE
DSBGA
YFP
42
250
Green (RoHS
& no Sb/Br)
SNAGCU
Level-1-260C-UNLIM
-40 to 125
BQ51025
(1)
The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2)
Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability
information and additional product content details.
TBD: The Pb-Free/Green conversion plan has not been defined.
Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that
lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes.
Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and package, or 2) lead-based die adhesive used between
the die and leadframe. The component is otherwise considered Pb-Free (RoHS compatible) as defined above.
Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight
in homogeneous material)
(3)
MSL, Peak Temp. - The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature.
(4)
There may be additional marking, which relates to the logo, the lot trace code information, or the environmental category on the device.
(5)
Multiple Device Markings will be inside parentheses. Only one Device Marking contained in parentheses and separated by a "~" will appear on a device. If a line is indented then it is a continuation
of the previous line and the two combined represent the entire Device Marking for that device.
(6)
Lead/Ball Finish - Orderable Devices may have multiple material finish options. Finish options are separated by a vertical ruled line. Lead/Ball Finish values may wrap to two lines if the finish
value exceeds the maximum column width.
Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information
provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and
continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals.
TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release.
Addendum-Page 1
Samples
PACKAGE OPTION ADDENDUM
www.ti.com
13-Nov-2014
In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis.
Addendum-Page 2
PACKAGE MATERIALS INFORMATION
www.ti.com
13-Nov-2014
TAPE AND REEL INFORMATION
*All dimensions are nominal
Device
Package Package Pins
Type Drawing
SPQ
Reel
Reel
A0
Diameter Width (mm)
(mm) W1 (mm)
BQ51025YFPR
DSBGA
YFP
42
3000
330.0
12.4
BQ51025YFPT
DSBGA
YFP
42
250
330.0
12.4
Pack Materials-Page 1
B0
(mm)
K0
(mm)
P1
(mm)
W
Pin1
(mm) Quadrant
2.99
3.71
0.81
8.0
12.0
Q1
2.99
3.71
0.81
8.0
12.0
Q1
PACKAGE MATERIALS INFORMATION
www.ti.com
13-Nov-2014
*All dimensions are nominal
Device
Package Type
Package Drawing
Pins
SPQ
Length (mm)
Width (mm)
Height (mm)
BQ51025YFPR
DSBGA
YFP
42
3000
367.0
367.0
35.0
BQ51025YFPT
DSBGA
YFP
42
250
367.0
367.0
35.0
Pack Materials-Page 2
PACKAGE OUTLINE
YFP0042
DSBGA - 0.5 mm max height
SCALE 4.700
DIE SIZE BALL GRID ARRAY
B
E
A
BUMP A1
CORNER
D
C
0.5 MAX
SEATING PLANE
BALL TYP
0.19
0.13
0.05 C
2 TYP
SYMM
G
F
D: Max = 3.586 mm, Min =3.526 mm
E
SYMM
2.4
TYP
E: Max = 2.874 mm, Min =2.814 mm
D
C
0.3
0.2
0.015
42X
B
C A
B
A
0.4 TYP
1
2
3
4
5
6
0.4 TYP
4221555/B 04/2015
NOTES:
1. All linear dimensions are in millimeters. Any dimensions in parenthesis are for reference only. Dimensioning and tolerancing
per ASME Y14.5M.
2. This drawing is subject to change without notice.
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EXAMPLE BOARD LAYOUT
YFP0042
DSBGA - 0.5 mm max height
DIE SIZE BALL GRID ARRAY
(0.4) TYP
42X ( 0.23)
1
2
3
4
6
5
A
(0.4) TYP
B
C
SYMM
D
E
F
G
SYMM
LAND PATTERN EXAMPLE
SCALE:25X
( 0.23)
METAL
0.05 MAX
METAL
UNDER
SOLDER MASK
0.05 MIN
( 0.23)
SOLDER MASK
OPENING
SOLDER MASK
OPENING
NON-SOLDER MASK
DEFINED
(PREFERRED)
SOLDER MASK
DEFINED
SOLDER MASK DETAILS
NOT TO SCALE
4221555/B 04/2015
NOTES: (continued)
3. Final dimensions may vary due to manufacturing tolerance considerations and also routing constraints.
For more information, see Texas Instruments literature number SNVA009 (www.ti.com/lit/snva009).
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EXAMPLE STENCIL DESIGN
YFP0042
DSBGA - 0.5 mm max height
DIE SIZE BALL GRID ARRAY
(0.4) TYP
(R0.05) TYP
42X ( 0.25)
1
2
4
3
5
6
A
(0.4)
TYP
METAL
TYP
B
C
SYMM
D
E
F
G
SYMM
SOLDER PASTE EXAMPLE
BASED ON 0.1 mm THICK STENCIL
SCALE:30X
4221555/B 04/2015
NOTES: (continued)
4. Laser cutting apertures with trapezoidal walls and rounded corners may offer better paste release.
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