LT8584 - 2.5A Monolithic Active Cell Balancer with Telemetry Interface

LT8584
2.5A Monolithic Active Cell
Balancer with Telemetry Interface
Description
Features
2.5A Typical Average Cell Discharge Current
n Integrated 6A, 50V Power Switch
n Integrates Seamlessly with LTC680x Family:
No Additional Software Required
n Selectable Current and Temperature Monitors
n Ultralow Quiescent Current in Shutdown
n Engineered for ISO 26262 Compliant Systems
n Isolated Balancing:
n Can Return Charge to Top of Stack
n Can Return Charge to Any Combination of Cells
in Stack
n Can Return Charge to 12V Battery for Alternator
Replacement
n Can Be Paralleled for Greater Discharge Capability
n All Quiescent Current in Operation Taken from Local Cell
n16-Lead TSSOP Package
n
Applications
n
n
n
n
Active Battery Stack Balancing
Electric and Hybrid Electric Vehicles
Fail-Safe Power Supplies
Energy Storage Systems
Typical Application
MODULE +
The LT8584 includes an integrated 6A, 50V power switch,
reducing the design complexity of the application circuit.
The part runs completely off of the cell which it is discharging, removing the need for complicated biasing schemes
commonly required for external power switches. The enable
pin (DIN) of the part is designed to work seamlessly with
the LTC680x family of battery stack voltage monitoring
ICs. The LT8584 also provides system telemetry including
current and temperature monitoring when used with the
LTC680x family of parts. When the LT8584 is disabled, less
than 20nA of total quiescent current is typically consumed
from the battery.
L, LT, LTC, LTM, Linear Technology and the Linear logo are registered trademarks and Hot
Swap and isoSPI are trademarks of Linear Technology Corporation. All other trademarks are the
property of their respective owners. Protected by U.S. Patents, including 6518733 and 6636021.
12-Cell Battery Stack Module with Active Balancing
2.5A AVERAGE
DISCHARGE
+
The LT®8584 is a monolithic flyback DC/DC converter designed to actively balance high voltage stacks of batteries.
The high efficiency of a switching regulator significantly
increases the achievable balancing current while reducing
heat generation. Active balancing also allows for capacity recovery in stacks of mismatched batteries, a feat unattainable
with passive balance systems. In a typical system, greater
than 99% of the total battery capacity can be recovered.
BAT 12
MODULE +
•
•
MODULE –
V+
READ CELL PARAMETERS
LT8584
ENABLE BALANCING
2.5A AVERAGE
DISCHARGE
+
BAT 2
MEASURABLE CELL
PARAMETERS
• VCELL
• IDISCHARGE
• VREF
• TEMPERATURE
EXTRACTABLE CELL
PARAMETERS
• RCABLE + RCONNECTOR
• SWITCHING FAULTS
• UNDERVOLTAGE
• SERIAL FAULTS
• COULOMB COUNTING
MODULE +
•
MODULE –
READ CELL PARAMETERS
ENABLE BALANCING
2.5A AVERAGE
DISCHARGE
BAT 1
C12
S12
•
LT8584
+
LTC6804
BATTERY STACK
MONITOR
C2
S2
MODULE +
•
•
MODULE –
READ CELL PARAMETERS
LT8584
ENABLE BALANCING
C1
S1
V–/C0
LT8584 TA01a
MODULE –
8584fb
For more information www.linear.com/LT8584
1
LT8584
Absolute Maximum Ratings
Pin Configuration
(Note 1)
DIN to GND Voltage.................................................. ±10V
VIN, VCELL, VSNS, MODE, OUT,
DCHRG Voltage............................................. –0.3V to 9V
RTMR Voltage..................................................... (Note 2)
SW Voltage (Note 3)................................... –0.4V to 50V
VIN – VCELL Voltage.............................................±200mV
VIN – VSNS Voltage..............................................±200mV
MODE – VIN Voltage..............................................200mV
VSNS, MODE Pin Current......................................... ±1mA
VCELL, OUT Pin Current......................................... ±10mA
SW Pin Negative Current...........................................–2A
Operating Junction Temperature Range (Note 4)
LT8584E.................................................. –40°C to 125°C
LT8584I.................................................. –40°C to 125°C
LT8584H................................................. –40°C to 150°C
Storage Temperature Range................... –65°C to 150°C
Lead Temperature (Soldering, 10 sec).................... 300°C
TOP VIEW
GND
1
16 SW
GND
2
15 SW
GND
3
14 SW
GND
4
MODE
5
RTMR
6
11 VSNS
DIN
7
10 VCELL
OUT
8
9
17
GND
13 SW
12 DCHRG
VIN
FE PACKAGE
16-LEAD PLASTIC TSSOP
TJMAX = 150°C, θJA = 38°C/W
EXPOSED PAD (PIN 17) IS GND, MUST BE SOLDERED TO PCB
Order Information
LEAD FREE FINISH
TAPE AND REEL
PART MARKING*
PACKAGE DESCRIPTION
TEMPERATURE RANGE
LT8584EFE#PBF
LT8584EFE#TRPBF
8584FE
16-Lead Plastic TSSOP
–40°C to 125°C
LT8584IFE#PBF
LT8584IFE#TRPBF
8584FE
16-Lead Plastic TSSOP
–40°C to 125°C
LT8584HFE#PBF
LT8584HFE#TRPBF
8584FE
16-Lead Plastic TSSOP
–40°C to 150°C
Consult LTC Marketing for parts specified with wider operating temperature ranges. *The temperature grade is identified by a label on the shipping container.
For more information on lead free part marking, go to: http://www.linear.com/leadfree/
For more information on tape and reel specifications, go to: http://www.linear.com/tapeandreel/
2
8584fb
For more information www.linear.com/LT8584
LT8584
Electrical
Characteristics
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. VIN = 4.2V, DIN = GND unless otherwise noted. (Note 4)
PARAMETER
CONDITIONS
VIN Recommended Voltage Range
Switching
Nonswitching
VIN Quiescent Current
Switching
Nonswitching
In Shutdown, DIN = OUT
In Shutdown, DIN = OUT
MIN
l
l
2.5
2.45
l
l
2.1
Switch DC Current Limit
l
6
Current Limit Blanking Time
ISW = 4A
Switch Leakage Current
VSW = 4.2V
VSW = 4.2V
6.3
3
90
1
UNITS
V
mA
mA
nA
µA
2.45
V
6.8
A
450
ns
200
mV
5
l
70
4
nA
µA
l
30
50
70
µs
l
0.5
0.85
1.2
µs
ISW = 2mA
ISW = 6A
42
45
50
48
V
V
Note 6
80
200
360
ns
95
150
mV
100
180
ns
Switch Maximum On Time
Switch Short Detection Timeout
Note 5
Switch Clamp Voltage
Switch Clamp Blanking Time
DCM Comparator Trip Voltage
VSW – VVIN
l
DCM Comparator Propagation Delay
200mV Overdrive
l
40
DCM Blanking Time
230
MODE Threshold
DIN Shutdown Threshold
MAX
5.3
5.3
45
2.5
1
l
VIN UVLO
Switch VCESAT
TYP
ns
1.7
1
1.2
V
1.4
V
High → Low, Referred to GND
l
DIN Data Threshold
High → Low, VTH = VOUT – VDIN, MODE = 0V
l
0.3
0.7
0.9
V
DIN Data Threshold Hysteresis
VTH = VOUT – VDIN, MODE = 0V
l
20
80
160
mV
DIN Pin Current
VDIN = 0V
VDIN = –1V
l
–6
–18
–3
–14
–1
–6
µA
µA
DCHRG Threshold
MODE Tied to VIN
l
0.5
0.8
1.1
V
DIN Shutdown Threshold Hysteresis
100
mV
100
mV
300
µA
300
µA
1.22
V
DCHRG Hysteresis
MODE Tied to VIN
DCHRG Pull-down Current
Pin Voltage = 0.4V
l
220
DCHRG Pull-up Current
Pin Voltage = VIN – 0.4V
l
220
RMTR Pin High Voltage
RRTMR = 50kΩ
RMTR Pin Low Voltage
RRTMR = 50kΩ
0
V
VCELL Switch RDSON
55
Ω
VSNS Dynamic Input Range
Gain Error ≤ 8%
l
–30
70
mV
VSNS Average Input Range
Gain Error ≤ 3%
l
15
45
mV
–1.1
VSNS Amplifier Input Referred Offset
VCELL – VSNS = 40mV
l
VSNS Amplifier Gain
Over VSNS Average Input Range
l
18.7
Handshake Voltage Error
Measured ± with Respect to:
VMODE1 = 0.2V
VMODE2 = 0.4V
VMODE3 = 0.6V
VMODE4 = 0.8V
VSW,ERR = 1.2V
VFAULT = 1.4V
VFAULT = 1.4V
l
l
l
l
l
l
–13
–14
–18
–22
–31
–35
–28
19
1.1
mV
19.3
V/V
13
14
18
22
31
35
28
mV
mV
mV
mV
mV
mV
mV
8584fb
For more information www.linear.com/LT8584
3
LT8584
Electrical
Characteristics
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. VIN = 4.2V, DIN = GND unless otherwise noted. (Note 4)
PARAMETER
CONDITIONS
MIN
TYP
MAX
0.75
UNITS
Handshake Voltage Line Regulation
From VVIN = 2.5V to VVIN = 4.2V
0.2
VTEMP Temperature Coefficient (TC)
Note 7, °K = (VCELL – VTEMP)/TC
2
%/V
VTEMP
VTEMP = VIN – VOUT, TJ = 25°C
0.658
V
OUT Pin Clamp Voltage
10mA Sourced from Pin
l
1.53
1.6
V
OUT Pin Amplifier Load Regulation
IOUT = 10µA to 1mA
l
0
0.2
mV/°K
0.4
%/mA
Timing
Characteristics
The l denotes the specifications which apply over the full operating temperature
range, otherwise specifications are at TA = 25°C. MODE = 0V. Refer to Timing Diagram for parameter definition. (Note 4)
SYMBOL
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
l
l
l
l
tW
Decode Window Duration
RRTMR = 10kΩ
RRTMR = 50kΩ
RRTMR = 100kΩ
RRTMR = 200kΩ
1.76
8
15.6
29.3
1.86
8.4
16.4
31.5
1.96
8.8
17.2
33.7
ms
ms
ms
ms
tRST
Decode Window Range
l
1.76
33.7
ms
DIN Serial Communication Reset Time
l
10
t1
RTMR Start-Up Time
t2
t3
t4
DIN Low Time
t5
Discharger Activation Time
t6
Discharger Deactivation Time
SR
DIN Slew Rate
RRTMR = 10kΩ
1.8
l
5
µs
DIN Hold-Off Time
l
50
µs
DIN High Time
l
50
µs
l
50
RRTMR = 10kΩ
l
Note 1: Stresses beyond those listed under Absolute Maximum Ratings
may cause permanent damage to the device. Exposure to any Absolute
Maximum Rating condition for extended periods may affect device reliability
and lifetime.
Note 2: Do not apply a positive or negative voltage or current source to
RTMR, otherwise permanent damage may occur.
Note 3: ABSMAX rating refers to the maximum DC + AC leakage spike. Do
not exceed 40VDC on any of the SW pins.
Note 4: The LT8584E is guaranteed to meet performance specifications
from 0°C to 125°C junction temperature. Specifications over the –40°C
to 125°C operating junction temperature range are assured by design,
characterization, and correlation with statistical process controls. The
LT8584I is guaranteed over the full –40°C to 125°C operating junction
temperature range. The LT8584H is guaranteed over the full –40°C to
150°C operating junction temperature range.
4
µs
9
µs
900
ns
2.1
µs
V/ms
Note 5: This is a measure of time duration from the onset of the switch
turning on to the time the short-circuit protection circuit is disabled. If the
current comparator trips during this duration, the switch error latch is set.
This indicates that the connection to the transformer primary is most likely
shorted.
Note 6: This is a measure of time duration for the switch clamp to operate
continuously without setting the switch error latch. If the switch clamp
remains engaged longer than the switch clamp blanking time, the switch
error latch is set and switching is disabled.
Note 7: The voltage proportional to temperature (VTEMP) is measured
on the OUT pin while in analog multiplexer MODE 3 or 4. VTEMP must be
subtracted from the VCELL voltage that is measured while in analog mux
MODE 1. Both measurements should be taken within 100ms of each other
to reduce errors in absolute temperature calculation.
8584fb
For more information www.linear.com/LT8584
LT8584
Typical Performance Characteristics
TA = 25°C, VIN = VCELL = VSNS = 4.2V, unless otherwise noted.
VIN Pin Current
Switching Disabled
5
DIN = 0V, PART ENABLED
ENABLED CURRENT (mA)
2.4
2.3
2.2
2.1
2.0
–60
–20
20
60
100
TEMPERATURE (°C)
4
3
0.4
2
0.2
1
0
140
0.6
2
4
6
PIN VOLTAGE (V)
8584 G01
Switch Current Limit
CURRENT (A)
6.2
5.8
5.4
2.1
–20
20
60
100
TEMPERATURE (°C)
5.0
–60
140
–20
60
100
20
TEMPERATURE (°C)
8584 G04
48
53
44
42
40
–60
Switch Clamp Voltage (ISW = 6A)
60
100
20
TEMPERATURE (°C)
140
8584 G07
0.4
30
0.3
25
–20
20
60
100
TEMPERATURE (°C)
140
20
DCM Comparator Threshold
130
110
51
49
90
70
47
–20
35
8584 G06
VOLTAGE (mV)
55
VOLTAGE (V)
50
46
0.5
0.2
–60
140
40
ISW = 5.8A
8584 G05
Switch Maximum On-Time
TIME (µs)
Switch Characteristics
0.6
6.6
2.2
140
BETA (A/A)
VOLTAGE (V)
2.5
2.3
60
100
20
TEMPERATURE (°C)
8584 G03
7.0
2.4
–20
8584 G02
VIN Internal UVLO
2.0
–60
2
0
–60
VCE,SAT (V)
2.6
3
1
0
8
DIN = OUT
DCHRG = 0V
MODE = VIN
4
SHDN CURRENT (mA)
CURRENT (mA)
2.5
5
0.8
CURRENT (µA)
2.6
Total Input Leakage
IVIN + IVCELL + IVSNS + ISW
VIN Pin Current
45
–60
–20
60
100
20
TEMPERATURE (°C)
140
8584 G08
50
–60
–20
20
60
100
TEMPERATURE (°C)
140
8584 G09
8584fb
For more information www.linear.com/LT8584
5
LT8584
Typical Performance Characteristics
TA = 25°C, VIN = VCELL = VSNS = 4.2V, unless otherwise noted.
DIN Pin Current
DIN Pin Current
180
DIN SHDN Threshold
0
1.6
150
90
60
–10
0
–10
–8
–6
–4
–2
0
DIN VOLTAGE (V)
2
–15
–60
4
–20
20
60
100
TEMPERATURE (°C)
8584 G10
0.8
–60
140
0.4
0.2
RISING
350
0.6
FALLING
0.4
0
–60
–20
60
100
20
TEMPERATURE (°C)
RESISTANCE (Ω)
VOLTAGE (V)
100
1.4
60
100
20
TEMPERATURE (°C)
140
8584 G16
6
1.0
VCELL = 2.5V
VCELL = 3V
VCELL = 3.6V
VCELL = 4.2V
80
60
20
–60
20
60
100
TEMPERATURE (°C)
140
VTEMP
0.9
40
–20
–20
8584 G15
VCELL Switch RDS(ON)
120
2.0
1.2
–60
200
–60
140
VCELL – VOUT (V)
MODE Pin Threshold
2.2
1.6
SINK
8584 G14
8584 G13
1.8
SOURCE
300
250
0.2
140
140
400
CURRENT (µA)
VOLTAGE (V)
VOUT – VDIN (V)
RISING
60
100
20
TEMPERATURE (°C)
DCHRG Drive Current (Serial
Mode)
FALLING
0.6
–20
8584 G12
1.0
0.8
60
100
20
TEMPERATURE (°C)
FALLING
DCHRG Threshold (Simple Mode)
0.8
–20
1.2
8584 G11
DIN Data Threshold
0
–60
RISING
1.0
VDIN = –1V
30
1.0
1.4
–5
VOLTAGE (V)
CURRENT (µA)
CURRENT (µA)
VDIN = 0V
120
0.8
0.7
0.6
0.5
–20
60
100
20
TEMPERATURE (°C)
140
8584 G17
0.4
–60
–20
60
100
20
TEMPERATURE (°C)
140
8584 G18
8584fb
For more information www.linear.com/LT8584
LT8584
Typical Performance Characteristics
TA = 25°C, VIN = VCELL = VSNS = 4.2V, unless otherwise noted.
1200
VSNS Transfer Function
VSNS Amplifier
Input Referred Offset
VSNS Amplifier Gain
19.50
500
19.25
250
600
OFFSET (µV)
800
GAIN (V/V)
VCELL – VOUT (mV)
1000
19.00
400
18.75
0
–250
200
0
0
10
30
40
50
20
VCELL – VSNS (mV)
60
18.50
–60
70
8584 G19
20
60
100
TEMPERATURE (°C)
140
–500
–60
10
–10
–60
–20
20
60
100
TEMPERATURE (°C)
3
0.25
2
0.20
1
ERROR (%)
REGULATION (%/V)
SW, ERR
FAULT
MODE4
MODE3
MODE2
MODE1
140
Decode Window Duration Error
0.30
100k
50k
5
–5
20
60
100
TEMPERATURE (°C)
8584 G21
Handshake Voltage
Line Regulation
0
–20
8584 G20
Handshake Voltage Error
ERROR VOLTAGE (mV)
–20
0.15
0
0.10
–1
0.05
–2
0
–60
140
–20
8584 G22
60
100
20
TEMPERATURE (°C)
10k
–3
–60
140
–20
60
100
20
TEMPERATURE (°C)
8584 G24
8584 G23
OUT Pin Clamp Voltage
IOUT = 10mA
OUT Pin Amplifier
1% Settling Time, COUT = 220nF
OUT Pin Amplifier Drive Current
2.0
140
10
400
9
300
1.6
1.4
7
SINK
6
5
SOURCE
4
1.2
TIME (µs)
8
CURRENT (mA)
VIN – VOUT (V)
1.8
VIN – VOUT =
1.4V → 0.2V
200
VIN – VOUT =
0V → 1.4V
100
3
1.0
–60
–20
60
100
20
TEMPERATURE (°C)
140
8584 G25
2
–60
–20
60
100
20
TEMPERATURE (°C)
140
8584 G26
0
–60
–20
20
60
100
TEMPERATURE (°C)
140
8584 G27
8584fb
For more information www.linear.com/LT8584
7
LT8584
Typical Performance Characteristics
TA = 25°C, VIN = VCELL = VSNS = 4.2V, unless otherwise noted.
Switching Waveform
Average Discharge Current
2.6
T1 = NA5920-AL
D1 = 2 SERIES ES1J
2.4
ISW
2A/DIV
2µs/DIV
T1 = NA5920-AL
D1 = 2 SERIES ES1J
VCELL = 4.2V
VSTACK = 400V
8584 G28
2.0
1.8
1.6
1.4
50
100 150 200 250 300 350
STACK VOLTAGE (VSTACK+ – VSTACK–)
80
75
VCELL = 2.5V
VCELL = 3V
VCELL = 3.6V
VCELL = 4.2V
1.2
1.0
T1 = NA5920-AL
D1 = 2 SERIES ES1J
85
2.2
EFFICIENCY (%)
DISCHARGE CURRENT (A)
VSW
10V/DIV
Conversion Efficiency
90
70
400
VCELL = 2.5V
VCELL = 3V
VCELL = 3.6V
VCELL = 4.2V
50
Average Discharge Current
3.0
ISW
2A/DIV
2µs/DIV
T1 = NA5743-AL
D1 = ES1D
VCELL = 3.6V
VMODULE = 40V
RCD SNUBBER = 4.99kΩ, 22nF
8584 G31
T1 = NA5743-AL
D1 = ES1D
2.8
2.4
30
30
8584 G34
Conversion Efficiency
90
T1 = NA6252-AL
D1 = STPS3H100U
2.8
2.6
2.4
10
15
20
25
30
AUXILLARY VOLTAGE (V)
80
75
VCELL = 2.5V
VCELL = 3V
VCELL = 3.6V
VCELL = 4.2V
2.2
2.0
T1 = NA6252-AL
D1 = STPS3H100U
85
EFFICIENCY (%)
DISCHARGE CURRENT (A)
ISW
2A/DIV
40
50
60
70
80
MODULE VOLTAGE (VMODULE+ – VMODULE–)
8584 G33
Average Discharge Current
VSW
10V/DIV
8
70
40
50
60
70
80
MODULE VOLTAGE (VMODULE+ – VMODULE–)
VCELL = 2.5V
VCELL = 3V
VCELL = 3.6V
VCELL = 4.2V
8584 G32
3.0
T1 = NA6252-AL
D1 = STPS3H100U
VCELL = 4.2V
VAUX = 13.8V
RCD SNUBBER = 4.99kΩ, 22nF
80
75
VCELL = 2.5V
VCELL = 3V
VCELL = 3.6V
VCELL = 4.2V
2.2
2.0
T1 = NA5743-AL
D1 = ES1D
85
2.6
Switching Waveform
2µs/DIV
Conversion Efficiency
90
EFFICIENCY (%)
DISCHARGE CURRENT (A)
VSW
10V/DIV
400
8584 G30
8584 G29
Switching Waveform
100 150 200 250 300 350
STACK VOLTAGE (VSTACK+ – VSTACK–)
35
8584 G35
70
VCELL = 2.5V
VCELL = 3V
VCELL = 3.6V
VCELL = 4.2V
6
12
18
24
30
AUXILLARY VOLTAGE (V)
36
8584 G36
8584fb
For more information www.linear.com/LT8584
LT8584
Pin Functions
GND (Pin1, Pin 2, Pin 3, Pin 4, Pin 17): Must be soldered
directly to local ground plane.
MODE (Pin 5): Serial Enable Pin. Connect this pin to
ground to enable serial interface for analog mux control.
Connect this pin to VIN to disable the analog mux. When
the analog mux is disabled, the OUT pin defaults to VTEMP
measurement. Do not float this pin.
RTMR (Pin 6): Serial Interface Timer Pin. Place a resistor
from this pin to ground to set the serial count duration
window, tW. See the Applications Information section for
proper resistor selection.
DIN (Pin 7): Data Input Pin. Take this pin to ground to
initiate switching if MODE pin is connected to VIN, or to
select the desired analog mux state if MODE pin is tied
to ground. This pin is designed to be directly driven from
the LTC680x family’s S pins.
OUT (Pin 8): Analog Output Pin. Connect this pin to an
accurate voltage monitor to measure a voltage proportional to the internal IC temperature, VTEMP, if MODE pin
is connected to VIN, or measure the output of the internal
analog mux if MODE pin is connected to ground. In analog
mux mode, the OUT pin allows voltage monitoring of the
VCELL pin, the VSNS pin, or VTEMP. This pin is designed
to be directly connected to the LTC680x family’s C pins.
Must connect a compensation capacitor to this pin. See
the Applications Information section for proper capacitor
sizing and placement.
VIN (Pin 9): Supply Pin. Connect this pin directly to the
positive battery cell terminal. Must be bypassed with high
grade (X5R or better) ceramic capacitor placed close to
the transformer’s primary winding connection.
VCELL (Pin 10): Cell Voltage Monitor Pin. This pin provides
a Kelvin connection to the battery cell for accurate voltage
monitoring. Connect this pin directly to the positive battery
cell terminal. The recommended cell voltage is 2.5V to 5.3V.
VSNS (Pin 11): Voltage Sense Pin. Connect this pin to the
current sense resistor connected to the primary side of
the transformer. Use this pin to measure average current
discharged from battery cell (see the Block Diagram). MODE
pin must be connected to ground and the internal analog
mux must have the VSNS pin selected to use this feature.
Input current is determined as (VVCELL – VVSNS)/RSNS.
DCHRG (Pin 12): Discharge Pin. The Discharge pin can
be configured as an input or output pin. Connect MODE
pin to ground to configure DCHRG as an output pin where
DCHRG is driven to VIN during switching and driven
to ground when switching is deactivated. The output
configuration can be used to drive multiple LT8584’s or
other switching regulators in parallel, to boost discharge
capability. Connect MODE pin high to configure DCHRG as
an input. When configured as an input pin, drive DCHRG
pin to VIN to enable switching. Note in this mode that serial communication is disabled and the DIN pin must be
grounded to initiate switching.
SW (Pin 13, Pin 14, Pin 15, Pin 16): Switch Pin. This
is the collector of the internal 6A NPN power switch.
Minimize the metal trace area connected to this pin to
minimize EMI. Connect the bottom side of the transformer
primary to this pin.
8584fb
For more information www.linear.com/LT8584
9
10
For more information www.linear.com/LT8584
CFBO
RRTMR
TO PARALLEL
DISCHARGERS
(OPTIONAL)
MODULE–
–
VMODULE
+
MODULE+
•
•
VSW
RTMR
MODE
1.22V
40mV
–+
6.3mΩ
SW
DCHRG
Q1
T1
–
+
–
+
A3
VIN
VIN
SIMPLE
MODE
SERIAL
MODE
A1
TIMER
A2
LATCH
POWER
DURING
TIMER
VIN
DIE
TEMPERATURE
VSNS AMP
VVIN – 1.4V
VTEMP
VVIN – 1.2V
VVIN – 0.8V
VVIN – 0.6V
VVIN – 0.4V
ANALOG MUX
–+
1V
CHIP
ENABLE
VVIN – 0.2V
+–
95mV
TO S PIN (LTC680x)
DIN
VCELL
– +
DCM
COMPARATOR
SWITCH
PROTECTION
CIRCUITRY
11-BIT
COUNTER
CONTROL LOGIC
Q
R SWITCH S
LATCH
CURRENT
COMPARATOR
CTRAN
+
–
D1
+
–
CHIP
POWER
M1
TO ANALOG
MUX
CVIN
+
–
1.6V
M2
VIN
+
–
–
+
5kΩ
OUT PIN CLAMP
19x
VSNS AMP
8584 BD
GND
OUT
VCELL
VSNS
RSNS
CELL
BEING
BALANCED
CELL BELOW
COUT
TO C PIN
LTC680x
CVCELL
CELL ABOVE
LT8584
Block Diagram
8584fb
LT8584
Timing Diagram
DIN
SR
tRST
t2
t3
t4
t6
RTMR
t1
tW
DCHRG
t5
8584 TD
Operation
Many systems use multiple battery cells connected in series to increase the available capacity and voltage. In such
systems, the individual battery cells must be constantly
monitored to ensure that they operate within a controlled
range. Otherwise, the battery’s capacity and life span may
be compromised. Linear Technology offers the LTC680x
family series of multicell battery stack monitors (BSM) to
accomplish this task.
The LTC680x monitors each individual cell in the stack
and communicates this information through a proprietary
serial bus to a central processing unit. As a cell begins to
reach the upper charge limit, commands are issued to the
LTC680x to turn on that cell’s passive shunt, bypassing
the charging current to that cell and allowing the current to
continue to the rest of the cells. The passive shunt current
and/or power capability constrains the maximum charging
current for the battery stack. Using a passive shunt is also
inefficient, and the shunted current produces considerable
heat at higher charging currents.
The LT8584 solves the two limitations of passive shunting
balancers by actively shunting the charging current and
returning the energy back to the battery stack. Instead of
the energy being lost as heat, it is reused to charge the
rest of the batteries in the stack. The architecture of the
LT8584 also solves the problem of reduced run time when
one or more of the cells in the stack reaches the lower
safety voltage threshold before the entire stack capacity
is extracted. Only active balancing can redistribute the
charge from the stronger cells (cells with higher voltage)
to charge the weaker cells. This allows the weaker cells to
continue to supply the load, extracting greater than 96%
of entire stack capacity where passive balancing may only
extract 80%.
The LT8584 has an integrated 6A switch designed to operate
as a boundary mode flyback converter and provides 2.5A
average discharge current. The average discharge current
is also scalable by using multiple LT8584s to balance each
cell. Note that each battery in the stack requires an LT8584
active cell balancer.
The LT8584 flyback topology allows the charge to return
between any two points in the battery stack. Most applications use a module approach and return the charge to a
local set of 12 series-connected cells monitored by a 12
channel BSM IC, where the output of the flyback converter
is designated as VMODULE. The entire battery stack is then
constructed using several 12-cell modules connected in
series. A second approach is to return the charge to the
entire battery stack, where the flyback output is designated as VSTACK. A final option is to return the charge to
an auxiliary power rail, designated as VAUX.
The LT8584 has two modes of operation—selectable by
the MODE pin—that can be integrated with the LTC680x
or other battery stack system. In simple mode, the LT8584
8584fb
For more information www.linear.com/LT8584
11
LT8584
Operation
discharger is toggled on/off using a logic input pin. In
serial mode, the LT8584 allows the user to measure the
discharge current and the die temperature, in addition to
the cell voltage.
ILPRI
VVIN – VCESAT
LPRI
IPK
General Flyback Operation
t
The first cycle will commence approximately 2µs after
LT8584 has been commanded to discharge a cell. The
LT8584 is configured as a flyback converter operating in
boundary mode (the edge of continuous operation), and
has three basic states (see Figure 1).
ILSEC
VMODULE + VDIODE
LSEC
IPK
N
t
VPRI
1. Primary-Side Charging
VVIN – VCESAT
When the switch latch is set, the internal NPN switch turns
on, forcing (VVIN – VCESAT) across the primary winding.
Consequently, current in the primary coil rises linearly at
a rate of (VVIN – VCESAT)/LPRI. The input voltage is mirrored on the secondary winding as –N • (VVIN – VCESAT)
which reverse-biases the secondary-side series diode and
prevents current flow in the secondary winding. Thus,
energy is stored in the core of the transformer.
t
–(VMODULE + VDIODE)
N
VSEC
VMODULE + VDIODE
t
2. Secondary-Side Energy Transfer
When current limit is reached, the current limit comparator
resets the switch latch and the device enters the second
phase of operation, secondary-side energy transfer. The
energy stored in the transformer core forward-biases the
series diode and current flows into the output capacitor
and/or battery. During this time, the output voltage plus
the diode drop is reflected back to the primary coil.
VSW
VVIN +
VMODULE + VDIODE
N
VVIN
VCESAT
VCESAT
t
3. Discontinuous Mode Detection
During secondary-side energy transfer to the output
capacitor, (VMODULE + VDIODE)/N will appear across the
primary winding. A transformer with no energy cannot
support a DC voltage, so the voltage across the primary
winding will decay to zero. In other words, the collector
of the internal NPN, SW pins, will ring down from VVIN +
(VMODULE + VDIODE)/N to VVIN. When the SW pin voltage
falls below VVIN + 95mV, the DCM comparator sets the
switch latch and a new switch cycle begins. States 1-3
continue until the part is disabled.
12
–N(VVIN – VCESAT)
(1)
(2)
(3)
PRIMARY-SIDE SECONDARY-SIDE DISCONTINUOUS
CHARGING ENERGY TRANSFER
MODE
AND OUTPUT
DETECTION
DETECTION
8584 F01
Figure 1. Simplified Discharging Waveforms
8584fb
For more information www.linear.com/LT8584
LT8584
Operation
Switch Protection
Overvoltage Protection (OVP)
Several protection features are included to reduce the
likelihood of permanent damage to the internal power
NPN switch: the short-circuit detector, the high-impedance
detector, the switch overvoltage protection (OVP), and
internal undervoltage lockout (UVLO). These also alert
the user when the integrity of the discharge converter
has been compromised because of a fault. Switching is
disabled during fault conditions.
The OVP circuitry dynamically clamps the NPN collector’s
SW pins to 50V. This protects the internal power switch
from entering breakdown and causing permanent damage. The clamp is also used as a primary-side snubber to
absorb the leakage inductance energy. The 200ns switch
clamp blanking time determines if the clamp is absorbing
a leakage spike or if the switch is turning off while the
secondary of the transformer is open. If the switch clamp
is on longer than approximately 200ns, the switch error
latch is set. The part must be reset to clear the switch
error fault.
Short-Circuit Detector
The short-circuit detector detects when the power NPN
switch turns off prematurely due to a short in the primaryside winding. If the current comparator trips before the
850ns short detection timeout, the switch error latch will
trip. The OUT pin is driven to VVIN – 1.2V, VSW,ERR, during
a switch error. The part must be reset to clear the switch
error fault.
High-Impedance Detector
The high-impedance detector monitors how long the power
NPN switch has been on. If the switch remains on longer
than 50µs, the switch maximum on-time, the switch error
latch is set and the OUT pin is driven to VVIN – 1.2V, VSW,ERR.
The part must be reset to clear the switch error fault.
Internal Undervoltage Lockout (UVLO)
LT8584 protects itself during a UVLO condition by disabling
switching. The OUT pin is driven to VVIN – 1.4V, VFAULT,
during a UVLO condition. A UVLO fault is non-latching and
dominates over a switch fault (Serial Mode requires VIN
to remain above 2V for a UVLO fault to be non-latching).
Once the UVLO condition is cleared, the OUT pin reverts
to normal operation and switching resumes. If the switch
fault latch was tripped prior to the UVLO event, the OUT pin
will indicate a switch fault, VSW,ERR, only after the UVLO
condition is cleared and switching would remain disabled.
STACK+
STACK+
•
LOCAL
IC GND
LOCAL
IC GND
•
•
LT8584
MODE
VIN
OFF ON
DIN
GND
LT8584
MODE
OFF ON
•
STACK–
VSNS VCELL
SW
DCHRG
OUT
LOCAL
IC GND
STACK–
VSNS VCELL
VIN
LOCAL
IC GND
SW
DCHRG
DIN
OUT
RTMR
GND
RTMR
8584 F02
ACTIVE LOW
ACTIVE HIGH
Figure 2. Simple Mode Configurations
8584fb
For more information www.linear.com/LT8584
13
LT8584
Operation
Simple Mode Operation
OUT Pin in Simple Mode
Connecting the MODE pin to the VIN pin configures the
LT8584 as a simple discharger with a simple on/off
shutdown pin. Two shutdown options are provided to
handle either an active high (DCHRG) or an active low
input (DIN), see Figure 2. Connect DIN to ground and use
DCHRG pin for an active high input, or connect DCHRG to
VIN and use DIN as an active low input. The part will begin
switching once the DIN pin is low and DCHRG is high.
Figure 3 shows the enable logic function. Never drive DIN
more than 0.4V below the local ground while operating
in active-high simple mode.
The OUT pin defaults to VTEMP, a voltage proportional to
the die temperature, and is measured with respect to the
cell voltage such that VTEMP = VVCELL – VOUT. This can be
used to monitor the internal die temperature for system
diagnostics. The OUT pin will also output two distinct indication voltage levels, VVIN – 1.4V, VFAULT, for an internal
UVLO condition, or VVIN – 1.2V, VSW,ERR, for a switch
error. VTEMP is not allowed to exceed 1V (equivalent to
180°C)1. This makes both the fault and switch error voltages deterministic. The switch error latch is set when the
power NPN switch has encountered a fault (see the Switch
Protection section for more details).
DCHRG
ENABLE
BALANCING
DIN
1 Not verified during production testing.
8584 F03
Figure 3. Simple Mode Enable Logic
DIN
SHUTDOWN
ENABLED WITH
CORRECT STATE
SERIAL DECODE
VVIN
SHUTDOWN
t
RTMR
DECODE WINDOW
1.22V
16.3ms
RRTMR = 100kΩ
t
OUT
VVIN
VVIN – 0.2V
VVIN – 0.4V
VVIN – 0.6V
VVIN – 0.8V
VVIN – 1.4V
OUT WILL NEVER BE DRIVEN BELOW VVIN – 1.435V
OUT PIN CLAMP IS ACTIVE BELOW VVIN – 1.53V
t
VCELL
SELECTED
VOLTAGE MODE
HANDSHAKE
ANALOG MUX
ACTIVATED TO DESIRED INPUT
VCELL SELECTED
8584 F04
Figure 4. Serial Communication Decode
14
8584fb
For more information www.linear.com/LT8584
LT8584
Operation
OSCILLATOR
EN
POR
11-BIT
Y0
RIPPLE
RST COUNTER Y11
2×4
DECODER
1-SHOT
POR
VDD
DIN
POR
2-BIT
RIPPLE Y0
RST COUNTER Y1
POR
S
Q
R
Q
S
Q
R
Q
VDD
a
A
MODE 1
B
MODE 2
C
MODE 3
D
b
MODE 4
8584 F05
Figure 5. Serial Communication Architecture
Serial Mode Operation
Serial Architecture
Use serial mode if monitoring the discharging current
and/or the die temperature are required. Connecting the
MODE pin to GND enables serial communication. The DIN
pin is used to input serial data through a custom serial
bus (see Figures 4 and 5).
Power to the part is latched on the first negative edge
of DIN signal and remains latched for the duration of the
decode window, tW. This allows the DIN pin to be toggled
for communicating serial data without resetting the part.
Serial Mode Safety Features
The LT8584 provides the user with several levels of safety
and verification. The LT8584 has built in switch protection that detects and halts power delivery during either
a primary-side open or short, a secondary-side open or
short, or an overvoltage on the primary or secondary. The
LT8584 outputs the VSW,ERR handshake that can be read
back by the battery stack monitor (BSM).
The LT8584 also detects communication errors including
too many or too few DIN pulses or a UVLO condition. The
LT8584 outputs the VFAULT handshake that can be read
back by the BSM.
The LT8584 also provides critical cell parameters including
temperature, discharge current, cell voltage, and cell and
connection DC resistance. These are all read back by the
BSM. As the cell starts to age, the cell impedance increases.
This allows the user to perform preventative maintenance,
keeping the system down time to a minimum.
Finally, the LT8584 handshake voltages are ±3% accurate
independent references that can be used to verify that every
channel in the BSM is measuring accurately.
The LT8584 counts the number of negative edges seen
on the DIN pin. Note that the first edge, which initiates serial communication and latches the part, is not counted.
There are four active modes the user can select as shown
in Table 1. Handshaking is accomplished by reading the
analog voltage on the OUT pin. Handshaking voltages
are asserted on the negative edge of the DIN signal, corresponding to the serial decode count.
Once the decode window expires and RTMR pin returns
to ground, three actions are initiated: the OUT pin analog
multiplexer switches to the desired measurement, the discharger turns on depending on selected mode in Table 1,
and the input power latch disables. Note that the LT8584
can only be disabled after the decode window has expired
and the DIN pin has been taken high.
Table 1.Serial Mode States
MODE
DISCHARGER
STATE
MUX
OUTPUT
HANDSHAKE
VOLTAGE
(VVIN – VOUT)
Part Disabled
0
Disabled
VCELL
N/A
PULSE
COUNT
0
Fault
Disabled
VFAULT
1.4
1
1
Enabled
VCELL
0.2
2
2
Enabled
VSNS
0.4
3
3
Enabled
VTEMP
0.6
4
4
Disabled
VTEMP
0.8
≥5
Fault
Disabled
VFAULT
1.4
8584fb
For more information www.linear.com/LT8584
15
LT8584
Operation
Serial Timer Decode Window
OUT Pin Analog MUX
The timer initiates on the first negative edge on the DIN pin.
RTMR pin remains high for the duration of the timer which
signifies the decode window for the serial input counter.
A resistor from the RTMR pin to ground sets the decode
window duration. The duration can be accurately set from
1.9ms (RRTMR = 10k) to 31ms (RRTMR = 200k). The timer
can be set outside this range, but the accuracy decreases.
The serial input counter stops counting and latches the
data once the RTMR pin goes low; after which, the OUT
pin amplifier input MUX selects the desired measurement,
and the discharger is set to the right state.
An internal multiplexer, MUX, selects between VCELL and
the OUT pin amplifier based on one of the selected Serial
Modes shown in Table 1. The OUT pin amplifier has a
5kΩ internal load and has several inputs including: VTEMP,
the 19•VSNS amplifier, and six handshake voltages. The
internal MUX defaults to VCELL in shutdown—consuming
no power in the process—and provides a 55Ω nominal
resistance from the VCELL pin to the OUT pin. Figure 6
shows the connection of the OUT pin to a BSM and its
internal analog MUX.
The serial interface has several fault monitors that prevent
entering undesired modes due to a communication error.
The OUT pin is set to VVIN – 1.4V to indicate the LT8584 is
in fault. The part remains in fault from the onset of RTMR
going high until the first count is detected. If no count is
seen by the serial input counter during the decode window,
the fault is latched. If the serial input counter counts higher
than 4 negative edges, the fault latch is set.
The MUX switches over to one of the handshake voltage
levels once both the LT8584 and the decode window are
activated. The OUT amplifier will indicate a fault at start-up
until the serial input counter recognizes the first negative
edge on DIN. Subsequent negative edges on DIN cause the
MUX to select the handshake voltage corresponding to the
number of edges counted. These voltage levels provide a
means of verifying if the serial interface has recognized
the correct count. Note that the OUT pin amplifier has an
approximate 200µs one percent settling time when driving
a 220nF load capacitance.
A third latching fault occurs if an internal undervoltage
lockout (UVLO) is detected during the decode window.
This protects against undesired operation if data latches
or the serial input counter were reset. The part must be
reset by taking DIN high to clear a fault.
Once the RTMR pin goes low, the MUX selects the OUT pin
mode corresponding to the number of serial input counts
(see Table 1 for available modes). The part can also be
placed in shutdown when RTMR is low and the decode
window has expired.
DIN Pin and Serial Bus Timing
VCELL Measurement
Several internal passive filters are added to the data bus
to prevent injected system noise corrupting serial communication. These filters have time constants that place
constraints on the serial communication timing requirements (see the Timing Diagram). The LT8584 can reject
up to 4µs of erroneous glitches on the DIN pin in either
direction. The power latch filter can also reject up to a
4µs glitch on DIN.
The user can measure the cell voltage by measuring
the voltage on the OUT pin either with the part disabled
(discharger off) or with the part enabled in MODE 1 (discharger on), see Table 1. The LT8584 uses an internal
PMOS switch with RDSON = 55Ω to connect VCELL to the
OUT pin. Note that any current flowing into or out of the
OUT pin will cause a measurement error due to the IR
drop across the switch.
Serial Communication Fault Modes
The DIN pin has built-in hysteresis of approximately 100mV.
This allows the serial input counter to recognize both slow
and fast edges without erroneous behavior. The discharger
activation or deactivation time is typically less than 3µs
and is a direct indication of the switch enable latch state.
16
VSNS 19× Amplifier
An amplifier is provided to allow the user to monitor the
discharger current. This measurement can only be performed when the discharger is on (MODE 2). The differential voltage between VVCELL and VVSNS is amplified 19×.
8584fb
For more information www.linear.com/LT8584
LT8584
Operation
RSNS
1:4
+
•
•
VCELL
VIN
VSNS
LTC680x
–
SW
LT8584
ANALOG MUX
DCHRG
VMODULE
VCELL
VTEMP
VSNS AMP
+
VIN – 0.2V
VIN – 0.4V
BAT2
OUT
C2
DIN
S2
VIN – 0.6V
RTMR
VIN – 0.8V
VIN – 1.2V
VIN – 1.4V
MODE
GND
CONTROL
COUNTER
DCC2
BIT
RSNS
1:4
+
•
•
VCELL
VIN
VSNS
ANALOG MUX
DCHRG
ADC
VMODULE
–
SW
LT8584
VCELL
VTEMP
VSNS AMP
+
VIN – 0.2V
VIN – 0.4V
BAT1
OUT
C1
DIN
S1
VIN – 0.6V
RTMR
VIN – 0.8V
VIN – 1.2V
VIN – 1.4V
MODE
GND
CONTROL
COUNTER
DCC1
BIT
C0
8584 F06
Figure 6. Serial Mode Analog MUX Connection
8584fb
For more information www.linear.com/LT8584
17
LT8584
Operation
This reduces errors due to input offset in the measurement circuitry connected to the OUT pin. It also allows
the use of low-value resistors, and thus, yields greater
overall efficiency.
where TJ,CORR is the corrected die temperature and TJ,CAL
is die temperature calculated from the previous equation.
For accuracy, the VIN pin should be tied to the VSNS pin to
include both the LT8584 bias current and the internal NPN
base drive current. Tying the VIN pin to the VSNS pin changes
the overall gain to 20x. Tying the VIN pin to the VCELL measures
transformer current only and the overall gain remains 19x.
All parameters including handshake voltages, VSNS, and
VTEMP are extracted differentially by taking two sequential
measurements and doing a subtraction. Figure 7 shows
the method for extracting a given parameter, VPAR, from
the highlighted LT8584. The LT8584 directly below the
LT8584 under measurement must be forced to select
VCELL (MODE 0) and becomes the negative reference for
both sequential measurements.
The VSNS amplifier has a –30mV to 70mV dynamic input
range. Internal filtering and circuit architecture allows accurate measurements even when the input current contains
negative components. The VSNS amplifier requires that the
average input current remain positive. VVIN – VOUT is not
allowed to exceed 1V during VSNS measurement to guarantee
that both VFAULT and VSW,ERR are deterministic. This sets the
maximum average input range, VVCELL – VVSNS, to 50mV.
Die Temperature Output
The user can also monitor the die temperature by selecting either MODE 3 (discharger enabled) or MODE 4
(discharger disabled). The voltage VVCELL – VOUT, VTEMP,
is proportional to the absolute temperature in degrees
Kelvin. Thus, the user needs to take two measurements
to calculate the die temperature. Temperature data gives
the user a second means to verify if the discharger is on
as well as to monitor environmental conditions. VTEMP is
not allowed to exceed 1V (equivalent to 180°C)1 to make
both VFAULT and VSW,ERR deterministic.
The following equation is used to determine the internal
die temperature in degrees Celsius:
TJ (°C) =
VTEMP − 0.609
0.00197
where VTEMP = VVCELL – VOUT and expressed in volts.
Although the absolute die temperature can deviate from
the above equation by ±25°C, the relationship between
VTEMP and the change in die temperature is well defined.
The offset error can be calibrated out using an accurate
system temperature monitor like that in the LTC680x family
of parts. There is also a small VVCELL dependence on VTEMP
which can be corrected using the following expression:
TJ,CORR (°C) = TJ,CAL + (4.2V – VCELL) • 2°C
18
Serial Mode Differential Measurements
Table 2. MODE Selection During Differential Measurements
DESIRED PARAMETER
Handshake Voltage
VSNS
VTEMP, Balancer Enabled
VTEMP, Balancer Disabled
SERIAL MODE STATE
1ST MEASUREMENT 2ND MEASUREMENT
MODE 0
MODE 1
MODE 1
MODE 0
During Decode
Window
MODE 2
MODE 3
MODE 4
Selecting VCELL for the first measurement is performed
by entering either MODE 0 (balancer disabled) or MODE 1
(balancer enabled). Use Table 2 to determine which VCELL
to reference for a given parameter. All measurements
are taken after the decode window has expired, unless
otherwise noted.
VPAR =1st Measurement – (2nd Measurement)
= VCELL – (VCELL – VPAR)
The LTC6803’s channel above the channel under measurement will have a voltage higher than a standard cell, VCELL
+ VPAR, see Figure 7. The LT8584 was architected to protect
the LTC6803’s ADC inputs and to guarantee that they well
never be stressed beyond their absolute maximum rating.
DCHRG Output
The DCHRG pin allows the LT8584 to operate several dischargers in parallel. The DCHRG pin goes high when the
switch enable latch is set. The DCHRG pin can be used to
directly drive the DCHRG pin of another LT8584 configured
in simple mode (MODE pin connected to VIN) or to directly
drive the shutdown pin of another power converter. It has
the ability to sink or source currents up to 300µA.
1 Not verified during production testing.
For more information www.linear.com/LT8584
8584fb
BAT1
BAT2
BAT3
• • •
–
GND
–
GND
LT8584
VCELL
LT8584
VCELL2
VCELL
GND
+
LT8584
VCELL3
VCELL
GND
–
+
LT8584
VCELL4
VCELL
OUT
OUT
OUT
OUT
ANALOG MUX
SELECTING
VCELL
ANALOG MUX
SELECTING
VCELL
–
VCELL2
+
–
VCELL3
+
–
VCELL4
+
• • •
• • •
For more information www.linear.com/LT8584
ADC
BAT1
BAT2
BAT3
BAT4
GND
–
GND
LT8584
VCELL
LT8584
VCELL2
VCELL
–
+
GND
VCELL
LT8584
VCELL3
+
GND
–
VCELL
LT8584
VCELL4
+
OUT
OUT
OUT
OUT
ANALOG MUX
SELECTING
VCELL
ANALOG MUX
SELECTING
PARAMETER
–
VCELL2
+
–
VCELL3 –
VPAR,3
+
–
VCELL4 +
VPAR,3
+
C0
C1
C2
C3
C4
ADC
LTC680x
• • •
• • •
• • •
• • •
• • •
• • •
• • •
8584 F07
• • •
Figure 7. Serial Mode Differential Measurements
C0
C1
C2
C3
C4
LTC680x
MEASUREMENT 2 (VCELL – VPAR)
• • •
BAT4
+
MEASUREMENT 1 (VCELL)
LT8584
Operation
• • •
• • •
8584fb
19
LT8584
Applications Information
The LT8584 can be used as a discharger for balancing
the charge in battery or supercapacitor stack systems.
The user can choose either simple mode or serial mode.
The LT8584 can be driven from any battery stack monitor such as the LTC680x. Simple mode can be employed
using either active high or active low logic, increasing its
interface flexibility.
Component Selection
turns to achieve a desired primary inductance; thus, a balance can be achieved between core and winding losses.
Recommended transformers are given in Table 3 that have
been optimized for efficiency and size. Use the following
guidelines when designing new transformers.
Reduce the transformer size by designing the boundarymode operating frequency between 100kHz and 150kHz.
The peak primary current is fixed at 6A by the chip. The
transformer turns ratio, N, should be selected by optimizing the converter input RMS current, i.e. battery discharge
current. The RMS input current can be estimated as:
Few external components are required to achieve balancing. The only external components are the transformer,
the output diode(s), the VIN bypass capacitors, the RSNS
resistor (for measuring discharge current), the RRTMR resistor (for serial mode), and in some cases, a RCD snubber.
The equations are shown for a module based approach
described in the Operation section. VMODULE becomes
VSTACK in all equations for applications returning charge to
the entire stack voltage, and VMODULE becomes VAUX for
all applications returning charge to an auxiliary power rail.
Note that negative switch current reduces the RMS input
current by effectively reducing the boundary-mode frequency, ƒBM, (see Figure 8). Reduce the overall reflected
capacitance on the SW node by reducing the output diode
and transformer interwinding parasitic capacitances.
IRMS,IN = IPK •
ƒ BM • tON
3
Transformer Design
The transformer design should yield overall converter
efficiencies greater than 80%. This reduces heat dissipation and allows for a smaller converter PCB footprint.
A proper transformer design balances core losses with
winding losses. The LT8584 converter operates in DCM
where the flux swing in the transformer is the greatest.
This shifts most of the heat loss from winding loss to core
loss. Reduce transformer core flux swing by lowering the
air-gap permeability. A lower permeability requires more
VSW
ISEC
NO SEC.
CAPACITANCE
IPRI
SEC. DISCHARGE
8584 F08
t
Figure 8. Effect of Secondary Winding Capacitance
Table 3. Recommended Transformers
RECOMMENDED
RCD SNUBBER
OUTPUT RANGE (V)
REQUIRED
SIZE W × L × H (mm)
MANUFACTURER
PART NUMBER
LPRI (µH) TURNS RATIO (PRI:SEC)
Coilcraft
www.coilcraft.com
NA6252-AL
NA5743-AL
NA5920-AL*
10 to 35
30 to 80
100 to 400
Yes
Yes
No
15.24 × 12.7 × 11.43
15.24 × 12.7 × 11.43
15.24 × 12.7 × 11.43
4
4
4
11:15
1:4
1:24
Cooper Bussmann
www.cooperindustries.com
CTX02-19175-R
CTX02-19174-R
CTX02-19176-R*
10 to 35
30 to 80
100 to 400
Yes
Yes
No
15 × 13 × 12
15 × 13 × 12
15 × 13 × 12
4
4
4
3:4
1:4
1:24
Würth
www.we-online.com
750314019_R01
750314018_R02
750314020_R01*
10 to 35
30 to 80
100 to 400
Yes
Yes
No
15.24 × 13.34 × 11.43
15.24 × 13.34 × 11.43
15.24 × 13.34 × 11.43
4
4
4
3:4
1:4
1:24
* Switch error latch may trip when starting at voltages lower than the recommended output range.
20
8584fb
For more information www.linear.com/LT8584
LT8584
Applications Information
The RMS input current can be increased by increasing
the ratio between the effective switch on-time, tON, and
off-time, tOFF. This off-time ratio is set by the transformer
ratio, N. The following equation sets the switch off-time
to approximately 1/3 of the switch on-time to optimize
power transfer and efficiency.
N=
Secondary Turns VMODULE
=
Primary Turns
3 • VIN
LEAKAGE
SPIKE CLAMPED
TO 50V
VVIN + VSTACK/N
MUST BE LESS THAN 40V
0V
8584 F06
The off-time ratio should not be decreased much beyond
1/5; otherwise, secondary-side energy transfer time becomes too short, and the converter efficiency is reduced.
Some applications may require a lower RMS current due
to charging limitations or thermal dissipation limitations.
Both can be reduced by increasing the turns ratio, N. Use
the following equation to size the transformer’s primary
inductance:
LPRI =
VSW
IPK
1
 1

N
• ƒBM • 
+

 VIN V MODULE 
t
Figure 9. Internal Switch Voltage Waveform
Higher transformer turns ratios benefit from higher
reflected capacitance that helps snub the leakage spike.
N ratios less than 8 usually require an RCD snubber to
help clamp this primary-side leakage spike and increase
the converter efficiency. Good values for the resistor and
capacitor are 4.99kΩ and 22nF, respectively.
Output Diode
Keep the primary inductance in the range of 2.2µH to
10µH. The lower limit guarantees proper detection of an
open circuit in the transformer’s secondary. The upper
limit guarantees the high-impedance detector does not
activate a false switch error during normal operation.
Leakage Inductance
Leakage inductance causes added voltage stress on the
internal power NPN collector. The LT8584 uses an internal
Zener clamp to absorb this leakage spike energy and clamp
the switch node voltage to 50V. The leakage spike energy
should be limited to improve efficiency. Figure 9 shows
the waveform of the internal NPN switch.
Design the transformer to have minimum leakage inductance. Keep both transformer windings tightly wound
around the core air gap. Using a bifilar winding or a
sandwiched secondary decreases leakage inductance.
Note that increased interwinding capacitance is a trade-off
with lower leakage inductance. Several iterations may be
required to optimize the transformer design.
The output diode(s) are selected based on the maximum
repetitive reverse voltage (VRRM) and the average forward
current, IF(AVG). The output diode’s VRRM should at a minimum exceed VMODULE + N • VVIN. The LT8584’s internal
OVP circuitry triggers at 50V, and VRRM should therefore
exceed N•(50 + VVIN) to prevent damage to the output
diode during an OVP event. Note that the leakage spike
will usually cause the OVP to trigger roughly 10% lower
than the nominal reflected voltage on the primary. The
output diode’s IF(AVG) should exceed IPK /2N, the average
short-circuit current. The average diode current is also a
function of the output voltage.
IPK • VVIN
IF(AVG) =
2 • VMODULE +N • VVIN
(
)
The highest average diode current occurs at low output
voltages and decreases as the output voltage increases.
Reverse recovery time, reverse bias leakage, and junction capacitance should also be considered. All affect
the overall charging efficiency. Excessive diode reverse
recovery times can cause appreciable discharging of the
output stack, thereby decreasing charge recovery. Choose
a diode with a reverse recovery time of less than 75ns.
8584fb
For more information www.linear.com/LT8584
21
LT8584
Applications Information
Diode leakage current under high reverse bias bleeds the
output battery/capacitor stack of charge. Choose a diode
that has minimal reverse bias leakage current. Diode
junction capacitance is reflected back to the primary, and
energy is lost during negative NPN collection conduction.
Choose a diode with minimal junction capacitance. Table 4
recommends several output diodes for various output
voltages that have adequate reverse recovery times.
Flyback Output Capacitor
Every balancer flyback output must have a ceramic capacitor on its output. The output capacitor serves as a local,
low impedance return path. It also aids during a connection
failure, adding charge storage to allow the OVP circuit to
detect an open. The capacitor should be sized to allow
roughly 10 switch cycles when charging the output from
ground to the nominal output voltage, VOUTPUT,NOM. Use
the following equation to size the output capacitor:
C FBO ≥
400 • LPRIMARY
V 2OUTPUT,NOM
The voltage surge rating must exceed 50•N. The voltage surge rating is usually specified as a multiple of the
maximum operating voltage. For capacitor maximum
operating voltages less than 100V, the surge rating is
2.5x. For operating voltage between 100V and 630V, the
surge rating is typically 1.5x; and for voltages higher than
1000V, the surge rating is 1.2x.
Bypass Capacitors
The LT8584 should be bypassed using 3 capacitors, CVIN,
CVCELL, and CTRAN (see Block Diagram), using a high-grade
(X5R or better) ceramic capacitors. CVIN should be placed
close to the VIN pin and should be sized between 1μF and
4.7μF. CTRAN must be placed close to the transformer’s
primary winding connection and the IC local ground.
The capacitance should range between 47μF and 100μF.
Simple mode should have VSNS, VCELL, and DCHRG shorted
to VIN, which provides an excellent landing for both the
transformer primary and a single bypass cap (see the
Recommended Layout section). CVIN may be omitted in
Simple Mode provided that the CTRAN capacitor is in close
proximity to the VIN pin. CVCELL is used for bulk capacitance
and should be place close to the battery input connection.
Ceramic capacitors are a good choice for bypassing due
to their moderate density, low internal series impedance,
and very low leakage current. Note that capacitor leakage current at a given operating voltage goes down with
increasing capacitor voltage rating. Ceramic capacitors
offer the lowest leakage current, while most electrolytic
capacitors are quite leaky.
Table 4. Recommended Output Diodes
MANUFACTURER
STMicroelectronics
Fairchild Semiconductor
www.fairchildsemi.com
Vishay
www.vishay.com
RECOMMENDED TRANSFORMER
TURNS RATIO (N) RANGE
1 to 2
PART NUMBER
IF(AVG) (A)
VRRM
(V)
trr (ns)
JUNCTION
CAPACITANCE (pF)
PACKAGE
STPS3H100U
3
100
N/A
90
SMB
STPS2H100AY*
2
100
N/A
50
SMA
2 to 4
STTH102AY*
1
200
20
12
SMA
10 to 24
STTH112A
1
1200
75
1 to 2
ES2B
2
100
20
SMA
18
SMB
2 to 4
ES1D
1
200
15
7
SMA
4 to 8
ES1G
1
400
35
10
SMA
6 to 12
ES1J
1
600
35
8
SMA
1 to 2
SS2H10*
2
100
N/A
70
SMB
U2B
2
100
20
16
SMB
2 to 4
10 to 20
ES1D
1
200
15
10
SMA
ES07D-M*
1.2
200
25
5
SMF
US1M
1
1000
50
10
SMA
*AEC-Q101 Qualified
22
8584fb
For more information www.linear.com/LT8584
LT8584
Applications Information
Discharge Current Sense Resistor
OUT Pin Compensation and Filtering
The discharge current sense resistor, RSNS, should only
be used in serial mode. Omit this resistor and short VSNS
and VCELL to VIN in simple mode. The maximum sense
voltage between VVSNS and VVCELL is 50mV. It is recommended to design for a nominal sense voltage of 30mV. It
is not recommended to design for a nominal sense voltage
below 20mV since the input offset voltage of the differential
amplifier contributes more error at the lower range.
V
− VVSNS 30mV
RSNS = VCELL
=
= 12mΩ
IDIS,AV
2.5A
The OUT pin must have external compensation, COUT, for
all applications including both serial mode and simple
mode. The external capacitor also provides necessary
filtering for the input to the BSM. The OUT amplifier is
internally compensated to handle capacitance ranging from
20nF to 220nF. Use 47nF for most applications to yield
approximately 100µs 1% settling time. A faster amplifier
response can be achieved by adding a zero using a resistor in series with the external filter capacitor. Use 4.7nF
capacitor with a 60Ω series resistor to achieve a sub-100µs
settling time. Note that in serial mode, the capacitors are
placed between adjacent LT8584 OUT pins. This effectively
doubles the compensation capacitance from the capacitor
value used. The OUT amplifier also has internal filtering
to both improve PSRR and handle large-signal steps or
spikes that may be present on the supply lines.
The internal amplifier amplifies the voltage difference
between VVSNS and VVCELL 20× when VIN is tied to VSNS.
The voltage is referenced from VCELL such that:
VVCELL – VOUT = 20 • (RSNS • IDIS,AV)
The measurement is the average discharge current, IDIS,AV,
and not the RMS value. The output, VVIN – VOUT, is clamped
to a maximum of 1V.
Decode Window Resistor, RRTMR
RTMR pin is used to set the duration of the decode window
and is programmed by selecting the value of the resistor connected between RTMR and GND. This pin is used
in serial mode only. Ground this pin when using simple
mode. The decode window is programmable from 1.9ms
to 31ms. Set the decode window duration 30% longer
than the required time to set the LT8584 in MODE 4 and
read back the handshake voltage. This allows the system
to detect if there is a communication error. Set RRTMR
based on following equation:
RRTMR
(kΩ) = 0.015 • t2
W + 5.9 • tW – 1.1
Additional filtering may be required in noisy environments.
Figure 10 shows a two-pole filter with the LT8584 operating in serial mode. The resistors must be kept small to
minimize error due to non-zero input currents into the
BSM. The LTC6804 is guaranteed to have 2µA or less
input bias current during measurement. There are two
resistors in any given measurement path. Thus, a 50Ω
series resistor will introduce up to a 200µV error. DIN pin
current will also cause an error when enabling a particular
LT8584, but the error term is canceled when making differential measurements.
LT8584
OUT
OUT
AMP
where RRTMR is given in kΩ and tW is given in ms.
The RTMR pin is driven to 1.22V approximately 2µs after
the part is first enabled. This indicates the decode window
is active. The RTMR pin is taken low after the decode
window expires. The internal decoder states are latched
on the falling edge of RTMR (see Figure 4). The OUT pin
multiplexer then selects the correct input corresponding
to the programmed mode (refer to Table 1).
LT8584
OUT
OUT
AMP
COUT
47nF
50Ω
COUT
47nF
100nF
TO BSM
±2µA
100nF
±2µA
FROM BSM
50Ω
COUT
47nF
100nF
8584 F10
Figure 10. Optional OUT Pin Filtering
8584fb
For more information www.linear.com/LT8584
23
LT8584
Applications Information
Hot Swap™ Protection
Large currents are developed when hot swapping a battery with a LT8584 application due to the large input bulk
capacitance coupled with the low ESR of the batteries. In
most cases, the LT8584 should have no problem handling
the overshoot voltage that follows the large inrush current.
The downstream BSM, however, might encounter damage
that requires additional steps and/or circuitry to protect
against hot swapping. Several solutions use a two-path
method incorporating a pre-charge resistive path and a
shunt path (see Figure 11).
10Ω
This method has the disadvantage of lower efficiency and
higher cost. Use FETs for M1 in Figure 12 that have low
RDS,ON to maximize converter efficiency and have less than
a 1.25V VGS threshold. Table 7 lists several recommended
FETs for M1. C1 should be sized such that C1 ≥ CVIN /500.
The third active solution protects the flyback output capacitors. All flyback outputs sum together and flow through
D13. During a Hot Swap condition, D13 will reverse bias
and prevent a large inrush current into the flyback output
capacitors. The peak repetitive reverse voltage, VRRM,
should exceed the maximum module voltage, VMODULE.
Several recommended diodes for D13 are given in Table 8.
Mechanical Solution
+
VBAT
–
CVIN
BATTERY
CONNECTION
LT8584
DIN
8584 F11
Figure 11. Dual Path Hot Swap Solution
For most applications, use the recommended Hot Swap
Solution shown as Active Solution 1 in Figure 12 and in
the Typical Application Section. Several other mechanical,
active, and order-of-assembly solutions are also given as
alternatives or as supplements.
Active Solution
An active solution has the added advantage of automatic
hot swap protection; no additional steps are needed when
connecting batteries. Two input protection solutions are
shown with the first solution using only TVS diodes. D1
is selected to trigger around 6V and to take the brunt of
the connection input pulse. The reverse leakage current
is more significant in low-voltage TVS’s. Table 5 gives
several diodes for D1 that have adequate current and
voltage characteristics while minimizing reverse leakage
current. D2 provides secondary protection for the BSM
inputs. These should be smaller than D1 since the LT8584’s
OUT pin limits current. Table 6 gives several diodes that
are optimal for D2.
The second active solution has additional overvoltage
protection via a fuse, F1, and a pre-charge MOSFET circuit.
24
A mechanical approach may result in a more cost effective
solution. A 10Ω resistor is used to pre-charge the CVIN
capacitor to the battery voltage, limiting the inrush current. After the CVIN cap is charged, a mechanical short is
connected across the resistor and remains there during
all normal operations. There are three recommended solutions for the mechanical short: 1.) use a > 3A rated jumper
2.) use a mechanical switch or 3.) use a staggered-pin
battery connector. The staggered pin connection has the
long pins connecting to LT8584 through the 10Ω resistor.
The short pins connect directly to the LT8584, shorting
out the 10Ω resistor. Normal insertion has a delay on the
order of milliseconds between the long pin connecting
and short pin connecting to the circuit, allowing CVIN to
charge up through a current limiting resistor before the
mechanical short is made.
Order of Assembly
The order of assembly of the battery stack, the LT8584
balancers, and the BSM can also mitigate hot swapping
issues. Having separate boards for both the LT8584
balancers and the BSM is recommended. This allows the
LT8584 balancers to be built and connected during the
battery stack assembly. The last step involves mating the
battery stack and LT8584 assembly with the BSM board.
Additional filters on the inputs into the BSM also reduce
possible issues during final assembly, see the OUT Pin
Compensation and Filtering section for more detail.
8584fb
For more information www.linear.com/LT8584
LT8584
Applications Information
TOP
OF STACK
+
VBAT
–
TOP
OF STACK
BATTERY
CONNECTION
+
D2
D1
CVIN
LT8584
VBAT
TO C12
–
F1, 5A
BATTERY
D1
CONNECTION
10Ω
C1
M1
LT8584
100k
D2
+
VBAT
D1
–
CVIN
LT8584
F1, 5A
+
TO C11
VBAT
D1
–
10Ω
C1
M1
+
VBAT
–
D1
CVIN
LT8584
F1, 5A
+
TO C10
VBAT
D1
–
CVIN
LT8584
100k
D2
CVIN
10Ω
C1
M1
100k
CVIN
LT8584
8584 F12
ACTIVE SOLUTION 1
ACTIVE SOLUTION 2
20k
MODULE +
+
D13
BAT12
•
BAT2
•
BAT1
LT8584
GND
SW
D2A
T2
1:4
C2
1µF
•
LT8584
GND
SW
+
C12
•
LT8584
GND
SW
+
D12A
T12
1:4
•
D1A
T1
1:4
•
C1
1µF
MODULE –
FLYBACK OUTPUT HOT SWAP PROTECTION
Figure 12. Active Hot Swap Solutions
8584fb
For more information www.linear.com/LT8584
25
LT8584
Applications Information
Table 5. Recommended Transient Voltage Suppressors (TVS) for D1 in Figure 12
MANUFACTURER
PART NUMBER
REVERSE LEAKAGE (µA)
VP-P AT IP-P
PACKAGE
STMicroelectronics
SM2T6V8A
50 at 5V
9.2V at 19.6A
DO-216AA
SM4T6V7AY*
20 at 5V
9.2V at 43.5A
SMA
SMA6T6V7AY*
20 at 5V
9.1V at 68A
SMA
VESD05A1-02V
1 at 5V
12V at 16A
SOD-523
GSOT05*
10 at 5V
12 at 30A
SOT-23
NXP
PESD5V0S1UA
4 at 5V
13.5V at 25A
SOD-323
Infineon
ESD5V0S1U-03W
20 at 5V
14V at 40A
SOD323
REVERSE LEAKAGE (µA)
VP-P AT IP-P
PACKAGE
Vishay
*AEC-Q101 Qualified
Table 6. Recommended Transient Voltage Suppressors (TVS) for D2 in Figure 12
MANUFACTURER
PART NUMBER
STMicroelectronics
ESDALC6V1-1M2
0.1 at 3V
9.2V at 6A
SOD882
Vishay
VBUS051BD-HD1
0.1 at 5V
16V at 3A
LLP1006-2L
VESD05-02V
0.1 at 5V
20V at 6A
SOD-523
Diode Inc
T5V0S5-7
0.05 at 5V
15V at 5A
SOD-523
NXP
PESD9X5.0L*
0.2 at 5V
10V at 1A
SOD-882
*AEC-Q101 Qualified
Table 7. Recommended FETs for M1 in Figure 12
MANUFACTURER
PART NUMBER
Fairchild Semiconductor
www.fairchildsemi.com
Vishay
www.vishay.com
RDS,ON (mΩ) AT VGS = 2.5V
IDS,MAX (A)
PACKAGE
FDS4465
10.5
13.5
SO-8
FDS6576
20
11
SO-8
FDMA905P
21
10
MicroFET 2x2
FDMA910PZ
24
9.4
MicroFET 2x2
Si7623DN
9
35
PowerPAK 1212-8
Si7615ADN
9.8
35
PowerPAK 1212-8
SiS407DN
13.8
25
PowerPAK 1212-8
SiA447DJ
19.4
12
PowerPAK SC-70
IF(AVG) (A)
VRRM (V)
PACKAGE
Table 8. Recommended Diodes for D13 in Figure 12
MANUFACTURER
PART NUMBER
Diodes, Inc.
www.diodes.com
SBR8U60P5
8
60
POWERDI5
PDS760-13
7
60
POWERDI5
Vishay
www.vishay.com
V8P10-M3
8
100
TO-277A
SS10P6
7
60
TO-277A
26
8584fb
For more information www.linear.com/LT8584
LT8584
Applications Information
Operating Paralleled LT8584s
Multiple LT8584s may be used if more discharge current
is required. The LT8584 connected to a battery stack
monitor (LTC6804 is recommended) becomes the master balancer. Connect its MODE pin to ground. Limit the
maximum number of parallel slave balancers to 20. This
gives a maximum discharge current of 50A. Other converters may also be used as a slave, including the LT3751
(must connect its VIN to the cell above) and the LT3750.
Connect all slave MODE pins to VIN. This forces those parts
into simple mode and makes their DCHRG pin an input pin.
Connect all slave DCHRG pins (SHDN pins if using other
converters) to the master DCHRG pin. Figure 13 shows a
5A discharger circuit using two LT8584s.
Each part operates asynchronously from the other one.
Use separate transformers for each LT8584 balancer.
The slave balancers operate only when the master balancer
is operating. A fault on the master balancer will turn off all
slave balancers. A fault in any of the slave balancers will
not turn off any of the other balancers. Use an external
sense resistor, RSNS, and the VSNS pin to determine if the
average current is at the expected value.
RSNS
MODULE+
BAT –
+
BAT
VCELL
VSNS
MODE
BAT –
MODULE+
BAT –
•
TO ADJACENT
OUT PIN
•
VIN
VCELL VSNS
MODULE–
SW
MODE
LT8584
•
VIN
MODULE–
SW
LT8584
TO C PIN
OUT
DCHRG
OUT
TO S PIN
DIN
RTMR
DIN
GND
•
DCHRG
GND
RTMR
TO ADJACENT
OUT PIN
8584 F13
MASTER BALANCER
SLAVE BALANCER
Figure 13. LT8584 Parallel Operation
THERMAL VIAS
GND
1
16
2
15
3
14
4
13
17
R1 5
T1
6
11 VSNS
7
10 VCELL
OUT
8
9
GND
CFBO
12 DCHRG
DIN
CVIN
VIN
GND
D1
• •
RTMR
COUT
THERMAL VIAS
TOP OF
BATTERY
STACK
RSNS
VIN
BATTERY
STACK
GROUND
CVTRAN
CVCELL
CELL INPUT
VIN
1
16
2
15
3
14
4
13
17
5
6
11
7
10
OUT
8
9 VIN
GND
SERIAL MODE
For more information www.linear.com/LT8584
D1
CFBO
BATTERY
STACK
GROUND
CVTRAN
CVCELL
SIMPLE MODE
Figure 14. LT8584 Suggested Layout
T1
• •
12
DIN
COUT
TOP OF
BATTERY
STACK
CELL INPUT
8584 F14
8584fb
27
LT8584
Applications Information
Recommended Layout
Connecting to a Battery Stack Monitor
The potentially high voltage operation of the LT8584
demands careful attention to the board layout, observing
the following points:
There are two methods used to connect the LT8584 balancer to a battery stack monitor (BSM): either a single-wire
or two-wire. Both have advantages and disadvantages.
Both methods may require Kelvin connections for the
BSM supply rails depending upon the magnitude of IR
drop across the connections to the battery stack. In most
cases, keeping the individual connection resistances less
than 60mΩ allows the BSM supply rails to share the return
path through RW0 and RW12, see Figure 16.
1.Minimize the board trace area of the high voltage end
of the secondary winding.
2.Keep the electrical path formed by CVTRAN, the primary
of T1, the SW node, and ground as short as possible.
Increasing the length of this path effectively increases
the leakage inductance of T1, resulting in excessive
energy loss in the internal Zener clamp or RCD snubber.
3.Thermal vias should be added underneath the chip’s
exposed pad, pin 17, to enhance the LT8584’s thermal
performance. These vias should go directly to a local
ground plane with a minimum area of 650mm2.
4.Make Kelvin connections for VSNS, VCELL, and RSNS to
the battery cell when using the LT8584 in serial mode.
The IR drop in the battery connection can be calibrated
out using a software algorithm. Consult Application
Engineering.
5.Care should be taken when routing VCELL, VSNS and VIN
connections. RTRACE in Figure 15 should be minimized for
better efficiency. RTRACE should never exceed 19•RSNS.
This guarantees that the OUT pin amplifier headroom is
sufficient enough for reporting the VSNS amplifier output.
6.Minimize the total connection resistance from the battery
terminals to the VCELL and GND pins of the LT8584. It
is recommended to keep the total resistance less than
60mΩ to improve converter efficiency. Excessive IR
drops in the PCB traces or connector terminals could
also cause the LT8584 to prematurely enter UVLO.
RSNS
VCELL
+
VBAT
–
Note that in the two-wire connection scheme, the ground
connection impedance can not be determined when
calculating wire impedance and will be invisible to the
measurement system. On the flip side, the algorithms
for computing two-wire connection impedance and back
calculating VCELL during discharging are more straightforward. The two-wire method also has the advantage of only
losing visibility of a single cell during an open connection
instead of two as in the single-wire method.
Integrating with the LTC680x Family
The LTC680x family of parts are multi-cell battery stack
monitors that are described in the Operation section of
this data sheet. For more information, consult the LTC680x
data sheets. Several operational flavors are available with
their inherent differences shown in Table 9.
Table 9. LTC680x Feature Differences
RTRACE
VSNS
The single-wire connection is recommended due to complete system visibility of the wire connection impedance.
The single-wire is also cheaper and more reliable due to
fewer wire connections. See the Typical Application section
for proper Kelvin connection between adjacent LT8584
channels in single-wire mode.
VIN
•
ISW
LPRI
Q1
8584 F15
PART
COMMUNICATION
COMPATIBLE MODES
LTC6802-1
Daisy Chained Serial
Simple Mode Only
LTC6802-2
Addressable Parallel
Simple Mode Only
LTC6804-1/LTC6803-1/ Daisy Chained Serial
LTC6803-3
Serial / Simple Mode
LTC6804-2/LTC6803-2/ Addressable Parallel
LTC6803-4
Serial / Simple Mode
Figure 15. RTRACE Minimization
28
8584fb
For more information www.linear.com/LT8584
LT8584
Applications Information
SINGLE-WIRE BATTERY CONNECTION
TWO-WIRE BATTERY CONNECTION
VMODULE+
VMODULE+
V+
RW12
BSM
V+
RW12
BAT 12
BSM
BAT 12
RW11
+ VERR –
BAT 11
RW10
BALANCING
CURRENT
LT8584
BALANCER ON
BALANCING
CURRENT
LT8584
BALANCER ON
RW9
BALANCING
CURRENT
LT8584
BALANCER ON
BAT 11
C11
RW0
BALANCING
CURRENT
LT8584
BALANCER ON
C12
C11
RW10
C10
BAT 10
RW1
BAT 1
LT8584
BALANCER ON
RW11
ADC
+ VERR –
BAT 10
C12
BALANCING
CURRENT
ADC
BALANCING
CURRENT
LT8584
BALANCER ON
BALANCING
CURRENT
LT8584
BALANCER ON
C10
RW1
BALANCING
CURRENT
LT8584
BALANCER ON
C1
BAT 1
C1
C0
V–
C0
V–
VMODULE–
8584 F16
VMODULE–
Figure 16. LT8584 Battery Connections
The LTC6803 and LTC6804 draw only 3µA of static current on the S pin, allowing the LT8584 to be enabled
without noticeable measurement error. The LTC6804
offers improved ADC performance over the LTC6803 by
reducing conversion time approximately 10x and reducing measurement error below 1.2mV. The LTC6804 also
utilizes isoSPI with improved RF-immunity.
to turn on one balancer where N = number of LTC680x in
the system and ƒ = frequency of the SCKI clock.
Table 10. Approximate Time to Enable One LT8584
STEP
TIME (s)
LTC6802-1/LTC6802-3
LTC6803-1/LTC6803-3
LTC6802-2/LTC6802-4
LTC6803-2/LTC6803-4
(16 + 56 • N)
72
ƒ
Enable Balancing in Simple Mode
Send WRCFG
Command, Write ‘1’
to Enable Balancer
Write a ‘1’ to the corresponding DCCx bit in the configuration register of the LTC680x. This pulls its S pin low and
activates the LT8584. Table 10 shows the required time
Note that the addressable serial interface is much faster
when writing to a single channel in a multi-chip system.
ƒ
8584fb
For more information www.linear.com/LT8584
29
LT8584
Applications Information
Enable Balancing in Serial Mode
In serial mode, the configuration register has to be written several times to toggle the DCCx bit and pipe data
into the serial bus. The RTMR resistor needs to be set
accordingly to guarantee that enough time is allocated
to enter any one of the four serial modes and read back
the handshake voltage on the OUT pin. There are speed
limitations when sending information to the LT8584 (see
the Timing Diagram). Use Table 11 to determine overall
timing requirements.
Table 11. Turning on LT8584 in MODE 4
LTC6803/LTC6804
VIN
VCELL
OUT
LT8584
DIN
GND
DCCx STATE
1 – DIN Low
0 – DIN High
1 – DIN Low (MODE 1)
0 – DIN High
1 – DIN Low (MODE 2)
0 – DIN High
1 – DIN Low (MODE 3)
0 – DIN High
1 – DIN Low (MODE 4)
Total
VIN
SON
ADC
VCELL
OUT
C(N)
LT8584
LTC6803-2/
LTC6803-4
DIN
GND
S(N)
SON
MODE
C(N–1)
(16 + 56 • N)
ƒ
(16 + 56 • N) • 9
ƒ
72
ƒ
648
ƒ
Filtering and ADC Measurements
The LTC680x has an internal multichannel differential ADC
that measures the voltage between each consecutive pair
of C pins. Figure 17 shows the ADC connected to C(N)
and C(N+1), measuring the difference between the two
adjacent LT8584’s OUT pins. Most parameters require
two measurements, one with the top LT8584 selecting
VCELL and another one with the top LT8584 selecting
the desired parameter. The difference between these two
measurements yields the desired parameter value. This
is required since the LTC680x is not directly connected to
the battery cells. See the Serial Mode Differential Measurements section for more detail.
Filter capacitors (typically 47nF) have to be placed between
adjacent C pins to provide the required 16kHz lowpass
filter for the ADC input path. This provides 30dB of noise
reduction. No external filter resistors are needed since the
30
S(N+1)
MODE
TIME (s)
LTC6803-1/
LTC6803-2
C(N+1)
8584 F17
Figure 17. LTC6803/LTC6804 Simplified Connections
internal impedance from VCELL to OUT is approximately
55Ω. Note that the effective capacitance on the OUT pin
becomes 2× 47nF or 94nF. Figure 17 has omitted these
capacitors for the sake of simplicity (see the Typical Applications for proper connection of the filter capacitors).
Adequate bypass capacitors need to be connected from
VIN to ground for each LT8584 to provide a low-impedance
path for high-frequency switching noise. Ceramic capacitors work well for this purpose.
Several passive filters internal to the LT8584 are included
to remove erroneous glitches on the DIN pin that are up
to 4µs in duration.
Test Circuit
Use the circuit in Figure 18 for testing the LT8584 in
Serial Mode without using a BSM. The inverter directly
driving the LT8584 should be placed close to the LT8584
and have less than 1V VGS thresholds. Figure 19 shows
typical serial communication waveforms using a 100kΩ
timer resistor and a 2ms data period.
8584fb
For more information www.linear.com/LT8584
LT8584
Applications Information
VISHAY Si1035x
100Ω
VISHAY SFH6720T
+
–
5V
TO
10V
VOUT
PULSE
GENERATOR
LT8584
D2
49.9Ω
D1
49.9Ω
10Ω
DIN
G1
GND
100nF
OUT
G2
VCC
2.3kΩ
S2
S1
100Ω
GND
8584 F18
Figure 18. Serial Mode Test Circuit
VRTMR
1V/DIV
VDIN
2V/DIV
VOUT
1V/DIV
2ms/DIV
PREVIOUS MODE SELECTED RESET
PULSE COUNTING
MODE4 HANDSHAKE
MODE4 SELECTED
8584 F19
Figure 19. Typical Serial Mode Communication Waveforms
8584fb
For more information www.linear.com/LT8584
31
LT8584
Typical Applications
Stackable Fast-Charge 8 to 12-Cell Battery Module, 4.6A Discharge Capability with 2 Parallel LT8584 per Cell
MODULE+
R12A
5mΩ
BATTERY STACK TO PCB CONNECTION
C12A
100µF
×2
D12A
C12B
22nF
R12C
4.99k
C12E
100µF
•
T12B
1:4
BAT12
VCELL VSNS VIN
D12D
RTMR
LOCAL
VIN
•
R12B
100k
DIN
RTMR
C13
47nF
+
C12C
MODULE
1µF
•
–
LTC680x
BSM
OUT
C12
DIN
S12
LT8584
MASTER
MODE
GND
T12A
1:4
SW
DCHRG
C12G
47nF
LT8584
SLAVE
•
D12F
–
VCELL VSNS VIN
OUT
MODE
R12D
4.99k
C12F
1µF MODULE
SW
DCHRG
C12H
22nF
+
D12E
+
V+
D13
D12B
GND
R2A
5mΩ
C2A
100µF
×2
D2A
C2B
22nF
R2C
4.99k
C2E
100µF
•
T2B
1:4
+
D2D
VCELL VSNS VIN
BAT2
•
RTMR
LOCAL
VIN
VCELL VSNS VIN
OUT
MODE
R2B
100k
DIN
RTMR
C3D
47nF
+
C2C
MODULE
1µF
•
–
OUT
C2
DIN
S2
LT8584
MASTER
MODE
GND
D3C
D2B
SW
DCHRG
C2G
47nF
LT8584
SLAVE
•
T2A
1:4
D2F
–
SW
DCHRG
R2D
4.99k
C2F
MODULE
1µF
D2E
+
C2H
22nF
GND
KELVIN CONNECTION TO R1A
R1A
5mΩ
C1A
100µF
×2
C1B
22nF
R1C
4.99k
C2E
100µF
•
T1B
1:4
VCELL VSNS VIN
DCHRG
+
RTMR
D1D
BAT1
LOCAL
VIN
R1D
4.99k
C1F
MODULE
1µF
•
–
SW
OUT
LT8584
SLAVE
C1H
22nF
+
D1E
D1A
D2C
DCHRG
R1B
100k
DIN
D1B
•
RTMR
MODE
MODE
GND
GND
LT8584
MASTER
+
C1C
1µF
MODULE
–
D1F
VCELL VSNS VIN
C1G
47nF
•
T1A
1:4
C2D
47nF
SW
OUT
C1
DIN
S1
C1D
47nF
RPASS
250Ω
10W
D1C
M1
GPIO1
C0
V–
8584 TA02a
MODULE–
Average Cell Discharge Current
3
2
5
ERROR (%)
1
4
3
0
–1
VCELL = 2.5V
VCELL = 3V
VCELL = 3.6V
VCELL = 4.2V
30
35
40
45
50
MODULE VOLTAGE (VMODULE+ – VMODULE–)
8584 TA02b
32
Typical Current Measurement Error
6
DISCHARGE CURRENT (A)
C1A-C12A: 6.3V X5R OR X7R CERAMIC CAPACITOR
C1B-C12B, C1H-C12H: 50V X5R OR X7R CERAMIC CAPACITOR
C1C-C12C: 100V X5R OR X7R CERAMIC CAPACITOR
C1D-C12D, C13: 50V NPO CERAMIC CAPACITOR
C1E-C12E: 6.3V X5R OR X7R CERAMIC CAPACITOR
C1F-C12F: 100V X5R OR X7R CERAMIC CAPACITOR
C1G-C12G: 6.3V X5R OR X7R CERAMIC CAPACITOR
D1A-D12A: STMICROELECTRONICS SMA6T6V7AY TVS DIODE
D1B-D12B: FAIRCHILD ES1D 200V, 1A ULTRAFAST RECTIFIER
D1C-D12C, D13: STMICROELECTRONICS ESDALC6V1-1M2 TVS
D1D-D12D: FAIRCHILD ES1D 200V, 1A ULTRAFAST RECTIFIER
D1E-D12E, D1F-D12F: FAIRCHILD SS16 60V, 1A
M1: FAIRCHILD FDMC86102L 100V, 5.5A
R1A-R12A: USE 1% 1206 RESISTORS
R1B-R12B, R1C-R12C, R1D-R12D: USE 1% 0603 RESISTORS
RPASS: 10W WIREWOUND
T1A-T12A, T1B-T12B: COILCRAFT NA5743-AL
U1: LINEAR TECHNOLOGY LTC680x FAMILY INCLUDING BUT NOT
LIMITED TO LTC6802, LTC6803, LTC6804
For more information www.linear.com/LT8584
VCELL = 2.5V
VCELL = 3V
VCELL = 3.6V
VCELL = 4.2V
–2
–3
30
35
40
45
50
MODULE VOLTAGE (VMODULE+ – VMODULE–)
8584 TA02b
8584fb
LT8584
Typical Applications
Stackable Fast-Charge 8 to 12-Cell Battery Module
Application Notes
Stackable 8 to 12-Cell Battery Module Application
Notes
1.Channels 3 through 11 are omitted for clarity. These
channels should be integrated similar to channel 2. Not
all required components for the LTC680x are shown.
Consult the LTC680x data sheet for recommended
components and their connections.
See the last page Typical Application.
2.Up to 20 LT8584 balancers may be connected in parallel to farther increase discharge current. The DCHRG
pin can also drive an enable pin of a separate DC/DC
converter like the LT3750 capacitor charger.
3.Multiple modules can be stacked in series to achieve
a larger battery stack. Each module must contain an
integer multiple of the total number of cells in the stack.
For instance, an 80 cell stack should be constructed with
8 modules each having 10 cells. Use consecutive BSM
channels starting with BSM channel 1when populating
a module with less than 12 channels. Tie all unused
LTC680x C pins to MODULE+.
4.Place one CnE capacitor close to the Master LT8584’s
transformer primary, and place the other CnE capacitor
close to the Slave LT8584’s transformer primary. The
symbol ‘n’ denotes a particular channel ranging from
1 to 12.
5.Place RCD snubber composed of DnF, DnE, RnC, RnD,
CnB, CnH, as close as possible to the respective transformer primary. The symbol ‘n’ denotes a particular
channel ranging from 1 to 12.
6.RPASS and M1 may be omitted for applications using
only one module in the stack.
7.Each LT8584 channel should have no less than 650mm2
of PCB pad footprint for proper heat sinking.
8.Consult Application Engineering for proper communication with LTC680x family of parts as well as a proper
algorithm for extracting cell parameters.
9.Recommended for cells that operate within a 2.5V to
5.3V range.
1.Channels 4 through 11 are omitted for clarity. These
channels should be integrated similar to channel 2. Not
all required components for the LTC680x are shown.
Consult the LTC680x data sheet for recommended
components and their connections.
2.Multiple modules can be stacked in series to achieve
a larger battery stack. Each module must contain an
integer multiple of the total number of cells in the stack.
For instance, an 80 cell stack should be constructed with
8 modules each having 10 cells. Use consecutive BSM
channels starting with BSM channel 1 when populating
a module with less than 12 channels. Tie all unused
LTC680x C pins to MODULE+.
3.Place the CnB capacitor close to the LT8584’s transformer primary. The RCD snubber composed of CnE,
RnC and DnD should also be placed close the LT8584’s
transformer primary. The symbol ‘n’ denotes a particular
channel ranging from 1 to 12.
4.The BSM V+ pin may share cell 12’s positive battery
connection, and the BSM V– pin may share cell 0’s
negative battery connection as long as the summation of each battery connection’s PCB trace, wire, and
interconnection resistance is less than 60mΩ.
5.RPASS and M1 may be omitted for applications using
only one module in the stack.
6.Each LT8584 channel should have no less than 650mm2
of PCB pad footprint for proper heat sinking.
7.Consult Application Engineering for proper communication with LTC680x family of parts as well as a proper
algorithm for extracting cell parameters.
8.Recommended for cells that operate within a 2.5V to
5.3V range.
8584fb
For more information www.linear.com/LT8584
33
LT8584
Package Description
Please refer to http://www.linear.com/designtools/packaging/ for the most recent package drawings.
FE Package
16-Lead Plastic TSSOP (4.4mm)
(Reference LTC DWG # 05-08-1663 Rev K)
Exposed Pad Variation BC
4.60
3.58
(.141)
4.90 – 5.10*
(.193 – .201)
16 1514 13 12 11
SEE NOTE 5
6.60 ±0.10
4.50 ±0.10
0.48
(.019)
REF
3.58
(.141)
2.94
(.116)
10 9
DETAIL B
6.40
2.94
(.252)
(.116)
BSC
SEE NOTE 4
0.45 ±0.05
1.05 ±0.10
0.51
(.020)
REF
DETAIL B IS THE PART OF
THE LEAD FRAME FEATURE
FOR REFERENCE ONLY
NO MEASUREMENT PURPOSE
0.65 BSC
1 2 3 4 5 6 7 8
RECOMMENDED SOLDER PAD LAYOUT
4.30 – 4.50*
(.169 – .177)
0.09 – 0.20
(.0035 – .0079)
0.25
REF
0.50 – 0.75
(.020 – .030)
NOTE:
1. CONTROLLING DIMENSION: MILLIMETERS
MILLIMETERS
2. DIMENSIONS ARE IN
(INCHES)
3. DRAWING NOT TO SCALE
4. RECOMMENDED MINIMUM PCB METAL SIZE
FOR EXPOSED PAD ATTACHMENT
34
1.10
(.0433)
MAX
0° – 8°
0.65
(.0256)
BSC
0.195 – 0.30
(.0077 – .0118)
TYP
0.05 – 0.15
(.002 – .006)
FE16 (BC) TSSOP REV K 1013
5. BOTTOM EXPOSED PADDLE MAY HAVE METAL
PROTRUSION IN THIS AREA. THIS REGION MUST
BE FREE OF ANY EXPOSED TRACES OR VIAS ON
PCB LAYOUT
*DIMENSIONS DO NOT INCLUDE MOLD FLASH. MOLD FLASH
SHALL NOT EXCEED 0.150mm (.006") PER SIDE
8584fb
For more information www.linear.com/LT8584
LT8584
Revision History
REV
DATE
DESCRIPTION
A
05/14
Clarified Features
PAGE NUMBER
1
Clarified Electrical Characteristics
3
Clarified Data Threshold graph
6
Clarified OUT Pin Amplifier graph
7
Clarified Operation description
11
Clarified Operation description
15
Clarified Applications Information
Clarified Figures 17, 18
B
8/14
20, 24, 30
30, 31
Clarified Absolute Maximum Ratings
2
Clarified Handshake Voltage Error Conditions
3
Clarified DIN Pin Function
9
Clarified Block Diagram
10
Clarified Figure 1
12
Clarified Sense Resistor Formula
23
Clarified Figure 16 in Applications Information
29
8584fb
Information furnished by Linear Technology Corporation is believed to be accurate and reliable.
However, no responsibility is assumed for its use. Linear Technology Corporation makes no representation that the interconnection
of its circuits
as described
herein will not infringe on existing patent rights.
For more
information
www.linear.com/LT8584
35
LT8584
Typical Application
Stackable 8 to 12-Cell Battery Module, LT8584 in Serial Mode, Single-Wire Configuration
Average Cell Discharge Current
MODULE+
R12A
12mΩ
C12E
22nF
C12A
100µF
C12B
100µF
D12A
+
BAT12
R12B
100k
R12C
4.99k
+
•
C12C
• 1µF
MODULE
SW
DCHRG
OUT
V+
D13
C13
47nF
–
D12D
VCELL VSNS VIN
RTMR
D12B
T12
1:4
DISCHARGE CURRENT (A)
BATTERY STACK
TO PCB CONNECTION
3.0
LTC6804
BSM
C12
LT8584
MODE
S12
DIN
C2A
100µF
R2A
12mΩ
C2B
100µF
C2E
22nF
R2C
4.99k
•
T2
1:4
C2C
1µF
MODULE
–
+
BAT2
R2B
100k
D3C
OUT
C2
DIN
S2
LT8584
GND
KELVIN CONNECTION TO R1A
C1A
100µF
C1B
100µF
D1A
C1E
22nF
R1C
4.99k
•
40
45
50
35
MODULE VOLTAGE (VMODULE+ – VMODULE–)
0.25
SW
R1A
12mΩ
30
0.30
DCHRG
MODE
2.2
Average Flyback Output Current
C3D
47nF
VCELL VSNS VIN
RTMR
2.4
8584 TA03b
+
•
D2D
D2A
2.6
D2B
OUTPUT CURRENT (A)
KELVIN CONNECTION TO R2A
2.8
2.0
GND
VCELL = 2.5V
VCELL = 3V
VCELL = 3.6V
VCELL = 4.2V
D1B
T1
1:4
+
•
C1C
1µF
MODULE
D1D
–
0.20
0.15
0.10
VCELL = 2.5V
VCELL = 3V
VCELL = 3.6V
VCELL = 4.2V
0.05
D2C
0
C2D
47nF
+
30
40
45
50
35
MODULE VOLTAGE (VMODULE+ – VMODULE–)
8584 TA03c
BAT1
R1B
100k
VCELL VSNS VIN
SW
DCHRG
OUT
C1
DIN
S1
RTMR
LT8584
MODE
GND
C1D
47nF
GPIO1
D1C
C0
V–
C1A-C12A: 6.3V X5R OR X7R CERAMIC CAPACITOR
C1B-C12B: 6.3V X5R OR X7R CERAMIC CAPACITOR
RPASS C1C-C12C: 100V X5R OR X7R CERAMIC CAPACITOR
500Ω C1D-C12D, C1E-C12E, C13: 50V NPO CERAMIC CAPACITOR
D1A-D12A: STMICROELECTRONICS SMA6T6V7AY TVS DIODE
5W
D1B-D12B: FAIRCHILD ES1D 200V ULTRAFAST RECTIFIER
D1C-D12C, D13: STMICROELECTRONICS ESDALC6V1-1M2 TVS
D1D-D12D: FAIRCHILD SS16 60V, 1A SCHOTTKY
M1
M1: FAIRCHILD FDMC86102L 100V, 5.5A
R1A-R12A: USE 1% 1206 RESISTORS
R1B-R12B, R1C-R12C: USE 1% 0603 RESISTORS
RPASS: 2 PARALLEL 2.5W WIREWOUND
T1-T12: COILCRAFT NA5743-AL
U1: LINEAR TECHNOLOGY LTC680x FAMILY INCLUDING BUT NOT
LIMITED TO LTC6802, LTC6803, LTC6804
8584 TA03a
MODULE–
Related Parts
PART NUMBER
DESCRIPTION
COMMENTS
LTC3300-1
High Efficiency Bidirectional Multicell Balancer
Synchronous Flyback, Up to 6 Cells in Series, 48-Lead QFN
LTC6803
Multicell Battery Stack Monitor
Measures Up to 12 Li-Ion Cells in Series, SSOP-44
LTC6804
Multicell Battery Stack Monitor
Measures Up to 12 Li-Ion Cells in Series, Built-In isoSPI™, SSOP-48
36 Linear Technology Corporation
1630 McCarthy Blvd., Milpitas, CA 95035-7417
For more information www.linear.com/LT8584
(408) 432-1900 ● FAX: (408) 434-0507
●
www.linear.com/LT8584
8584fb
LT 0814 REV B • PRINTED IN USA
 LINEAR TECHNOLOGY CORPORATION 2013