EUTECH EUP9261BJVIR0

EUP9261
LI-ION/POLYMER ONE CELL PROTECTOR
DESCRIPTION
The EUP9261 series are lithium-ion/lithium polymer rechargeable battery protection ICs incorporating
high-accuracy voltage detection circuit and delay circuit. The EUP9261 series are suitable for protection of
single-cell lithium-ion/lithium polymer battery packs from overcharge, overdischarge and overcurrent.
FEATURES
Absolute maximum rating of 30V for the charger connection pins(VM and CO)
Highly accurate voltage detector………….Overcharge detection (Topt=+25°C)
z
z
(Topt=-5 to 55°C)
±30mV
Overcharge hysteresis
±25mV
Overdischarge detection
±50mV
Overcurrent 1 detection
±15mV
Overcurrent 2 detection
±100mV
Variety of detector………………………… Overcharge detection
z
±25mV
Overcharge hysteresis
Overdischarge detection
Overdischarge hysteresis
3.9V-4.4V step of 5mV
0.0V-0.4V*1 step of 50mV
2.0V-3.0V step of 10mV
0.0V-0.7V*2 step of 100mV
Overcurrent 1 detection
0.03V-0.3V step of 10mV
Overcurrent 2 detection
0.5V
*1 Overcharge release voltage=Over detection voltage-Overcharge hysteresis voltage
*2 Overdischarge release voltage = Overdischarge detection voltage-Overdischarge hysteresis voltage.
z
z
Delay times internally generated. Accuracy : ±30%.
(overcharge: tCU, overdischarge: tDL, overcurrent 1: tlOV1, overcurrent 2: tlOV2)
Three-step overcurrent detection circuit is included.(overcurrent 1,overcurrent 2 and load short – circuiting)
Charger detection function and abnormal charge current detection function, included.
z
0V-battery charge option: Acceptable/Unacceptable.
z
Low current consumption
z
„
„
z
z
z
z
Operation: 3.0µA typ. 6µA max.
Power-down 0.1µA max.
DP pin……………………………………...At VSS level, delay circuit is disabled. Tie a 300kΩ resistor to VSS,
delay time of all items expect short-circuit can be reduced.
Wide operating temperature range: -40°C to + 85°C.
Small package: SOT-23-6, STDFN-6(2mm*2mm)
RoHS compliant and 100% lead (Pb)-free
APPLICATIONS
z Lithium-ion rechargeable battery packs.
z Lithium polymer rechargeable battery packs.
DS9261 Ver2.4 Jan. 2007
1
EUP9261
Block Diagram
Figure1.
DS9261 Ver2.4 Jan. 2007
2
EUP9261
Pin Configurations
Package Type
Pin Configurations
SOT-23-6
STDFN-6
Pin Description
PIN
SOT-23-6
STDFN6
DO
1
3
VM
2
2
CO
3
1
CO FET gate control pin for charge(CMOS output)
DP
4
6
Pin for reduce output delay time and for delay time measurement
VDD
5
5
VDD Positive power input pin
VSS
6
4
VSS Negative power input pin
DS9261 Ver2.4 Jan. 2007
DESCRIPTION
DO FET gate control pin for discharge (CMOS output)
VM Voltage detection pin between VM and VSS
(Overcurrent detection pin)
3
EUP9261
Absolute Maximum Ratings
„
Input voltage between VDD and VSS
-------------------------------------------------- VSS -0.3 V to VSS +12 V
„
Input pin voltage for VM --------------------------------------------------------------
VDD -30 V to VDD +0.3 V
„
Output pin voltage for CO -------------------------------------------------------------
VVM -0.3 V to VDD +0.3 V
„
Output pin voltage for DO --------------------------------------------------------------- VSS -0.3 V to VDD +0.3 V
„
Power dissipation SOT-23-6 ----------------------------------------------------------------------------
„
Operating temperature range ---------------------------------------------------------------------
„
Storage temperature range
„
ESD Susceptibility
---------------------------------------------------------------------
250mW
-40°C to +85°C
-55°C to +125°C
HBM (Human Body Mode) -------------------------------------------------------------------------------
>1KV
MM (Machine Mode) ---------------------------------------------------------------------------------------
>200V
DS9261 Ver2.4 Jan. 2007
4
EUP9261
Ordering Information
Order Number
Package Type
Marking
Operating Temperature range
EUP9261AJVIR1
SOT-23-6
BJ □ □
-40°C to 85°C
EUP9261AJVIR0
SOT-23-6
BJ □ □
-40°C to 85°C
EUP9261BJVIR1
SOT-23-6
BT □ □
-40°C to 85°C
EUP9261BJVIR0
SOT-23-6
BT □ □
-40°C to 85°C
EUP9261BOVIR1
SOT-23-6
BO □ □
-40°C to 85°C
EUP9261BOVIR0
SOT-23-6
BO □ □
-40°C to 85°C
EUP9261BQVIR1
SOT-23-6
BQ □ □
-40°C to 85°C
EUP9261BQVIR0
SOT-23-6
BQ □ □
-40°C to 85°C
EUP9261BPVIR1
SOT-23-6
BP □ □
-40°C to 85°C
EUP9261BPVIR0
SOT-23-6
BP □ □
-40°C to 85°C
EUP9261BBVIR1
SOT-23-6
BB □ □
-40°C to 85°C
EUP9261BBVIR0
SOT-23-6
BB □ □
-40°C to 85°C
EUP9261BFVIR1
SOT-23-6
BF □ □
-40°C to 85°C
EUP9261BFVIR0
SOT-23-6
BF □ □
-40°C to 85°C
EUP9261BJSIR1
STDFN-6
□□□
BT
-40°C to 85°C
EUP9261□□
□ □ □ □
Lead Free Code
1:Lead Free
0:Lead
Packing
R: Tape& Reel
Operating temperature range
I: Industry Standard
Package Type
V: SOT-23-6, S: STDFN-6
Model No.
DS9261 Ver2.4 Jan. 2007
5
EUP9261
Application Circuit
Figure2.
Symbol
Parts
FET1
N channel
MOSFET
FET2
N channel
MOSFET
R1
Resistor
C1
Capacitor
R2
Resistor
Purpose
Charge control
Discharge control
Recommend
min.
--
--
--
--
max.
--
--
Remarks
Threshold voltage ≤ Overdischarge
detection voltage *1
Gate to source withstand voltage ≥
Charge voltage*2
Threshold voltage ≤ Overdischarge
detection voltage *1
Gate to source withstand voltage ≥
Charge voltage*2
470Ω
300Ω
1kΩ
Resistance should be as small as
possible to avoid lowering of the
overcharge detection accuracy caused
by VDD pin current. *3
For power fluctuation
0.1µF
0.022µF
1.0µF
Install a capacitor of 0.022µF or higher
between VDD and VSS. *4
Protection for
reverse connection
2kΩ
300Ω
4kΩ
Select a resistance as large as possible
to prevent current when a charger is
reversely connected. *5
ESD protection
For power fluctuation
of a charger
*1 If the threshold voltage of an EFT is low, the FET may not cut the charging current.
If an FET with a threshold voltage equal to or higher than the overdischarge detection voltage is used, discharging may be stoped
before overdischarge is detected.
*2 If the withstand voltage between the gate and source is lower than the charger voltage, the FET may destroy.
*3 If R1 has a high resistance, the voltage between VDD and VSS may exceed the absolute maximum rating when a charger is
connected reversely since the current flows from the charger to the IC.
Insert a resistor of 300Ω or higher as R1 for ESD protection.
*4 If a capacitor of less than 0.022µF is installed as C1,DO may oscillate when load short-circuiting is detected.
Be sure to install a capacitor of 0.022µF or higher as C1.
*5 If R2 has a resistance higher than 4kΩ, the charging current may not be cut when a high-voltage charger is connected.
Remark
The DP pin should be open.
Caution
The above connection diagram and constant will not guarantee successful operation. Perform through evaluation
using the actual application to set the constant.
DS9261 Ver2.4 Jan. 2007
6
EUP9261
Product name list
Overcharge
detection
voltage[VCU]
Overcharge
Hysteresis
voltage[VHC]
EUP9261AJ
4.325 V
EUP9261BJ
4.28
EUP9261BO
Overdischarge
detection
voltage [VDL]
Overdischarge
hysteresis
voltage [VHD]
Overcurrent 1
detection
voltage [VIOV1]
0V battery
charge function
0.25V
2.5V
0.4V
0.150V
Unavailable
0.2V
3.0V
0V
0.080V
Available
4.28
0.2V
2.3V
0V
0.040V
EUP9261BQ
4.28
0.2V
2.9V
0.1V
0.030V
Available
Available
EUP9261BP
4.35
0.2V
2.3V
0.7V
0.200V
Available
EUP9261BB
4.28
0.3V
2.3V
0.1V
0.125V
Available
EUP9261BF
4.28
0.2V
2.8V
0V
0.050V
Available
Model No.
Model No.
Overcharge detection
delay time
Overdischarge detection
delay time
Overcurrent 1 detection
delay time
EUP9261AJ
1.3s
175ms
12ms
EUP9261BJ
1.3s
12ms
EUP9261BO
1.3s
175ms
175ms
1.3s
175ms
12ms
EUP9261BF
1.3s
175ms
12ms
EUP9261BP
144ms
40ms
20ms
EUP9261BB
144ms
40ms
20ms
EUP9261BQ
12ms
Note: It is possible to change the detection voltages of the product other than above. The delay times can also be changed within
the range listed bellow. For details, please contact our sales office.
DS9261 Ver2.4 Jan. 2007
7
EUP9261
Electrical Characteristics (1) Except detection delay time (25°C)
Symbol
Parameter
Remark
Min
(Ta=25°C unless otherwise specified)
Measurement
Typ Max Unit
circuit
Detection Voltage
VHC
VCU
+0.025
VCU
+0.030
VHC
+0.025
VDL
-0.050
VDL
VDL
+0.050
V
2
-----
VHD
-0.050
VHD
VHD
+0.050
V
2
Overcurrent 1 detection voltage
VIOV1=0.05V to 0.3V,10mV Step
-----
VIOV1
-0.015
VIOV1
VIOV1
+0.015
V
2
Overcurrent 2 detection voltage
-----
0.4
0.5
0.6
V
2
-----
0.7
1
1.3
V
2
-----
-1.3
-1.0
-0.7
V
2
Operation voltage between VDD and
VSS
Internal circuit
operating voltage
1.5
--
8
V
---
VDSOP2 Operation voltage between VDD and VM
Internal circuit
operating voltage
1.5
--
28
V
---
VDD=3.5 V, VVM =0 V
1.0
3.0
6.0
µA
2
VDD=VVM =1.5 V
--
--
0.1
µA
2
VCO=3.0V,VDD=3.5V
VVM =0 V
2.5
5
10
kΩ
4
2.5
5
10
kΩ
4
2.5
5
10
kΩ
4
2.5
5
10
kΩ
4
VDD=1.8 V, VVM =0 V
100
300
900
kΩ
VDD=3.5 V, VVM =1.0 V
15
35
60
kΩ
3
1.2
--
--
V
2
--
--
0.5
V
2
VCU
-----
Overcharge detection voltage
VCU =3.9 V to 4.4 V, 5 mV Step
Ta = -5°C to 55°C*1
VHC
Overcharge hysteresis voltage
VHC=0.0V to 0.4V, 50mV Step
-----
VDL
Overdischarge detection voltage
VDL=2.0 V to 3.0 V, 10 mV Step
-----
VHD
Overdischarge hysteresis voltage
VHD=0.0V to 0.7V, 100mV Step
VIOV1
VIOV2
VSHORT Load short-circuiting detection voltage
VCHA
Charge detection voltage
VCU
-0.025
VCU
-0.030
VHC
-0.025
VCU
VCU
V
1
V
1
Input Voltage, Operation Voltage
VDSOP1
Current Consumption
IOPE
Current
consumption
operation
in
normal
IPDN
Current consumption at power down
Output Resistance
RCOH
CO pin H resistance
RCOL
CO pin L resistance
RDOH
DO pin H resistance
RDOL
DO pin L resistance
VCO=0.5 V, VDD= 4.5V,
VVM =0 V
VDO=3.0 V, VDD=3.5V,
VVM =0 V
VDO=0.5V VDD=VVM
=1.8 V
VM Internal Resistance
RVMD
RVMS
Internal resistance between VM and
VDD
Internal resistance between VM and
VSS
3
0V battery charging function
V0CHA
V0INH
0V battery charge starting charger
voltage
0V battery charge inhibition battery
voltage
0V battery charging
available
0V battery charging
unavailable
*1. Since products are not screened at low and high temperature, the specification for this temperature range is guaranteed by
design not tested in production.
DS9261 Ver2.4 Jan. 2007
8
EUP9261
1
Electrical Characteristics (2) Except detection delay time (-40°C to +85°C* )
Symbol
Parameter
Remark
(Ta= -40°C to +85°C*1 unless otherwise specified)
Measurement
Min
Typ
Max Unit
circuit
Detection Voltage
VCU
VHC
VDL
VHD
Overcharge detection voltage
VCU=3.9 V to 4.4 V, 5 mV Step
Overcharge hysteresis voltage
VHC=0.0V to 0.4V, 50mV Step
---------
Overdischarge detection voltage
VDL=2.0 V to 3.0 V, 10 mV Step
Overdischarge hysteresis voltage
VHD=0.0V to 0.7V, 100mV Step
VCU
-0.055
VHC
-0.030
VCU
VHC
VCU
+0.040
VHC
+0.030
V
1
V
1
-----
VDL
-0.080
VDL
VDL
+0.080
V
2
-----
VHD
-0.050
VHD
VHD
+0.050
V
2
VIOV1
Overcurrent 1 detection voltage
VIOV1=0.05V to 0.3V,10mV Step
-----
VIOV1
-0.025
VIOV1
VIOV1
+0.025
V
2
VIOV2
Overcurrent 2 detection voltage
-----
0.37
0.5
0.63
V
2
-----
0.5
1
1.5
V
2
-----
-1.5
-1.0
-0.5
V
2
1.5
--
8
V
---
1.5
--
28
V
---
VDD=3.5 V, VVM = 0 V
0.7
3.0
8.0
µA
2
VDD=V, VVM =1.5 V
--
--
0.1
µA
2
VSHORT Load short-circuiting detection voltage
VCHA
Charge detection voltage
Input Voltage, Operation Voltage
VDSOP1
Operation voltage between VDD and
VSS
VDSOP2 Operation voltage between VDD and VM
Internal circuit
operating voltage
Internal circuit
operating voltage
Current Consumption
IOPE
Current
consumption
operation
in
normal
IPDN
Current consumption at power down
Output Resistance
RCOH
CO pin H resistance
VCO = 3.0 V,
VDD=3.5V, VVM = 0 V
1.2
5
15
kΩ
4
RCOL
CO pin L resistance
VCO=0.5 V, VDD=4.5V,
VVM = 0 V
1.2
5
15
kΩ
4
RDOH
DO pin H resistance
VDO=3.0 V, VDD=3.5V,
VVM = 0 V
1.2
5
15
kΩ
4
RDOL
DO pin L resistance
VDO=0.5V,
VDD=VVM = 1.8V
1.2
5
15
kΩ
4
VM internal resistance
RVMD
Internal resistance between VM and
VDD
VDD=1.8 V, VVM =0 V
78
300
1310
kΩ
3
RVMS
Internal resistance between VM and VSS
VDD=3.5 V, VVM =1.0 V
10
35
70
kΩ
3
1.7
--
--
V
2
--
--
0.3
V
2
0V battery charging function
V0CHA
V0INH
0V battery charge starting charger
voltage
0V battery charge inhibition battery
voltage
0V battery charging
available
0V battery charging
unavailable
*1.Since products are not screened at low and high temperature, the specification for this temperature range is guaranteed by
design, no tested in production.
DS9261 Ver2.4 Jan. 2007
9
EUP9261
Electrical Characteristics (3) Detection delay time
(I) EUP9261 AJ, EUP9261BJ, EUP9261BO, EUP9261BQ, EUP9261BF
Symbol
Parameter
Remark
Min.
Typ.
Max.
Unit
Measurement
circuit
Delay time (25°C)
tCU
tDL
tIOV1
tIOV2
tSHORT
Overcharge detection delay time
Overdischarge detection delay time
Overcurrent 1 detection delay time
Overcurrent 2 detection delay time
Load short-circuiting detection delay
time
-----------------
0.91
122
8.4
2.1
1.3
175
12
3
1.69
228
15.6
3.9
s
ms
ms
ms
5
5
5
5
-----
200
320
500
µs
5
Delay time (-40°C to +85°C) *1
tCU
tDL
tIOV1
tIOV2
Overcharge detection delay time
Overdischarge detection delay time
Overcurrent 1 detection delay time
Overcurrent 2 detection delay time
-----------------
0.72
97
6.7
1.5
1.3
175
12
3
2.16
291
20
5
s
ms
ms
ms
5
5
5
5
tSHORT
Load short-circuiting detection delay
time
-----
150
320
600
µs
5
Min.
Typ.
Max.
Unit
Measurement
circuit
(II) EUP9261BB, EUP9261BP
Symbol
Parameter
Remark
Delay time (25°C)
tCU
tDL
tIOV1
tIOV2
Overcharge detection delay time
Overdischarge detection delay time
Overcurrent 1 detection delay time
Overcurrent 2 detection delay time
-----------------
100
28
14
2.1
144
40
20
3
187
52
26
3.9
ms
ms
ms
ms
5
5
5
5
tSHORT
Load short-circuiting detection delay
time
-----
200
320
500
µs
5
Delay time (-40°C to +85°C) *1
tCU
tDL
tIOV1
tIOV2
tSHORT
Overcharge detection delay time
Overdischarge detection delay time
Overcurrent 1 detection delay time
Overcurrent 2 detection delay time
-----------------
80
22.2
11
1.5
144
40
20
3
240
66.6
33
5
ms
ms
ms
ms
5
5
5
5
Load short-circuiting detection delay
time
-----
150
320
600
µs
5
DS9261 Ver2.4 Jan. 2007
10
EUP9261
Measurement Circuits
(4) Measurement Condition 4, Measurement Circuit 2
<Charger detection voltage, abnormal charge current
detection voltage.>
Unless otherwise specified, the output voltage levels “H”
and “L” at CO and DO pins are judged by the threshold
voltage (1.0 V) of the N channel FET. Judge the CO pin
level with respect to VVM and the DO pin level with
respect to VSS.
Set V1=1.8V and V2=0V. Increase V1 gradually until
V1=VDL+(VHD/2) , then decrease V2 from 0V gradually.
The voltage between VM and VSS when VDO goes “H”
from “L” is the charger detection voltage (VCHA). Charger
detection voltage can be measured only in the product
whose overdischarge hysteresis VHD ≠ 0.
Set V1=3.5V and V2=0V. Decrease V2 from 0V gradually.
The voltage between VM and VSS when VCO goes “L”
from “H” is the abnormal charge current detection voltage.
The abnormal charge current detection voltage has the
same value as the charger detection voltage (VCHA).
(1) Measurement Condition 1, Measurement Circuit 1
<Overcharge detection voltage, Overcharge hysteresis
voltage.>
The overcharge detection voltage (VCU) is defined by the
voltage between VDD and VSS at which VCO goes “L”
from “H” when the voltage V1 is gradually increased from
the starting condition V1=3.5V. The overcharge
hysteresis voltage (VHC) is then defined by the difference
between the overcharge detection voltage (VCU) and the
voltage between VDD and VSS at which VCO goes “H”
from “L” when the voltage V1 is gradually decreased.
(5) Measurement Condition 5, Measurement Circuit 2
<Normal operation current consumption, Power-down
current consumption.>
Set V1=3.5V and V2=0V under normal condition. The
current IDD flowing through VDD pin is the normal
operation consumption current (IOPE). Set V1=V2=1.5V
under overdischarge condition. The current IDD flowing
through VDD pin is the power-down current consumption
(IPDN).
(2) Measurement Condition 2, Measurement Circuit 2
<Overdischarge detection voltage, Overdischarge
hysteresis voltage >
The overdischarge detection voltage (VDL) is defined by
the voltage between VDD and VSS at which VDO goes “L”
from “H” when the voltage V1 is gradually decreased
from the starting condition V1=3.5V and V2 =0V. The
overdischarge hysteresis voltage (VHD) is then defined by
the difference between the overdischarge detection
voltage (VDL) and the voltage between VDD and VSS at
which VDO goes “H” from “L” when the voltage V1 is
gradually increased.
(6) Measurement Condition 6, Measurement Circuit 3
< Internal resistance between VM and VDD, Internal
resistance between VM and VSS. >
Set V1=1.8V and V2=0V. The resistance between VM
and VDD is the internal resistance (RVMD) between VM
and VDD. Set V1=3.5V and V2=1.0V. The resistance
between VM and VSS is the internal resistance (RVMS)
between VM and VSS.
(3) Measurement Condition 3, Measurement Circuit 2
<Overcurrent 1 detection voltage, Overcurrent 2
detection voltage, Load short-circuiting detection
voltage.>
(7) Measurement Condition 7, Measurement Circuit 4
<CO pin H resistance, CO pin L resistance>
The overcurrent 1 detection voltage (VIOV1) is defined by
the voltage between VM and VSS at which VDO goes ”L”
from “H” when the voltage V2 is gradually increased from
the normal condition V1 =3.5V and V2 =0V.
Set V1=3.5V, V2=0V and V3=3.0V. CO pin resistance is
the CO pin H resistance (RCOH). Set V1=4.5V, V2=0V and
V3=0.5V. CO pin resistance is the CO pin L resistance
(RCOL).
The overcurrent 2 detection voltage (VIOV2) is defined by
the voltage between VM and VSS at which VDO goes “L”
from “H” when the voltage V2 is increased at the speed
between 1ms and and 4ms from the normal condition
V1=3.5V and V2 = 0V.
(8) Measurement Condition 8, Measurement Circuit 4
<DO pin H resistance, DO pin L resistance.>
Set V1=3.5V, V2=0V and V4=3.0V. DO pin resistance
is the DO pin H resistance (RDOH).Set V1=1.8V,V2= 0V
and V4=0.5 V. DO pin resistance is the DO pin L
resistance (RDOL).
The load short-circuiting detection voltage (VSHORT) is
defined by the voltage between VDD and VSS at which
VDO goes “L” from “H” when the voltage V2 is increased
at the speed between 1µs and 50µs from the normal
condition V1=3.5V and V2=0V.
DS9261 Ver2.4 Jan. 2007
11
EUP9261
Set V1=3.5V and V2=0V. Increase V2 from 0V to 1.6V
momentarily (within 10µs). The time needed for VDO to go
“L” is the load short-circuiting detection delay time
(tSHORT).
(9) Measurement Condition 9, Measurement Circuit 5
<Overcharge detection delay time, Overdischarge
detection delay time.>
The overcharge detection delay time (tCU) is the time
needed for VCO to change from “H” to “L” just after the V1
rapid increase within 10 µs from the overcharge detection
voltage (VCU) - 0.2V to the overcharge detection voltage
(VCU) + 0.2V in the condition V2=0V. The overdischarge
detection delay time (tDL) is the time needed for VDO to
change from “H” to “L” just after the V1 rapid decrease
within 10µs from the overdischarge detection voltage
(VDL)+0.2V to the overdischarge detection voltage (VDL) .
0.2V in the condition V2=0V.
Set V1=3.5V and V2=0V. Decrease V2 from 0V to 1.1V
momentarily (within 10µs). The time needed for VCO to go
“L” is the abnormal charge current detection delay time.
The abnormal charge current detection delay time has
the same value as the overcharge detection delay time.
(11) Measurement Condition 11, Measurement Circuit 2
(Product with 0V battery charge function)
<0V battery charge starting charge voltage>
(10) Measurement Condition 10, Measurement Circuit 5
<Overcurrent 1 detection delay time, Overcurrent 2
detection delay time , Load short – circuiting detection
delay time , Abnormal charge current detection delay
time. >
Set V1=V2=0V and decrease V2 gradually. The voltage
between VDD and VM when VCO goes ”H” (VVM+0.1V or
higher) is the 0V battery charge starting charger voltage
(V0CHA).
Set V1=3.5V and V2=0V. Increase V2 from 0V to 0.35 V
momentarily (within 10µs). The time needed for VDO to go
“L” is overcurrent 1 detection delay time (tIOV1).Set
V1=3.5V and V2=0V. Increase V2 from 0V to 0.7V
momentarily (within 10µs). The time needed for VDO to go
“L” is overcurrent 2 detection delay time (tIOV2).
(12) Measurement Condition 12, Measurement Circuit 2
(Product with 0V battery charge inhibition function)
<0V battery charge inhibition battery voltage>
DS9261 Ver2.4 Jan. 2007
Set V1=0V and V2=4V. Increase V1 gradually. The voltage
between VDD and VM when VCO goes ”H” (VVM+0.1V or
higher) is the 0V battery charge inhibition battery voltage
(V0INH).
12
EUP9261
Measurement Circuit
Measurement Circuit 1
Measurement Circuit 2
Measurement Circuit 3
Measurement Circuit 4
Measurement Circuit 5
DS9261 Ver2.4 Jan. 2007
13
EUP9261
Characteristics
1. Detection/release voltage temperature characteristics
Overcharge detection voltage vs.
temperature
4.04
4.32
4.02
4.30
4.00
VCL(V)
VCU(V)
4.34
Overcharge release voltage vs.
temperature
4.28
4.26
3.98
3.96
3.94
4.24
3.92
4.22
-50
-25
0
25
Ta(℃)
50
75
-50
100
-25
2.54
2.92
2.52
2.90
VDU(V)
VDL(V)
2.94
2.5
100
2.48
2.88
2.86
2.46
2.84
2.44
2.82
25
50
Ta(℃)
75
100
-50
-25
Figure5.
0
25
50
Ta(℃)
75
100
Figure6.
Overcurrent1 detection voltage vs.
temperature
0.3
1.50
0.25
1.25
0.2
1.00
Viov2(V)
Viov1(V)
75
Overdischarge release voltage vs.
temperature
2.56
0
50
Figure4.
Overdischarge detection voltage vs.
temperature
-25
25
Ta(℃)
Figure3.
-50
0
0.15
0.1
0.05
Overcurrent 2 detection voltage
temperature
0.75
0.50
0.25
0.00
0
-50
-25
0
25
50
75
100
-50
Ta(℃)
Figure7.
DS9261 Ver2.4 Jan. 2007
-25
0
25
50
Ta(℃)
Figure8.
14
75
100
EUP9261
Load short-circuting detection voltage vs.
temperature
2.20
Vshort(V)
2.00
1.80
1.60
1.40
1.20
1.00
-50
-25
0
25
50
75
100
Ta(℃)
Figure9.
2. Current consumption temperature characteristics
Current consumption vs. temperature in
power-down mode
8.00
0.0600
7.00
0.0500
6.00
0.0400
Ipdn(uA)
Iope(uA)
Curremt consumption vs. temperature in
normal mode
5.00
4.00
3.00
0.0300
0.0200
0.0100
2.00
0.0000
-50
-25
0
25
Ta(℃)
50
75
100
-50
-25
0
Figure10.
25
50
Ta(℃)
75
100
Figure11.
3. Detection/release delay time temperature characteristics
Overdischarge detection delay time
vs.temperature
2.3
260
2
230
1.7
200
Tdl(ms)
Tcu(s)
Overcharge detection delay time
vs.temperature
1.4
1.1
0.8
170
140
110
0.5
80
-50
-25
0
25
Ta(℃)
50
75
100
-50
Figure12.
DS9261 Ver2.4 Jan. 2007
-25
0
25
Ta(℃)
50
Figure13.
15
75
100
EUP9261
Overcurrent 2 detection delay time vs.
temperature
17
6
15
5
Tiov2(ms)
Tiov1(ms)
Overcurrent 1 detection delay time vs.
temperature
13
11
9
3
2
7
1
5
0
-50
-25
0
25
50
75
-50
100
500
400
300
200
25
50
75
100
Ta(℃)
Figure16.
DS9261 Ver2.4 Jan. 2007
50
Figure15.
600
0
25
Figure14.
700
-25
0
Ta(℃)
800
-50
-25
Ta(℃)
Load short-circuiting delaytime vs.
temperature
Tshort(us)
4
16
75
100
EUP9261
Description of Operation
Normal condition
Overcharge condition
The EUP9261 monitors the voltage of the battery
connected between VDD and VSS pin and the voltage
difference between VM and VSS pin to control charging
and discharging. When the battery voltage is in the
range from the overdischarge detection voltage (VDL) to
the overcharge detection voltage (VCU), and the VM pin
voltage is in the range from the charger detection
voltage (VCHA) to the overcurrent 1 detection voltage
(VIOV1), the IC turns both the charging and discharging
control FETs on. This condition is called the normal
condition, and in this condition charging and
discharging can be carried out freely.
Note: When a battery is connected to the IC for the first
time, the battery may not enter dischargeable state. In
this case, set the VM pin voltage equal to the VSS
voltage or connect a charger to enter the normal
condition.
When the battery voltage becomes higher than the
overcharge detection voltage (VCU) during charging
under the normal condition and the detection
continues for the overcharge detection delay time (tCU)
or longer, the EUP9261 turns the charging control
FET off to stop charging. This condition is called the
overcharge condition. The overcharge condition is
released by the following two cases ((1) and (2)):
(1) When the battery voltage falls below the
overcharge release voltage, which is equal to the
overcharge detection voltage (VCU) overcharge
detection hysteresis voltage (VHC), the EUP9261 turns
the charging control FET on and turns to the normal
condition.
(2) When a load is connected and discharging starts,
the EUP9261 turns the charging control FET on and
returns to the normal condition. Just after the load is
connected and discharging starts, the discharging
current flows through the parasitic diode in the
charging control FET. At this moment the VM pin
potential becomes Vf -volt, the voltage for the parasitic
diode, higher than VSS level. When the battery
voltage goes under the overcharge detection voltage
(VCU) and provided that the VM pin voltage is higher
than the overcurrent 1 detection voltage, the
EUP9261 releases the overcharge condition.
Note1:
If the battery is charged to a voltage higher than the
overcharge detection voltage (VCU) and the battery
voltage does not fall below the overcharge detection
voltage (VCU) even when a heavy load is connected,
the detection of overcurrent 1, overcurrent 2 and load
short-circuiting does not work. Since an actual battery
has the internal impedance of several dozens of mΩ,
the battery voltage drops immediately after a heavy
load which causes overcurrent is connected, and the
detection of overcurrent 1, overcurrent 2 and load
short-circuiting then works.
Note2:
When a charger is connected after the overcharge
detection, the overcharge condition is not released
even if the battery voltage is below the overcharge
release voltage (VCL (＝Vcu －VHC)). The overcharge
condition is released when the VM pin voltage goes
over the charger detection voltage (VCHA) by removing
the charger.
Overcurrent condition (Detection of Overcurrent 1,
Overcurrent 2 and Load short-circuiting)
When the condition in which VM pin voltage is equal to
or higher than the overcurrent detection voltage,
condition that caused by the excess of discharging
current over a specified value, continues longer than
the overcharge detection delay time in a battery under
the normal condition, the EUP9261 turns the
discharging control FET off to stop discharging. This
condition is called the overcurrent condition. Though
the VM and VSS pins are shorted by the RVMS resistor
in the IC under the overcurrent condition, the VM pin
voltage is pulled to the VDD level by the load as long
as the load is connected. The VM pin voltage returns to
VSS level when the load is released. The overcurrent
condition returns to the normal condition when the
impedance between the EB+ and EB- pin (see Figure 2)
becomes higher than the automatic recoverable
impedance, and the IC detects that the VM pin
potential is lower than the overcurrent 1 detection
voltage (VIOV1).
Note: The automatic recoverable impedance changes
depending on the battery voltage and overcurrent 1
detection voltage settings.
DS9261 Ver2.4 Jan. 2007
17
EUP9261
Overdischarge condition
Abnormal charge current detection is released when
the voltage difference between VM pin and VSS pin
becomes less than charger detection voltage (VCHA).
When the battery voltage falls below the
overdischarge detection voltage (VDL) during
discharging under the normal condition and the
detection continues for the overdischarge detection
delay time (tDL) or longer, the EUP9261 turns the
discharging control FET off to stop discharging. This
condition is called the overdischarge condition. When
the discharging control FET turns off, the VM pin
voltage is pulled up by the RVMD resistor between VM
and VDD in the IC. The voltage difference between
VM and VDD then falls bellow 1.3V (typ.), the current
consumption is reduced to the power-down current
consumption (IPDN). This condition is called the
power-down condition. The power-down condition is
released when a charger is connected and the
voltage difference between VM and VDD becomes
1.3V (typ.) or higher. Moreover when the battery
voltage becomes the overdischarge detection voltage
(VDL) or higher, the EUP9261 turns the discharging
FET on and returns to the normal condition.
Delay circuits
The detection delay times are generated by dividing the
approximate 3.5 KHz clock with a counter.
Note1:
The detection delay time for overcurrent 2 and load
short-circuiting start when the overcurrent 1 is detected.
As soon as the overcurrent 2 or load short-circuiting is
detected over the detection delay time for overcurrent 2
or load short-circuiting after the detection of
Overcurrent 1, the EUP9261 turns the discharging
control FET off.
Charger detection
When a battery in the overdischarge condition is
connected to a charger and provided that the VM pin
voltage is lower than the charger detection voltage
(VCHA), the EUP9261 releases the overdischarge
condition and turns the discharging control FET on as
the battery voltage becomes equal to or higher than the
overdischarge detection voltage (VDL) since the charger
detection function works. This action is called charger
detection. When a battery in the overdischarge
condition is connected to a charger and provided that
the VM pin voltage is not lower than the charger
detection voltage (VCHA), the EUP9261 releases the
Overdischarge condition when the battery voltage
reaches the overdischarge detection voltage (VDL)
overdischarge hysteresis (VHD) or higher.
Figure17.
Note2:
When the overcurrent is detected and it continues for
longer than the Overdischarge detection delay time
without releasing the load, the load, the condition
changes to the power-down condition when the
battery voltage falls below the Overdischarge
detection voltage.
Note3:
When the battery voltage falls below the
Overdischarge detection voltage due to the
overcurrent, the EUP9261 turns the discharging
control FET off by the overcurrent detection. And in
this case the recovery of the battery voltage is so
slow that the battery voltage after the Overdischarge
detection delay time is still lower than the
Overdischarge detection voltage, the EUP9261
transits to the power-down condition.
Abnormal charge current detection
If the VM pin voltage falls below the charger detection
voltage (VCHA) during charging under normal condition
and it continues for the overcharge detection delay time
(tCU) or longer, the charging control. FET turns off and
charging stops. This action is called the abnormal
charge current detection. Abnormal charge current
detection works when the DO pin voltage is “H” and the
VM pin voltage falls below the charger detection
voltage (VCHA). Consequently, if an abnormal charge
current flows to an over-discharged battery, the
EUP9261 turns the charging control FET off and stops
charging after the battery voltage becomes higher than
the overdischarge detection voltage which make the
DO pin voltage “H”, and still after the overcharge
detection delay time (tCU) elapses.
DS9261 Ver2.4 Jan. 2007
18
EUP9261
DP pin
0V battery charge inhibition function*1
The DP pin is a test pin for delay time measurement
and for output delay time reduction or bypass. It should
be open or VDD level in the actual application.
For reducing delay time, connect this pin with a 300kΩ
resistor to VSS. An internal clock can be measured.
Under this condition, output delay time of over-charge,
over-discharge, over-current1 and over-current2 can be
shorter than the setting value (delay time for over
charge becomes about 1/64 of normal state).
By forcing this pin to VSS, output delay time circuit can
be disabled.
This function inhibits the recharging when a battery
which is short-circuited (0V) internally is connected.
When the battery voltage is 0.6V (typ.) or lower, the
charging control FET gate is fixed to EB- pin voltage to
inhibit charging. When the battery voltage is the 0V
battery charge inhibition battery voltage (V0INH) or
higher, charging can be performed.
*1.Some battery providers do not recommend
charging for completely self-discharged battery.
Please ask battery providers before determining
the 0V battery charge function.
*2.The 0V battery charge function has higher priority
than the abnormal charge current detection
function. Consequently, a product with the 0V
battery charge function charges a battery forcedly
and abnormal charge current cannot be detected
when the battery voltage is low.
0V battery charge function*1*2
This function is used to recharge the connected battery
whose voltage is 0V due to the self-discharge.
When the 0V battery charge starting charge voltage
(V0CHA) or higher is applied between EB+ pin and
EB-pin by connecting a charger, the charging control
FET gate is fixed to VDD pin voltage. When the voltage
between the gate and source of the charging control
FET becomes equal to or higher than the turn-on
voltage e by the charger voltage, the charging control
FET turns on to start charging. At this time, the
discharging control FET is off and the charging current
flows through the internal parasitic diode in the
discharging control FET. When the battery voltage
becomes equal to or higher than the overdischarge
release voltage (VDU), the EUP9261 enters the normal
condition.
DS9261 Ver2.4 Jan. 2007
19
EUP9261
Operation Timing Chart
1. Overcharge and Overdischarge Detection
Figure18.
2. Overcurrent Detection
Figure19.
Note: (1) Normal condition. (2) Overcharge condition. (3) Overdischarge condition. (4) Overcurrent condition
The charger is supposed to charge with constant current
DS9261 Ver2.4 Jan. 2007
20
EUP9261
3. Charger Detection
Figure20.
4. Abnormal Charge Current Detection
Figure21.
Note: (1) Normal condition. (2) Overcharge condition. (3) Overdischarge condition. (4) Overcurrent condition
The charger is supposed to charge with constant current
DS9261 Ver2.4 Jan. 2007
21
EUP9261
Package Information
SOT-23-6
SYMBOLS
A
A1
b
D
E1
e
E
L
DS9261 Ver2.4 Jan. 2007
MILLIMETERS
MIN.
MAX.
1.45
0.00
0.15
0.30
0.50
2.90
1.60
0.95
2.60
3.00
0.30
0.60
22
INCHES
MIN.
0.000
0.012
MAX.
0.057
0.006
0.020
0.114
0.063
0.037
0.102
0.012
0.118
0.024
EUP9261
Package Information
STDFN-6
SYMBOLS
A
A1
b
D
D1
E
E1
e
L
DS9261 Ver2.4 Jan. 2007
MILLIMETERS
MIN.
MAX.
0.50
0.60
0.00
0.05
0.15
0.35
1.85
2.15
1.40
1.85
2.15
0.80
0.65
0.25
0.45
23
INCHES
MIN.
0.020
0.000
0.006
0.073
MAX.
0.024
0.002
0.014
0.085
0.055
0.073
0.085
0.031
0.026
0.010
0.018