TI EMB1499QMHE/NOPB

EMB1499Q
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SNOSCV7B – NOVEMBER 2011 – REVISED SEPTEMBER 2013
EMB1499Q Bidirectional Current DC-DC Controller
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FEATURES
DESCRIPTION
•
•
•
•
•
•
The EMB1499Q bidirectional current dc/dc controller
IC works in conjunction with the EMB1428 switch
matrix gate driver IC to support TI’s switch matrix
based active cell balancing scheme for a battery
management system. The EMB1499Q provides three
PWM MOSFET gate signals to a bidirectional forward
converter so that its output current, either positive or
negative, is regulated around a user-defined
magnitude. This inductor current is channeled by the
EMB1428 through the switch matrix to the cell that
needs to be charged or discharged. In a typical
scheme, the EMB1499Q-based forward converter
exchanges energy between a single cell and the
battery stack to which it belongs, with a maximum
stack voltage of up to 60 V. The switching frequency
is fixed at 250 kHz. The EMB1499Q senses cell
voltage, inductor current and stack current and
provides protection from abnormal conditions during
balancing.
1
•
•
60-V Maximum Stack Operating Voltage
Bidirectional Balancing Current
Fully Synchronous Operation
Active Clamp Signal
250-kHz Switching Frequency
Fault Detection Includes Two Separate UVLO
Cells (One for Each External Supply), Primary
and Secondary Side Current Limit, OVP/UVP
Sense on Cell Being Charged, Thermal
Shutdown, and Watchdog Timer
Balancing Current User-selectable Through
External Voltage
EMB1499Q is an Automotive Grade Product
that is AEC-Q100 Grade 1 Qualified (–40°C to
+125°C Operating Junction Temperature)
APPLICATIONS
•
•
•
Li-Ion Battery Management Systems
Hybrid and Electric Vehicles
Grid Storage
The EMB1499Q also provides an active clamp timing
signal to control an external FET driver for the
primary-side active clamp FET. The EMB1499Q is
enabled and disabled by the EMB1428. Fault
conditions detected by the EMB1499Q are
communicated to the EMB1428 through the DONE
and FAULT pins.
1
Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of
Texas Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet.
PRODUCTION DATA information is current as of publication date.
Products conform to specifications per the terms of the Texas
Instruments standard warranty. Production processing does not
necessarily include testing of all parameters.
Copyright © 2011–2013, Texas Instruments Incorporated
EMB1499Q
SNOSCV7B – NOVEMBER 2011 – REVISED SEPTEMBER 2013
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Typical Application
Vstack
Vstack
­
°
7-Cell
HalfStack
EMB1499
®
GATE_LS
GATE_HS2
GATE_HS1 VSENSE_LS
VSENSE_HS
PWM_CLAMP
CELLPLUS
VINA
VINP
VINF
PVINF
MOSFET
DRIVER
+12V
Floating
12V Supply
PGNDF
GNDF
°
¯
VSET
EMB1428
SOURCE[11..0]
GATE[11..0]
VDDCP
EN
DIR
DIR_RT
DONE
FAULT2
FAULT1
FAULT0
DAC
EN
DIR
DIR_RT
DONE
FAULT2
FAULT1
FAULT0
CEXT2
GNDA GNDP
CEXT1
SPI BUS
CS
SD0
SDI
SCLK
VSTACK
VDD12V
VDDP
+12V
+5V
+3.3V
TO OTHER BALANCING CIRCUIT
CPU OR
MCU
VDD5V
FAULT_INT
VDDIO
RST
GNDP GND
Figure 1. Typical Application
Connection Diagram
VSENSE_HS
CELLPLUS
LOR
TM
GNDA
VSET
WDOR
EN
DIR
DIR_RT
DONE
FAULT0
FAULT1
FAULT2
1
28
2
27
3
26
4
25
5
24
6
23
7
22
8
EMB1499
(Top View)
21
9
20
10
19
11
18
12
17
13
16
14
15
VINF
GNDF
N/C
GATE_HS2
PGNDF
GATE_HS1
PVINF
VINP
GNDP
GATE_LS
PWM_CLAMP
GNDA
VINA
VSENSE_LS
Figure 2. 28-Pin HTSSOP
See PWP Package
2
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PIN DESCRIPTIONS
Pin
Name
1
VSENSE_HS
2
CELLPLUS
3
LOR
Description
Application Information
Secondary side current sense input
Connect to transformer side of secondary sense resistor
Senses the cell voltage, used for
OVP/UVP fault detection
Connect to top of secondary side of the converter. This is the
top of the cell being charged.
Fault latch override input
Grounded for normal operation.
4
TM
Test mode input
Grounded for normal operation.
5, 17
GNDA
IC signal ground
Connect to module ground at board level.
6
VSET
Control voltage for adjusting the
balancing current
This voltage is set by the user.
7
WDOR
Watchdog timer override
Grounded for normal operation.
8
EN
Input from EMB1428, signals charge or
discharge cycle to begin.
Rising edge of this signal clears all fault latches, the DONE
latch, and initiates charge or discharge current. Falling edge of
this signal causes the charge current to ramp down to zero,
then asserts the DONE signal, causing shutdown.
9
DIR
Input from EMB1428, determines the
direction of the converter output current
"High" indicates charge mode, "Low" indicates discharge
mode.
10
DIR_RT
Output to EMB1428, inverted copy of the
DIR signal
Used as a handshake signal to ensure DIR signal has been
received correctly.
11
DONE
Output to EMB1428, indicates that the
balancing current has ramped down
towards zero.
When the EMB1499Q is disabled by toggling the EN pin low,
the chip goes into a 'soft shutdown', ramping the charging
current down within several hundred microseconds. When the
current has ramped down, the EMB1499Q shuts down and the
DONE signal latches high. The DONE latch is cleared at the
next rising edge of the EN signal.
12,13,14
FAULT[0,1,2]
Outputs to EMB1428, three bit digital fault If a fault condition is detected, the proper three bit word is
code
latched into the FAULT pins and the EMB1499Q is shut down.
The FAULT pins are cleared by the rising edge of the EN input.
15
VSENSE_LS
Primary side current sense input
Connect to transformer side of primary sense resistor.
16
VINA
External 12V supply
Powers all internal circuitry besides the primary gate side
driver. VINA and VINP should be connected together at the
board level.
18
PWM_CLAMP
19
GATE_LS
20
GNDP
IC power ground
Provides ground return for primary side gate driver. Connect to
board level ground.
21
VINP
External 12V supply
Powers the primary side gate driver. VINP and VINA should be
connected together at the board level.
22
PVINF
External floating 12V supply
This floating supply must be referenced to the bottom of the
transformer secondary. Supplies power to the secondary side
gate drivers. PVINF and VINF should be connected together at
the board level.
23
GATE_HS1
24
PGNDF
25
GATE_HS2
Output, PWM signal used to control
primary side active clamp (external driver
required)
Output, gate signal for external primary
side power FET
Output, gate signal for external secondary
side power FET
Floating power ground
Connect to secondary side of converter. Provides the ground
return for the secondary side gate drivers.
Output, gate signal for external secondary
side power FET
26
N/C
No connect
No connect pin. Do not connect
27
GNDF
Floating signal ground
Connected to secondary side of converter. Provides ground
reference for all internal circuitry that floats with the transformer
secondary except the secondary side gate drivers.
28
VINF
External floating 12V supply
This floating supply must be referenced to the bottom of the
transformer secondary. Supplies power to all internal circuitry
that floats with the transformer secondary except the
secondary side gate drivers. PVINF and VINF should be
connected together at the board level.
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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.
ABSOLUTE MAXIMUM RATINGS (1)
VINA, VINP to GND
-0.5V to 15V
VINF, PVINF to GNDF
-0.5V to 15V
GNDF to GND
-0.5V to 60V
VSENSE_LS to GND
-0.5V to 0.5V
VSENSE_HS to GNDF
-0.5V to 0.5V
VSET to GND
-0.5V to 7.5V
CELLPLUS to GNDF
-0.5V to 7.5V
All other inputs to GND
-0.5V to 15V
ESD Rating (2)
Human Body Model
±2kV
Soldering Information
Junction Temperature
150°C
Storage Temperature
-65°C to 150°C
(1)
(2)
Absolute Maximum Ratings indicate limits beyond which damage to the device may occur, including inoperability and degradation of
device reliability and/ or performance. Functional operation of the device and/or non-degradation at the Absolute Maximum Ratings or
other conditions beyond those indicated in the recommended Operating Ratings is not implied. The recommended Operating Ratings
indicate conditions at which the device is functional and should not be operated beyond such conditions.
The human body model is a 100pF capacitor discharged through a 1.5 kΩ resistor into each pin. Test method is per JESD22–A114.
OPERATING RATINGS
VINA, VINP to GND
10V to 14V
VINF, PVINF to GNDF
10V to 14V
GNDF to GND
0V to 56V
VSENSE_LS to GND
-0.2V to 0.2V
VSENSE_HS to GNDF
-0.2V to 0.2V
VSET to GND
1V to 2.2V
CELLPLUS to GNDF
0V to 6V
All other inputs to GND
0V to 14V
Junction Temperature (TJ)
-40°C to 125°C
4
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ELECTRICAL CHARACTERISTICS
Limits in standard type are for TJ = 25°C only; limits in boldface type apply over the junction temperature (TJ) range of −40°C
to +125°C. Minimum and Maximum limits are specified through test, design, or statistical correlation. Typical values represent
the most likely parametric norm at TJ = 25°C, and are provided for reference purposes only. For all tests, VINA = VINP =
VINF = PVINF = 12V unless otherwise specified.
Symbol
Parameter
Conditions
Min
Typ (1)
Max
Units
VSET = 2V
45
50
55
mV
VSET = 1.2V
24
30
36
mV
220
250
290
kHz
Feedback Voltage
VSENSE_HS
Feedback Voltage
Switching Parameters
FSW
Switching Frequency
DMAX
Maximum Duty Cycle
DMIN
Minimum Duty Cycle
Charge
Direction
91
%
Discharge
Direction
91
%
Charge
Direction
4
%
Discharge
Direction
3
%
Operating Thresholds
UVLO
Under-voltage Lockout
VINA, VINP,
VINF, PVINF
Rising
VINA, VINP,
VINF, PVINF
Falling
VEN_TH
Enable Threshold
VDIR_TH
Direction Threshold
10.8
5
V
EN Rising
EN Falling
1.55
V
0.45
V
DIR Rising
DIR Falling
V
2.75
V
2.2
V
Quiescent Currents
IQ_VINA
VINA Quiescent Current
(Operating)
VSET = 2V,
VSENSE_HS =
0V
2
2.8
mA
VINA Quiescent Current
(Shutdown)
EN = 0V
<1
2.3
µA
IQ_VINP
VINP Quiescent Current
(Shutdown)
VEN = 0V
<1
2.3
µA
IQ_VINF
VINF Quiescent Current
(Operating)
VSET = 2V,
VSENSE_HS =
0V
1.5
1.9
mA
VINF Quiescent Current
(Shutdown)
EN = 0V
<1
2
µA
IQ_PVINF
VPINF Quiescent Current
(Shutdown)
EN = 0V
<1
2.5
µA
IQ_CELLPLUS
CELLPLUS Quiescent Current
(Operating)
VSET = 2V,
VSENSE_HS =
0V
18
30
µA
Fault Detection
VCL_LS
Primary Side Current Limit
100
132
170
mV
VCL_HS
Secondary Side Current Limit
95
136
185
mV
VOVP
Cell OVP Threshold Voltage
4.5
5.5
7
V
CELLPLUS
Rising
CELLPLUS
Falling
(1)
5
V
Typical specifications represent the most likely parametric norm at 25°C operation.
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ELECTRICAL CHARACTERISTICS (continued)
Limits in standard type are for TJ = 25°C only; limits in boldface type apply over the junction temperature (TJ) range of −40°C
to +125°C. Minimum and Maximum limits are specified through test, design, or statistical correlation. Typical values represent
the most likely parametric norm at TJ = 25°C, and are provided for reference purposes only. For all tests, VINA = VINP =
VINF = PVINF = 12V unless otherwise specified.
Symbol
Parameter
Conditions
VUVP
Cell UVP Threshold Voltage
CELLPLUS
Rising
CELLPLUS
Falling
Min
Typ (1)
Max
1.17
0.55
0.74
Units
V
0.95
V
tWD
Watchdog Timeout
8
s
TSD
Thermal Shutdown
165
°C
Output Drivers
RON_LS_HIGH
Primary Side Driver Pull-up Output IGATE_LS =
Resistance
100mA
3.6
5.5
8.4
Ω
RON_LS_LOW
Primary Side Driver Pull-down
Output Resistance
1.1
1.7
3.2
Ω
RON_HS1_HIGH
Secondary Side Driver (HS1) Pull- IGATE_LS =
up Output Resistance
100mA
7
11
16
Ω
RON_HS1_LOW
Secondary Side Driver (HS1) Pull- IGATE_LS =
down Output Resistance
100mA
1.1
1.7
3.2
Ω
RON_HS2_HIGH
Secondary Side Driver (HS2) Pull- IGATE_LS =
up Output Resistance
100mA
7
11
16
Ω
RON_HS2_LOW
Secondary Side Driver (HS2) Pull- IGATE_LS =
down Output Resistance
100mA
0.9
1.5
3
Ω
6
IGATE_LS =
100mA
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VINA
VINF
VDDI
VDDIF
PVINF
PWM_HS1
VSENSE_HS
GATE_HS1
VSENSE_LS
PWM_HS2
GATE_HS2
Controller
EN
PGNDF
BIAS
VSET
VREF
DIR
VINP
DIR (HS and LS)
CLK
PWM_LS
FAULT
Support
Circuitry
CELLPLUS
TM
GATE_LS
ILIMIT (HS and LS)
(Bias, LDOs, UVLO,
Fault Logic)
PWM_CLAMP
GNDP
WDOR
DONE
LDOR
DIR_RT
FAULT[2:0]
GNDA
GNDF
Figure 3. Top-level Block Diagram
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Upper Voltage Domain
(referenced to GNDF)
VDDIF
(From
Support
Circuitry)
DIR_HS
(From
Support
Circuitry)
Iref
Error Amp
(From
Support
Circuitry)
Iref
VSENSE_HS
Secondary Side
Current Sense
Amp
VREF
2.5V
Trim
GNDF
Iref
Buffer
IsenseHS
ILIMIT_HS
(From
Support
Circuitry)
Current Limit
Comparators
VDDI
ILIMIT_LS
Primary Side
Current Sense Amp
200 mV
VSENSE_LS
PWM_HS2
(From
Support
Circuitry)
IsenseLS
(TO
DRIVERS)
DIR_LS
Isense
Artificial Ramp
Icontrol
PWM Comparator
PWM_HS1
PWM
Logic
Timing
Generator
PWM_LS
Iramp
250 kHz
GNDA
PWM_CLAMP
CLK
(To Support
Circuitry)
Figure 4. Controller Block Diagram
8
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CELLPLUS
VINA
VDDIF
OVP/UVP
LDO
UVLO
VOVP
Upper Voltage Domain
(referenced to GNDF)
L/S
DIR_HS
(TO
CONTROLLER)
VUVP
GNDF
VNA
VDDI
LDO
UVLO
EN
DIR_RT
DONE Signal
DIR_LS
DIR
(TO
CONTROLLER)
OVP
UVP
Thermal
Shutdown
1 D
Thermal Fault
Q
FAULT2
DFF
CLR
LOR
ILIMIT_HS
ILIMIT_HS Fault
ILIMIT
Counter
(FROM CONTROLLER)
ILIMIT_LS Fault
1 D
Fault
Encoder
(FROM CONTROLLER)
Freq/2
FAULT1
CLR
ILIMIT_LS
CLK
Q
DFF
1 D
Watchdog T/O
N
Q
FAULT0
DFF
CLR
WDOR
1 D
Q
DONE
DFF
Startup Circuitry
CLR
EN
Istartup
Adjust Line
VSET
Ideal Diode
Vd = 0V
VREF
VDDI
Ishutdown
Cstart
(TO
CONTROLLER)
Latch Clear
100 mV
~10 Ps
GNDA
Figure 5. Support Circuitry Block Diagram
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APPLICATION INFORMATION
The EMB1499Q and the EMB1428 work in conuction to control an active balancing circuit for up to 7 battery cells
connected in series. See Typical Application (Figure 1) for the typical system architecture. The EMB1499Q is a
PWM controller that regulates the inductor current in the bidirectional forward converter. The EMB1428 provides
12 floating gate drivers that are needed for the control of the FET switch matrix in the circuit. In a typical
application, the forward converter has the inductor side (also called “secondary side”, “floating side” or “high
side”) connected to the switch matrix and the other side (also called “primary side”, “non-floating side” or “low
side”) to the battery stack. With such an arrangement, every cell balancing action is an energy exchange
between a cell and the whole stack. The EMB1499Q can handle up to 56V between the top cell’s negative
terminal and the bottom of the stack (bottom cell negative terminal).
Driving the EN pin high initiates the normal operating cycle. Once EN goes high, the EMB1499Q drives the
DONE pin low. A normal operation cycle begins when the EMB1499Q DONE pin is driven low upon seeing the
EN pin go high. The IC will then set the DIR_RT pin to the logic opposite of the DIR pin. This completes the initial
handshaking with the EMB1428. The EMB1499Q will then start toggling the gate signals and the PWM_CLAMP
signal and ramp the inductor current toward the target current magnitude set by the VSET pin, and in the polarity
set by the DIR pin. After a few seconds (less than 8 sec.) of constant current operation, the EMB1499Q sees its
EN pin de-asserted by the EMB1428 and it will immediately start to ramp down the inductor current toward zero.
When the inductor current is typically 5% of steady state value, the EMB1499Q will pull the DONE pin high to the
EMB1428 that the forward converter has shut off. This completes one normal operation cycle for the EMB1499Q.
During operation, the DONE pin will be driven high and the converter shutdown if the following abnormalities are
detected during normal operation: over current, over voltage, under voltage, watchdog timeout, and thermal
shutdown. The EMB1428 will then assert its FAULT_INT to inform the system controller of this EMB1499Q Error
and read the fault code on the EMB1499Q FAULT pins.
To provide extra protection to the battery management system, the EMB1499Q has a built-in watchdog timer and
will automatically shut down the forward converter after 8 seconds of continuous operation. To keep charging or
discharging the same cell for more than 8 seconds, the microcontroller has to issue a stop and start command at
least once every 8 seconds.
The EMB1499Q needs two separate 12V supplies (10V to 14V) to function. One of the 12V supplies is
referenced to the stack ground and the other the floating ground.
Block Descriptions
This section contains descriptions of the individual circuit blocks in the EMB1499Q.
Voltage Domain Definitions
The EMB1499Q has been divided into two voltage domains. In this document the two domains are called the
upper voltage domain and the lower voltage domain.
The upper voltage domain refers to all circuitry that is referenced to GNDF, which is the floating ground. The
floating ground is connected to the bottom of the secondary side of the isolated converter. This is also the
negative side of the current cell being charged. The circuitry in this domain is powered by VINF, which is an
external floating supply. There is also an internal regulator powered from VINF that creates an internal floating
5V rail.
The lower voltage domain refers to all circuitry that is ground referenced. This domain is required to interface
with all signals to and from the microcontroller and EMB1428, as these signals are ground referenced. Most of
the circuitry in this domain is powered either directly from VINA or from an internal 5V rail powered by VINA. The
primary side driver is powered from VINP.
All interfaces between the upper and lower voltage domains require level shift circuitry implemented internally
within the EMB1499Q.
10
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FET Gate Drivers
The EMB1499Q includes one primary side gate driver and two secondary side gate drivers. A logic signal for the
driver of a primary side active clamp FET is also available. Input PWM signal for each of the three gate drivers is
level shifted from the internal digital supply rail (VDD) to the external power rail, either PVINF or VINP. Each
driver output buffer contains shoot through protection. All drivers are forced into an off state if any power rail
goes lower than the UVLO threshold.
Timing Generator
Depending on the desired direction of the balancing current (as dictated by the state of the DIR pin), the timing
generator will adjust the relative timing of the gate signals and PWM_CLAMP signal.
Based on the state of the DIR pin, the internal logic of the EMB1499Q assigns one of the gate signals as the
“control” signal and the others as the “synchronous” signals. The “control” signal is used to establish the required
duty cycle and the “synchronous” signals are timed relative to the “control” signal with the proper dead times or
overlap times. These two signal types are also treated differently by the internal logic for the purposes of startup,
shutdown, and fault handling.
Figure 6 and Figure 7 show typical relative timings for the gate signals in both balancing directions. Also noted in
each figure is the assignment of the “control” signal for the balancing current direction. Note that these diagrams
are ideal, indicating negligible capacitive loading on the pins. In reality, these gate signals would have finite rise
and fall times that are dictated by the CG of the external MOSFET and the output resistance of the internal driver
(consult the ELECTRICAL CHARACTERISTICS for the RON data).
GATE_LS
(Control)
GATE_HS1
95 ns
115 ns
95 ns
75 ns
GATE_HS2
PWM_CLAMP
115 ns
85 ns
Figure 6. Charge Direction (DIR high)
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115 ns
95 ns
GATE_HS1
(Control)
GATE_HS2
40 ns
PWM_CLAMP
85 ns
40 ns
100 ns
Figure 7. Discharge Direction (DIR low)
It should be noted here that for proper operation of the active clamp, an external delay network is required in
series with the external active clamp driver that delays the turn-on transition of the active clamp transistor (falling
edge of the PWM_CLAMP signal) by a specified amount. This is discussed in detail in the Application Hints.
PWM Controller Blocks
The DC voltage appearing at VREF (determined by applied to the VSET pin) sets the desired inductor current.
As can be seen in the Controller Block Diagram (Figure 4), the VREF voltage is transformed into a GNDF
referenced voltage through a current mirror (Iref, 25 μA) and that voltage is compared with the voltage across the
secondary side sense resistor. The difference between the two signals is fed to the error amplifier as the error
signal. The amplified and filtered/ compensated error signal becomes the current command signal and is
compared at the PWM comparator with sensed inductor current. The feedback loop forces the error toward zero
which means the inductor current will be regulated at the desired level set by VREF. The current sense amplifier
that senses the inductor current switches polarity when there is a change in the DIR logic level, so as to achieve
the bidirectional operation. There is also an internal soft start voltage ramp that forces a gradual turn-on and turnoff of the inductor current. The final reference appearing at the error amplifier is determined by the lower of the
said soft start voltage ramp and the voltage at VREF.
Current Limit Comparators
As shown in the Controller Block Diagram (Figure 4), both primary and secondary side currents of the forward
converter are internally turned into current sources by the current sense amplifiers. The current sources flow into
two resistors whose voltages are then compared with a 200mV reference by two current limit comparators. The
trigger point for both primary and secondary currents is typically 134mV across each sense resistor.
PWM Comparator
The EMB1499Q employs a Peak Current Mode control method. Basically the amplified inductor current
(IsenseHS) is compared to the current command (Icontrol) at the PWM comparator, generating the PWM signal
for gate drivers. To prevent a potential half-switching frequency (sub-harmonic) oscillation issue associated with
peak current control, an artificial ramp is added on top of the sensed inductor current before the latter is
compared with the current command.
12
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Startup Circuitry
The startup circuitry (Figure 5) performs three functions. The ramp generator charges an internal Cstart capacitor
during startup, generating a gradually increasing voltage ramp until the voltage reaches VSET value and is
clamped by it. This voltage ramp is used by the controller block to generate the ramp in the current reference
and bring up the inductor current in a soft start manner. The ramp generator also discharges the internal Cstart
capacitor during shutdown. The down slope in the VREF voltage as a result of the discharge will cause the
inductor current to ramp down gradually. Besides the ramp generator, there is also a comparator that will toggle
if the Cstart voltage dips below 100mV. This is to flag that the shutdown is considered complete. The startup
circuitry also generates a starthold pulse, which is a 10 μs long pulse that is activated upon the assertion of the
EN pin. While this pulse is active, the DONE and FAULT pins are held in the clear state, and the part is not
allowed to switch.
UVLO Blocks
The EMB1499Q has two under-voltage lockout (UVLO) blocks each monitoring one external 12V supply. Block
UVLO_LS monitors VINA with respect to GNDA and block UVLO_HS monitors VINF with respect to GNDF.
UVLO_HS will not be activated until UVLO_LS shows that VINA has crossed the UVLO rirsing threshold voltage.
UVLO_LS is activated if either EN is high or DONE is low. When UVLO_LS has a positive output, bias current is
sent to the UVLO_HS to activate it. Once both UVLOs have positive outputs, the internal chip enable signals are
activated, internal rails are powered up and gate drivers are unlocked.
Enable/Shutdown Sequencing
Shutdown Behavior
The standard shutdown sequence can be described as follows:
1. Initial State: DONE low, EN high, part operating in steady state.
2. The EMB1428 drops EN signal low.
3. Inductor current ramps down (typically 300 µs).
4. When inductor current has ramped sufficiently low, the EMB1499Q shuts down and DONE signal is asserted
high to tell the EMB1499Q that the shutdown process has finished, and can accept new commands.
5. DONE signal remains latched high, and is not cleared until the next enable sequence.
Enable Behavior
The standard enable sequence can be described as follows:
1. Initial State: DONE high, EN low, external supplies above UVLO voltage (from previous shutdown
sequence).
2. The EMB1428 asserts EN high.
3. EN activates the UVLO blocks, which then allow the internal rails to power up.
4. Internal “starthold” pulse remains high for first 10us, clears DONE latch and all fault latches.
5. When “starthold” drops low, part is allowed to start up normally, and all output latches are now free to be
clocked.
Fault Detection and Fault Codes
The fault detection circuitry of the EMB1499Q consists of a three-bit encoder which has as its input six different
fault modes. Its output is a digital word which is passed to the system microcontroller through the EMB1428. The
fault codes (FAULT[2:0])that are passed can be read as follows:
000 = No Fault 001 = Primary Side Current Limit
010 = Secondary Side Current Limit
011 = Thermal Shutdown
100 = Watchdog Timeout
101 = UVP Fault
110 = OVP Fault The fault detection process can be described as follows:
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1. Fault signals passed into the three-bit encoder
2. Internal fault signal passed to PWM logic and all gates are forced off and latched
3. Internal fault signal passed to the soft start comparator and asserts start-low, and therefore latches DONE
output high
4. Three-bit fault word is level shifted to the external supply, and external fault code is latched into output buffer
for FAULT 0..2 pins.
5. The EMB1428 reads the fault code on the FAULT 0..2 pins and drops EN voltage, shutting the EMB1499Q
down
6. Fault code and DONE signal remain latched until next startup cycle
Secondary OVP/UVP
This block senses the voltage of the cell being charged/discharged. If this voltage is outside a predefined range,
a fault is detected and the IC is disabled.
Current Limit Counter
The current limit counter monitors both the primary and secondary side current limit signals. The counter is reset
every 32 clock pulses. If a specified number of current limit events are detected (4 for primary side and 8 for
secondary side) within this 32 clock pulse window, a fault is flagged and the part is disabled.
Watchdog Timer
The purpose of this block is to create a maximum running time of 8 seconds for the chip. This timer is created by
using a string of flip-flops to count clock pulses. After 221 clock pulses (typically 8 seconds at 250kHz switching
frequency), if EN is still high, a fault is flagged and the IC is shut down.
Thermal Shutdown
This block senses the internal temperature of the die and flag output if that temperature exceeds a
predetermined threshold, TSD. If this fault flag is activated, the IC will shut down and charging operation will
cease.
Application Hints
Setting the Balancing Current (VSET and Secondary Sense Resistor)
If the secondary side of the forward converter is connected to battery cells via a switch matrix, the cell balancing
current is equal to the steady state value of the main inductor current. Two external parameters determine the
balancing current (Ibalancing): the voltage at the VSET pin and the secondary side sense resistance
(RSENSE2). The voltage at the VSET pin controls the reference voltage at the error amplifier, and therefore the
voltage at the VSENSE_HS pin. The equation for selecting the secondary side sense resistance is:
RSENSE2 =
VSENSEHS
Ibalancing
The equation for selecting the secondary side sense resistance is:
VSENSE_HS =
VSET
40
Supported values for VSET range from 1V to 2.2V. However, the EMB1499Q is factory trimmed at VSET = 2V.
Therefore, it is recommended to use VSET = 2V for highest balancing current accuracy. See ELECTRICAL
CHARACTERISTICS for specified tolerances on VSENSE_HS when for VSET = 2V and 1.2V. Due to switching
noise present at the secondary side current sense resistor, it is possible that current values are slightly different
for different directions of balancing, even if VSET is constant. In such a case, it is recommended that a
calibration be conducted at the system level so that a slightly different VSET is programmed when changing the
direction of balancing.
14
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Primary Sense Resistor Selection
The primary sense resistor should be chosen in conjunction with the secondary sense resistor so that the ratio
between the two resistors is approximately equal to the transformer turns ratio. For example if the secondary
sense resistor is 10mΩ, and the transformer turns ratio is 3.5:1 (recommended for a 14 cell application – see the
Transformer Selection section), the primary sense resistor should be chosen to be approximately 35mΩ.
Inductor Selection
The value of the inductor, along with the converter input/output voltages, determines the AC ripple of the inductor
current. A good practice is to choose an inductance value so that the peak-to-peak ripple falls somewhere
between 20% and 40% of the steady state balancing current during typical operation. If the transformer turns
ratio is selected properly (see the Transformer Selection section), and assuming a typical 250kHz switching
frequency, then the equation relating inductance to current ripple for the EMB1499Q can be reduced to:
L = 3 x 10-6sec-1 x VCELL x ΔiL
where VCELL is the typical cell voltage in the given application, and ΔiL is the peak-to-peak current ripple value.
The EMB1499Q utilizes peak current mode control, which means that the inductor current is sampled in real time
and used for loop control. In this type of control method, the slope of the sensed inductor current ripple is an
important parameter. This sensed slope is inversely proportional to the inductor value, and directly proportional to
the gain of the current sense path. In other words:
dISENSE RSENSE2Ai
D
dt
L
Where ISENSE is the sensed inductor current, RSENSE2 is the secondary side sense resistor value, and Ai is the
gain of the internal current sense amplifier.
In order to ensure stability of the internal current sense loop, it is recommended that the slope of the sensed
inductor current remain somewhat constant if external component values are changed. From the above equation,
this means that if the value of the secondary sense resistor is increased (possibly to achieve lower balancing
current), then the value of the output inductor should be increased with approximately the same scale.
In addition, it is important to choose an inductor that can support the peak output current without saturating.
Inductor saturation will cause a sudden reduction in the inductance value, and cause the converter to operate
incorrectly. It is also recommended to choose an inductor with minimal DC winding resistance in order to
minimize conduction losses and maximize efficiency.
Transformer Selection
The EMB1499Q is designed to work optimally with a transformer turns ratio of 3.5:1 when operating within a
stack of 14 cells. In order to maintain proper peak currents and voltage stresses on the drains of the power
MOSFETs, it is recommended that this relationship between turns ratio and number of cells be maintained. In
other words, follow the following equation when choosing a turns ratio for the transformer:
n = 0.25 x NumCells
In the typical application, the forward transformer for the EMB1499Q has a minimum primary side inductance of
190µH. To ensure proper operation, it is recommended to use this as the minimum inductance specification for a
14 cell solution. It is reasonable to scale this inductance with the number of cells in the stack. For example, for a
7 cell stack a minimum primary inductance of 95µH can be used. It is also recommended that the leakage
inductance of the transformer be less than or equal to 1% of the winding inductance.
In a typical 5A design, the primary side DC winding resistance should be less than typical 60mΩ, and the
secondary side resistance typical 12mΩ. In order to ensure reasonable efficiency and to ensure properly gauged
wires are used in the transformer, it is recommended to follow this specification. It is reasonable to scale these
resistance specifications for constant DC power dissipation with different balancing currents.
Power MOSFET Selection
For optimal balance transfer efficiency, the power MOSFETs should be selected to provide the lowest possible
conduction and switching power losses. For the purpose of MOSFET selection, a good criterion to use is the
tradeoff between switch on resistance (RDSON) and gate charge (QG). These parameters can be used to estimate
the total conduction and gate charge losses for each MOSFET, which should be minimized:
PLOSS = IRMS2 x RDSON + QG x FSW
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Where FSW is the switching frequency of the EMB1499Q (typically 250kHz), and IDS is the RMS drain current in
each MOSFET during steady state. The following equations can be used to provide a first order estimation of the
RMS drain current in each MOSFET: Primary switching NMOS:
IRMS
Ibalancing
| 2 x NumCells
Secondary switching NMOS:
IRMS |
Ibalancing
2
Active Clamp PMOS:
IRMS ≊ 25ms x VCELL_MAX
Where VCELL_MAX is the maximum operating voltage of any cell in the stack.
In addition to power dissipation concerns, and assuming that the transformer turns ratio has been chosen
correctly (see the Transformer Selection section), the power MOSFETs have the following additional
requirements:
• All power MOSFETS must have absolute max rating for VGS of at least 20V
• Primary MOSFETS (switching and active clamp) must have drain-source voltage rating of at least 2.5 times
the maximum operating stack voltage.
• Secondary MOSFETs must have a drain-source voltage rating of at least 30V, gate resistance no more than
3Ω, and be avalanche robust (i.e., have an Avalanche Energy rating (EAR) specified in the datasheet).
Input Capacitor Selection
Ceramic capacitors are required for proper operation due to their low ESR (equivalent series resistance). The
voltage rating of the capacitor should exceed the maximum stack voltage in an application with proper de-rating.
For example, in a 14 cell Li-ion application, the maximum stack voltage would be approximately 60V. Therefore,
a 100V rated capacitor would be recommended. It is advisable to use at least 6.6µF of capacitance. Optimum
performance will be achieved by using multiple smaller value capacitors in parallel to minimize series resistance
and inductance.
For proper performance, X5R or X7R ceramics are recommended.
Output Capacitor Selection
As with the input capacitors, ceramic capacitors are required (X5R or X7R recommended). Since the maximum
operating cell voltage of a Li-ion cell is 4.2V, a voltage rating of 6.3V or higher is recommended.
It is required to use at least 10µF of capacitance. Optimum performance will be achieved by using multiple
smaller value capacitors in parallel to minimize series resistance and inductance.
Clamp Capacitor Selection
As with the input and output capacitors, a ceramic capacitor is also required for the clamp capacitor. Assuming
that the transformer turns ratio has been chosen correctly (see the Transformer Selection section), the voltage
rating of the capacitor should be at least 2.5 times the maximum operating voltage of the battery stack.
For example, in a 14 cell solution with a maximum operating cell voltage of 4.2V, the maximum operating voltage
of the stack is 58.8V. Therefore, the voltage rating of the capacitor should be at least 2.5 * 58.8V = 147V. So for
a 14 cell solution, a voltage rating of 200V (the next closest common voltage rating) is recommended. The
recommended capacitance value for the clamp capacitor is 0.1µF.
Active Clamp Driver
The active clamp driver path consists of a delay circuit, gate driver, and a passive level shifting network. See
Figure 8 below for the recommended circuit.
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The delay network should provide approximately 300ns to 400ns delay to the turn-on transition of the clamp
PFET, and minimal delay to the turn-off transition. The recommended driver for this application is the EMB1412
from Texas Instruments. It is important to configure the driver in an inverting configuration. A passive levelshifting network is required in order to provide a negative gate voltage for the clamp PFET. It consists of a 0.1µF
AC coupling capacitor, a clamping diode, and a 1kΩ resistor to provide a DC path to ground for the gate of the
clamp PFET.
Level Shifting Network
Gate Driver
Level Shifting Network
+12V
25.5 k:
PWM_CLAMP
Signal From
EMB1499
0.1 PF
U1
U2
To Clamp
FET
47 pF
Figure 8. Active Clamp Driver Circuit
Continuous Balancing Operation
If it is desired to continually balance a particular cell for longer than the internal watchdog timeout of the
EMB1499Q (typically 8 seconds), the EN pin of the EMB1499Q needs to be toggled within a period less than 8
seconds.
At the system level, this can be done by sending a “stop balancing” command to the EMB1428 gate driver chip,
followed by “start balancing” command prior to the EMB1499Q timeout. Simply sending a new “start balancing”
command without first sending the “stop balancing” command will not cause the EN pin of the EMB1499Q to
toggle. If the EN pin does not toggle, the balancing will time out.
PCB Layout Recommendations
Besides following general switching power supply layout practices, below are recommendations for the
EMB1499Q:
1. Run the gate traces in parallel with their associated ground planes for as much of the total runs as possible
2. Keep current sensing traces away from high dv/dt nodes such as the drains of power FETs
3. Place adequate copper underneath power FETs to help with thermal dissipation
4. Place numerous 8-mil vias in the PCB pad beneath the EMB1499Q and connect them to the corresponding
ground plane(s) on all layers to help with thermal dissipation
5. Place the EMB1499Q within a couple inches of the power FETs to reduce board parasitics.
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REVISION HISTORY
Changes from Revision A (May 213) to Revision B
•
18
Page
Changed package drawing from PW to PWP, and package type from TSSOP to HTSSOP .............................................. 2
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PACKAGE OPTION ADDENDUM
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31-Oct-2013
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)
EMB1499QMH/NOPB
ACTIVE
HTSSOP
PWP
28
48
Green (RoHS
& no Sb/Br)
CU SN
Level-1-260C-UNLIM
-40 to 125
EMB1499
QMH
EMB1499QMHE/NOPB
ACTIVE
HTSSOP
PWP
28
250
Green (RoHS
& no Sb/Br)
CU SN
Level-1-260C-UNLIM
-40 to 125
EMB1499
QMH
EMB1499QMHX/NOPB
ACTIVE
HTSSOP
PWP
28
2500
Green (RoHS
& no Sb/Br)
CU SN
Level-1-260C-UNLIM
-40 to 125
EMB1499
QMH
(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
Addendum-Page 1
Samples
PACKAGE OPTION ADDENDUM
www.ti.com
31-Oct-2013
continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals.
TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release.
In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis.
Addendum-Page 2
PACKAGE MATERIALS INFORMATION
www.ti.com
31-Oct-2013
TAPE AND REEL INFORMATION
*All dimensions are nominal
Device
Package Package Pins
Type Drawing
SPQ
Reel
Reel
A0
Diameter Width (mm)
(mm) W1 (mm)
EMB1499QMHE/NOPB
HTSSOP
PWP
28
250
178.0
16.4
EMB1499QMHX/NOPB
HTSSOP
PWP
28
2500
330.0
16.4
Pack Materials-Page 1
B0
(mm)
K0
(mm)
P1
(mm)
W
Pin1
(mm) Quadrant
6.8
10.2
1.6
8.0
16.0
Q1
6.8
10.2
1.6
8.0
16.0
Q1
PACKAGE MATERIALS INFORMATION
www.ti.com
31-Oct-2013
*All dimensions are nominal
Device
Package Type
Package Drawing
Pins
SPQ
Length (mm)
Width (mm)
Height (mm)
EMB1499QMHE/NOPB
HTSSOP
PWP
EMB1499QMHX/NOPB
HTSSOP
PWP
28
250
210.0
185.0
35.0
28
2500
367.0
367.0
35.0
Pack Materials-Page 2
MECHANICAL DATA
PWP0028A
MXA28A (Rev D)
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