© Semiconductor Components Industries, LLC, 2017
September, 2019 − Rev. 13
1Publication Order Number:
LC05111CMT/D
Battery Protection IC for
1-Cell Lithium-Ion with
Integrated Power MOSFET
LC05111CMT
Overview
The LC05111CMT is a protection IC for 1−cell lithium−ion
secondary batteries with integrated power MOSFET. Also it integrates
highly accurate detection circuits and detection delay circuits to
prevent batteries from over−charging, over−discharging, over−current
discharging and over−current charging.
A battery protection system can be made by only LC05111CMT and
few external parts.
Features
•Charge−and−discharge Power MOSFET are Integrated at
Ta = 25_C, VCC = 4.5 V
♦ON Resistance (total of charge and discharge) 11.2 mW (typ)
•Highly Accurate Detection Voltage/Current at Ta = 25°C, VCC = 3.7 V
♦Over−charge Detection ±25 mV
♦Over−discharge Detection ±50 mV
♦Charge Over−current Detection ±0.7 A
♦Discharge Over−current Detection ±0.7 A
•Delay Time for Detection and Release (fixed internally)
•Discharge/Charge Over−current Detection is Compensated for
Temperature Dependency of Power FET
•0 V Battery Charging : “Permission”
•Auto Wake−up Function Battery Charging: “Permission”
•Over Charge Detection Voltage : 4.0 V to 4.5 V (5 mV steps)
•Over Charge Release Hysteresis : 0 V to 0.3 V (100 mV steps)
•Over Discharge Detection Voltage : 2.2 V to 2.7 V (50 mV steps)
•Over Discharge Release Hysteresis at Auto Wake−up : 0 V to 0.6 V
(200 mV steps)
•Over Discharge Release Hysteresis : 0 V to 0.075 V (25 mV steps)
•Discharge Over Current Detection : 2.0 A to 8.0 A (0.5 A steps)
•Charge Over Current Detection : −8.0 A to −2.0 A (0.5 A steps)
Typical Applications
•Lithium Ion Battery Protection
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MARKING DIAGRAM
XXXXX = Specific Device Code
A = Assembly Location
Y = Year
WW = Work Week
G= Pb−Free Package
*This information is generic. Please refer to
device data sheet for actual part marking.
(Note: Microdot may be in either location)
XXXXX
AYWWG
WDFN6 2.6x4.0, 0.65P,
DUAL FLAG
CASE 511BZ
See detailed ordering and shipping information on page 15 of
this data sheet.
ORDERING INFORMATION
LC05111CMT
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2
Specifications
Table 1. ABSOLUTE MAXIMUM RATINGS TA = 25°C (Notes 1 and 2)
Parameter Symbol Ratings Unit Conditions
Supply voltage VCC −0.3 to +12.0 VBetween PAC+ and VCC : R1 = 680 W
S1 − S2 voltage VS1−S2 24.0 V
CS terminal Input voltage CS VCC−24.0 V
Charge or discharge current BAT−, PAC−10.0 A
TST Input voltage TST −0.3 to +7.0 V
Storage temperature Tstg −55 to +125 °C
Current between S1 and S2(DC) ID 10.0 A VCC = 3.7 V
Current between S1 and S2
(continuous pulse)
IDP 35 A Pulse Width < 10 ms, duty cycle < 1%
Operating ambient temperature Topr −40 to +85 °C
Allowable power dissipation Pd 450 mW Glass epoxy four−layer board. Board
size 27.4 mm x 3.1 mm x 0.8 mm
Junction temperature Tj 125 °C
Stresses exceeding those listed in the Maximum Ratings table may damage the device. If any of these limits are exceeded, device functionality
should not be assumed, damage may occur and reliability may be affected.
1. Absolute maximum ratings represent the values which cannot be exceeded at any given time.
2. If you intend to use this IC continuously under high temperature, high current, high voltage, or drastic temperature change, even if it used
within the range of absolute maximum ratings or operating conditions, there is a possibility of decrease reliability. Please contact us for
confirmation.
Figure 1. Example of Application Circuit
Controller IC
S1 S2 CS
R2
R1
C1
VCC
TST
Battery
PAC+
PAC−
VSS
Table 2.
Components Recommended Value Max Unit Description
R1 680 1 k W
R2 1 k 2 k W
C1 0.1 m1.0 mF
3. We don’t guarantee the characteristics of the circuit shown above.
4. TST pin would be better to be connected to VSS pin, though it is connected to VSS with internal resistor (100 kW typ).
5. Battery voltage drop occurs, a current of about 60 mA flow period of 1.5 V − 1.3 V.
LC05111CMT
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Table 3. ELECTRICAL CHARACTERISTICS
Parameter Symbol Conditions Min Typ Max Unit
DETECTION VOLTAGE
Over−charge detection volt-
age
Vov R1=680W25°CVov_set −25 Vov_set Vov_set +25 mV
−30 to 70°CVov_set −30 Vov_set Vov_set +30
Over−charge release volt-
age
Vovr R1=680W25°CVovr_set −40 Vovr_set Vovr_set +40 mV
−30 to 70°CVovr_set −70 Vovr_set Vovr_set +70
Over−discharge detection
voltage
Vuv R1=680W25°CVuv_set −50 Vuv_set Vuv_set +50 mV
−30 to 70°CVuv_set −80 Vuv_set Vuv_set +80
Over−discharge release
voltage
Vuvr R1=680W
CS=0V
25°CVuvr_set −100 Vuvr_set Vuvr_set +100 mV
−30 to 70°CVuvr_set −120 Vuvr_set Vuvr_set +120
Over−discharge release
voltage2
Vuvr2 R1=680W
CS=open
25°CVuvr2_set −100 Vuvr2_set Vuvr2_set +100 mV
−30 to 70°CVuvr2_set −120 Vuvr2_set Vuvr2_set +120
Discharge over−current
detection current
Ioc R2=1kW25°C
VCC=3.7V
Ioc_set −0.7 Ioc_set Ioc_set +0.7 A
−30 to 70°C
VCC=2.6 to 4.3V
Ioc_set −1.2 Ioc_set Ioc_set +1.2
Discharge over−current
release current
Iocr R2=1kW25°C
VCC=3.7V
(Ioc_set−0.7) (Ioc_set) (Ioc_set+0.7) A
−30 to 70°C
VCC=2.6 to 4.3V
(Ioc_set−1.2) (Ioc_set) oc_set+1.2)
Discharge over−current de-
tection current(Short circuit)
Ioc2 R2=1kW25°C
VCC=3.7V
Ioc2_set*0.8 Ioc2_set Ioc2_set*1.2 A
Charge over−current detec-
tion current
Ioch R2=1kW25°C
VCC=3.7V
Ioch_set −0.7 Ioch_set Ioch_set +0.7 A
−30 to 70°C
VCC=2.6 to 4.3V
Ioch_set −1.2 Ioch_set Ioch_set +1.2
Charge over−current re-
lease current
Iochr R2=1kW25°C
VCC=3.7V
Ioch_set −0.7 Ioch_set Ioch_set +0.7 A
−30 to 70°C
VCC=2.6 to 4.3V
Ioch_set −1.2 Ioch_set Ioch_set +1.2
INPUT VOLTAGE
Operating Voltage for 0V
charging
Vchg VCC−CS
VCC−GND=0V
25°C 1.4 V
CURRENT CONSUMPTION
Operating current Icc At normal
state
25°C
VCC=3.7V
3 6 mA
Stand−by current Istb At Stand−by
state
Auto wake−up
= enable
25°C
VCC=2.0V
0.95 mA
RESISTANCE
ON resistance 1 of integrat-
ed power MOSFET
Ron1 VCC=3.1V
I=±2.0A
25°C 10.4 13 18.2 mW
ON resistance 2 of integrat-
ed power MOSFET
Ron2 VCC=3.7V
I=±2.0A
25°C 9.6 12 15.6 mW
ON resistance 3 of integrat-
ed power MOSFET
Ron3 VCC=4.0V
I=±2.0A
25°C 9.2 11.6 15 mW
ON resistance 4 of integrat-
ed power MOSFET
Ron4 VCC=4.5V
I=±2.0A
25°C 8.8 11.2 14 mW
LC05111CMT
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Table 3. ELECTRICAL CHARACTERISTICS
Parameter UnitMaxTypMinConditionsSymbol
RESISTANCE
Internal resistance
(VCC−CS)
Rcsu VCC=Vuv_set
CS=0V
25°C 300 kW
Internal resistance
(VSS−CS)
Rcsd VCC=3.7V
CS=0.1V
25°C 15 kW
DETECTION AND RELEASE DELAY TIME
Over−charge detection de-
lay time
Tov 25°C 0.8 1 1.2 sec
−30 to 70°C 0.6 1 1.5
Over−charge release delay
time
Tovr 25°C 12.8 16 19.2 ms
−30 to 70°C 9.6 16 24
Over−discharge detection
delay time
Tuv 25°C 16 20 24 ms
−30 to 70°C 12 20 30
Over−discharge release de-
lay time
Tuvr 25°C 0.9 1.1 1.3 ms
−30 to 70°C 0.6 1.1 1.5
Discharge over−current
detection delay time 1
Toc1 VCC=3.7V 25°C 9.6 12 14.4 ms
−30 to 70°C 7.2 12 18
Discharge over−current
release delay time 1
Tocr1 VCC=3.7V 25°C 3.2 4 4.8 ms
−30 to 70°C 2.4 4 6
Discharge over−current
detection delay time 2
(Short circuit)
Toc2 VCC=3.7V 25°C 280 400 560 ms
−30 to 70°C 180 400 800
Charge Over−current
detection delay time
Toch VCC=3.7V 25°C 12.8 16 19.2 ms
−30 to 70°C 9.6 16 24
Charge Over−current
release delay time
Tochr VCC=3.7V 25°C 3.2 4 4.8 ms
−30 to 70°C 2.4 4 6
Product parametric performance is indicated in the Electrical Characteristics for the listed test conditions, unless otherwise noted. Product
performance may not be indicated by the Electrical Characteristics if operated under different conditions.
LC05111CMT
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Table 4. SELECTION GUIDE
Device Vov(V) Vovr(V) Vuv(V) Vuvr(V) Vuvr2(V) AWUP Ioc(A) Ioch(A) Ioc2(A) 0Vcharge
LC05111C01MTTTG 4.425 4.225 2.500 2.500 2.900 enable 6.0 4.0 17.5 enable
LC05111C02MTTTG 4.280 4.180 2.700 2.700 2.900 enable 6.0 3.5 21.5 enable
LC05111C05MTTTG 4.425 4.225 2.300 2.300 2.700 enable 4.0 4.0 17.5 enable
LC05111C13MTTTG 4.240 4.140 2.700 2.700 2.900 enable 3.0 2.5 15.0 enable
LC05111C14MTTTG 4.445 4.245 2.600 2.600 3.000 enable 4.0 4.0 17.5 enable
LC05111C16MTTTG 4.470 4.270 2.500 2.500 2.900 enable 7.0 5.7 17.5 enable
LC05111C18MTTTG 4.200 4.000 2.700 2.750 2.900 enable 6.0 2.5 17.5 enable
LC05111C20MTTTG 4.310 4.110 2.500 2.500 2.900 enable 3.0 2.0 15.0 enable
LC05111C21MTTTG 4.240 4.140 2.700 2.700 2.900 enable 6.0 5.0 17.5 enable
LC05111C23MTTTG 4.425 4.225 2.600 2.600 3.000 enable 5.2 4.0 17.5 enable
LC05111C25MTTTG 4.225 4.025 2.600 2.600 3.000 enable 4.2 4.2 17.5 enable
Pdmax−Ta Graph
LC05111CMT
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Figure 4. All
Zoom
It can perform the detection of the overcurrent exactly by
performing these.
It can get rid of influence of the wiring impedance caused by
a severe electric current flowing through S1 and S2.
Red line of schematic is very important line.
1.Please connect the VSS line to a pin of S1 directly.
2.Please connect the resistance of R2 to a pin of S2 directly.
1
2
NOTES:
LC05111CMT
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Table 5. PIN FUNCTIONS
Pin No. Symbol Pin Function Description
1 S2 Charger minus voltage input pin
2 CS Charger minus voltage input pin
3 TST Package trimming Terminal Connected to GND by internal 100 kW resistor
4 VSS Negative power Input
5 VCC VCC terminal
6 S1 Negative power input
7 Drain Drain of FET Exposed pad
8 Sub IC Sub (VSS) Exposed pad
Figure 5. Block Diagram
S2S1 CS
VCC
Control Circuit
OSC
Level
Shifter
Power
Control
Over−charge
Detector
Over−discharge
Detector
1.2V
Discharge
Over−current
Detector
DCHG_SW CHG_SW
Short−circuit
Detector
Charge
Over−current
Detector
(Pack minus)
1.2 V
VSS
TST
LC05111CMT
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Description of Operation
(1) Normal mode
•LC05111CMT controls charging and discharging by
detecting cell voltage (VCC) and controls S2−S1
current. In case that cell voltage is between
over−discharge detection voltage (Vuv) and
over−charge detection voltage (Vov), and S2−S1 current
is between charge over−current detection current (Ioch)
and discharge over−current detection current (Ioc),
internal power MOS FETs as CHG_SW, DCHG_SW
are all turned ON.
This is the normal mode, and it is possible to be
charged and discharged.
(2) Over−charging mode
•Internal power MOS FET as CHG_SW will be turned
off if cell voltage will get equal to or higher than
over−charge detection voltage (Vov) over the delay
time of over−charging (Tov).
This is the over−charging detection mode.
•The recovery from over−charging will be made after
the following three conditions are all satisfied.
a. Charger is removed from IC.
b. Cell voltage will get lower than over−charge
release voltage (Vovr) over the delay time of
over−charging release (Tovr) due to discharging
through load.
Consequently, internal power MOS FET as CHG_SW will
be turned on and normal mode will be resumed.
•In over−charging mode, discharging over−current
detection is made only when CS pin will get higher
than discharging over−current detection current 2(Ioc2),
because discharge current flows through parasitic diode
of CHG_SW FET.
If CS pin voltage will get higher than discharging
over−current detection current 2 (Ioc2) over the delay
time of discharging over−current 2 (Toc2), discharging
will be shut off, because internal power FETs as
DCHG_SW is turned off.(short−circuit detection mode)
After detecting short−circuit, CS pin will be pulled
down to Vss by internal resistor Rcsd.
The recovery from short circuit detection in over−charging
mode will be made after the following two conditions are
satisfied.
a. Load is removed from IC.
b. CS pin voltage will get equal to or lower than
discharging over−current detection current 2
(Ioc2) due to CS pin pulled down through Rcsd.
Consequently, internal power MOS FET as DCHG_SW will
be turned on, and over−charging detection mode will be
resumed.
(3) Over−discharging mode
•If cell voltage will get lower than over−discharge
detection voltage (Vuv) over the delay time of over−
discharging (Tuv), discharging will be shut off, because
internal power FETs as DCHG_SW is turned off.
This is the over−discharging mode.
After detecting over−discharging, CS pin will be pulled
up to Vcc by internal resistor Rcsu and the bias of
internal circuits will be shut off. (Stand−by mode)
In stand−by mode, operating current is suppressed
under 0.95 mA (max).
•The recovery from stand−by mode will be made by
internal circuits biased after the following two
conditions are satisfied.
a. Charger is connected.
b. VCC level rise more than Over−discharge
release voltage2(Vuvr2) without charger.(Auto
wake−up function)
•If CS pin voltage will get lower than charger detecting
voltage (Vchg) by connecting charger under the
condition that cell voltage is lower than over−discharge
detection voltage, internal power MOS FET as
DCHG_SW is turned on and power dissipation in
power MOS FETs is suppressed.
*In case that charging current is low enough, ripple current
will be appeared at S2 terminal when CS pin voltage is near
by the threshold of charger detecting voltage (Vchg).
It is caused that the two modes, charger detected and charger
not detected (charging through parasitic diodes of
DCHG_SW, is alternately appeared.
•By continuing to be charged, if cell voltage will get
higher than over−discharge detection voltage (Vuvr)
over the delay time of over−discharging (Tuvr), internal
power MOS FETs as DCHG_SW is turned on and
normal mode will be resumed.
•In over−discharge detection mode, charging
over−current detection does not operate.
By continuing to be charged, charging over−current
detection starts to operate after cell voltage goes up
more than over−discharge release voltage (Vuvr).
(4) Discharging over−current detection mode 1
•Internal power MOS FET as DCHG_SW will be turned
off and discharging current will be shut off if CS pin
voltage will get equal to or higher than discharging
over−current detection current (Ioc) over the delay time
of discharging over−current (Toc1).
This is the discharging over−current detection mode 1.
In discharging over−current detection mode 1, CS pin
will be pulled down to Vss with internal resistor Rcsd.
•The recovery from discharging over−current detection
mode will be made after the following two conditions
are satisfied.
LC05111CMT
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10
a. Load is removed from IC.
b. CS pin voltage will get equal to or lower than
discharging over−current release current (Iocr)
over the delay time of discharging over−current
release (Tocr1) due to CS pin pulled down
through Rcsd.
Consequently, internal power MOS FET as DCHG_SW will
be turned on, and normal mode will be resumed.
(5) Discharging over−current detection mode 2 (short circuit
detection)
•Internal power MOS FET as DCHG_SW will be turned
off and discharging current will be shut off if CS pin
voltage will get equal to or higher than discharging
over−current detection current2 (Ioc2) over the delay
time of discharging over−current 2 (Toc2).
This is the short circuit detection mode.
•In short circuit detection mode, CS pin will be pulled
down to Vss by internal resistor Rcsd.
The recovery from short circuit detection mode will be
made after the following two conditions are satisfied.
a. Load is removed from IC.
b. CS pin voltage will get equal to or lower than
discharging over−current release current (Iocr)
over the delay time of discharging over−current
release (Tocr1) due to CS pin pulled down
through Rcsd.
Consequently, internal power MOS FET as DCHG_SW will
be turned on, and normal mode will be resumed.
(6) Charging over−current detection mode
•Internal power MOS FET as CHG_SW will be turned
off and charging current will be shut off if CS pin
voltage will get equal to or lower than charging
over−current detection current (Ioch) over the delay
time of charging over−current (Toch).
This is the charging over−current detection mode.
•The recovery from charging over−current detection
mode will be made after the following two conditions is
satisfied.
a. Charger is removed from IC and CS pin will
get higher by load connected.
b. CS pin voltage will get equal to or higher than
charging over−current release current (Iochr)
over the delay time of charging over−current
release (Tocrh).
Consequently, internal power MOS FET as CHG_SW will
be turned on, and normal mode will be resumed.
*Internal current flows out through CS and S2 terminals.
After charger is removed, it flows through parasitic diode of
CHG_SW FET.
Therefore, CS pin voltage will go up more than charging
over−current release current (Iochr).
So CS pin voltage is not an indispensable condition for
recovery from charging over−current detection.
(7) Available Voltage for 0 V charging
It is the function that the voltage of a connected battery can
charge from the state that became 0 V by self−discharge. The
0 V battery charge start battery charger voltage (Vchg), it fix
a gate of the charge system order FET to the VDD terminal
voltage when it connect a battery charger of the
above−mentioned voltage to PAC+ terminal between PAC−
terminals.
Gate−source voltage of the charge control FET becomes
equal to the turn−on voltage or more due to the charger
voltage, the charging control FET.
To start charging row is turned on.
Discharge control FET is off at this time, the charge current
flows through the internal parasitic diode in the discharging
control FET. It is the normal state battery voltage becomes
the overdischarge release voltage (Vuvr) or more.
LC05111CMT
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15
Table 6. ORDERING INFORMATION
Device Package Shipping (Qty / Packing)
LC05111C01MTTTG WDFN6 2.6x4.0, 0.65P, Dual Flag
(Pb−Free / Halogen Free)
4000 / Tape & Reel
LC05111C02MTTTG WDFN6 2.6x4.0, 0.65P, Dual Flag
(Pb−Free / Halogen Free)
4000 / Tape & Reel
LC05111C05MTTTG WDFN6 2.6x4.0, 0.65P, Dual Flag
(Pb−Free / Halogen Free)
4000 / Tape & Reel
LC05111C13MTTTG WDFN6 2.6x4.0, 0.65P, Dual Flag
(Pb−Free / Halogen Free)
4000 / Tape & Reel
LC05111C14MTTTG WDFN6 2.6x4.0, 0.65P, Dual Flag
(Pb−Free / Halogen Free)
4000 / Tape & Reel
LC05111C16MTTTG WDFN6 2.6x4.0, 0.65P, Dual Flag
(Pb−Free / Halogen Free)
4000 / Tape & Reel
LC05111C18MTTTG WDFN6 2.6x4.0, 0.65P, Dual Flag
(Pb−Free / Halogen Free)
4000 / Tape & Reel
LC05111C20MTTTG WDFN6 2.6x4.0, 0.65P, Dual Flag
(Pb−Free / Halogen Free)
4000 / Tape & Reel
LC05111C21MTTTG WDFN6 2.6x4.0, 0.65P, Dual Flag
(Pb−Free / Halogen Free)
4000 / Tape & Reel
LC05111C23MTTTG WDFN6 2.6x4.0, 0.65P, Dual Flag
(Pb−Free / Halogen Free)
4000 / Tape & Reel
LC05111C25MTTTG WDFN6 2.6x4.0, 0.65P, Dual Flag
(Pb−Free / Halogen Free)
4000 / Tape & Reel
ÉÉ
ÉÉ
ÉÉ
WDFN6 2.6x4.0, 0.65P, Dual Flag
CASE 511BZ
ISSUE B
DATE 02 NOV 2016
SCALE 2:1 NOTES:
1. DIMENSIONING AND TOLERANCING PER
ASME Y14.5M, 1994.
2. CONTROLLING DIMENSION: MILLIMETERS.
3. PROFILE TOLERANCE APPLIES TO THE
EXPOSED PADS AS WELL AS THE LEADS.
XXXXX = Specific Device Code
A = Assembly Location
Y = Year
WW = Work Week
G= Pb−Free Package
123
45
TOP VIEW
SIDE VIEW
D
E
BA
0.10 C
0.10 C
2X
2X
A
0.05 C
0.10 C
GENERIC
MARKING DIAGRAM*
*This information is generic. Please refer to
device data sheet for actual part marking.
1
XXXXX
XXXXX
AYWWG
G
6
PIN ONE
REFERENCE
NOTE 3 CSEATING
PLANE
8X A3
(Note: Microdot may be in either location)
*For additional information on our Pb−Free strategy and soldering
details, please download the ON Semiconductor Soldering and
Mounting Techniques Reference Manual, SOLDERRM/D.
SOLDERING FOOTPRINT*
0.27
0.65
0.40
2.29
6X
PITCH
2.50
DIMENSION: MILLIMETERS
4.20
6X
0.53
PACKAGE
0.40
OUTLINE
1
RECOMMENDED
DIM MIN
MILLIMETERS
A−−−
A3 0.10
b0.25
D2.60 BSC
D2 2.075
D3 1.20
E4.00 BSC
E2 2.95
E3 2.25
L0.12
MAX
0.80
0.25
0.40
2.375
1.50
3.05
2.55
0.32
D4 0.40 0.70
e0.65 BSC
L2 −−− 0.10
BOTTOM VIEW
1
L
e
b
6X
A
M
0.10 BC
M
0.05 C
6X
E2
4X L2
D2
D4
D3
3
E3
64
E1
b2
4X
4X L3
b2 0.15 0.30
E1 3.80 REF
L3 −−− 0.55
XXXXX
AYWWG
w/ ejector pin
w/o ejector pin
MECHANICAL CASE OUTLINE
PACKAGE DIMENSIONS
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