EUTECH EUP8051A

EUP8051A
Low Cost 1A Linear Battery Charge
Controllers
DESCRIPTION
FEATURES
The EUP8051A is a single Lithium-Ion (Li-Ion) and
Lithium–Polymer (Li-Pol) linear charge management
controller for use in cost sensitive and portable
applications. It combines high accuracy constant-current
and constant-voltage regulation, cell preconditioning,
temperature monitoring, automatic charge termination,
charge-status indication, in a space-saving MSOP-8
package.
The EUP8051A applies a constant current up to 1A to the
battery and the charge current can be programmed
externally with a sense-resistor.
The EUP8051A automatically terminates the charge cycle
when the charge current drops to the charge termination
threshold (ITERM) after the charge-regulation voltage is
reached.
When the input supply is removed, the EUP8051A
automatically enters a low-power sleep mode, dropping
the battery drain current to less than 1µA.
A battery charge state output pin is provided to indicate
battery charge status through a display LED. The battery
charge status output is a serial interface which may also be
read by a system microcontroller.
z
z
z
Programmable Charge Current up to 1A
4.5V-7V Input Voltage Range
Ideal for Single Cell (4.2V) Li-Ion or Li-Pol
Batteries
z
z
z
z
Preset Charge Voltage with ±1% Accuracy
Constant-Current/Constant Voltage Operation
Preconditioning of Low Voltage Cells
Optional Cell-Temperature Monitoring Before and
During Charge
Charge Status Indication
Automatic Battery Recharge
Charge Termination by Minimum Current
Automatic Low-Power Sleep Mode When Input
Power is Removed
Available in MSOP-8 Package
RoHS Compliant and 100% Lead (Pb)-Free
DS8051A Ver 1.1
Nov. 2006
1
z
z
z
z
z
z
APPLICATIONS
z
z
Cellular Phones / PDAs/ MP3 Players/DSC
Handheld Instruments
EUP8051A
Typical Application Circuit
DS8051A Ver 1.1
Nov. 2006
2
EUP8051A
Pin Configurations
Part
Number
Pin
Configurations
EUP8051A
MSOP-8
Pin Description
PIN
MSOP-8
I/O
VCC
1
I
Supply Voltage Input
TS
2
I
Temperature Sense Input
STAT
3
O
Charge Status Output
VSS
4
CC
5
O
FB/CE
6
I
SNS
7
I
Charge Control Output
External Feedback input or Charge Enable Function. Input from controller
or finely adjust the battery regulated voltage with external voltage divider
Current Sense Input
BAT
8
I
Battery Voltage Input
DS8051A Ver 1.1
Nov. 2006
DESCRIPTION
Ground
3
EUP8051A
Ordering Information
Order Number
Package Type
Marking
Operating Temperature range
EUP8051A-42MIR1
MSOP-8
xxxx
8051A
-20 °C to 70°C
EUP8051A-□□ □ □ □ □
Lead Free Code
1: Lead Free 0: Lead
Packing
R: Tape& Reel
Operating temperature range
I: Industry Standard
Package Type
M: MSOP
Output Voltage
42: 4.2V
DS8051A Ver 1.1
Nov. 2006
4
EUP8051A
Absolute Maximum Ratings
„
„
„
„
„
„
„
„
„
Supply voltage, (Vcc with respect to GND) ------------------------------------------------------ -0.3 to +10V
Input voltage, SNS, BAT, TS, PI (all with respect to GND)-------------------------- -0.3V to VCC +0.3V
Sink current (STAT pin) not to exceed PD -------------------------------------------------------------- 20mA
Source current (STAT pin) not to exceed PD ---------------------------------------------------------- 10mA
Output current (CC pin) not to exceed PD -------------------------------------------------------------- 40mA
Maximum Junction Temperature, TJ ------------------------------------------------------------------- 150°C
Storage temperature range, Tstg ------------------------------------------------------------- -65°C to 150°C
Lead temperature (soldering, 10s) -----------------------------------------------------------------300°C
Package Thermal Resistance, θJA- MSOP8 ---------------------------------------------------------- 80°C/W
Recommended Operating Conditions
Min.
Max.
Unit
Supply voltage, VCC
4.5
7
V
Operating free-air temperature range, TA
-20
70
°C
Electrical Characteristics over Recommended Operating Free-Air Temperature Range
EUP8051A
Symbol
Parameter
Conditions
Min. Typ. Max.
I(VCC)
VCC current
I(VCCS)
VCC Sleep current
VCC=5V >VCC(min), Excluding
external loads
0.5
Unit
1
mA
V(BAT) ≥ V(min),
V(BAT)-VCC ≥ 0.8V
6
µA
IIB(BAT)
Input bias current on BAT pin
V(BAT)=V(REG)
1
µA
IIB(SNS)
Input bias current on SNS pin
V(SNS)=5V
1
µA
IIB(TS)
Input bias current on TS pin
V(TS)=5V
1
µA
IIB(PI)
Input bias current on PI pin
V(PI)=5V
1
µA
4.242
V
Battery Voltage Regulation
VO(REG)
Output voltage
DS8051A Ver 1.1
Nov. 2006
EUP8051A-4.2
5
4.158
4.20
EUP8051A
Electrical Characteristics Over Recommended Operating Free-Air Temperature Range
Symbol
V(SNS)
Parameter
Conditions
Current regulation threshold Voltage at pin SNS, relative to VCC
EUP8051A
Unit
Min.
Typ. Max.
180
200
220
mV
5
15
25
mV
29
30
31
58
60
62
3.14
3.2
3.26
Charge Termination Detection
I(TERM)
Charge termination current Voltage at pin SNS, relative to VCC
detect threshold
0°C ≤ TA ≤ 50°C
Temperature Comparator
V(TS1)
Lower temperature threshold
V(TS2)
Upper temperature threshold
TS pin voltage
%VCC
Precharge Comparator
V(min)
Precharge threshold
EUP8051A-4.2
V
Precharge Current Regulation
I(PRECHG) Precharge current regulation
Voltage at pin SNS, relative to VCC
0°C ≤ TA ≤ 50°C
Voltage at pin SNS, relative to VCC
0°C ≤ TA ≤ 50°C , VCC=5V
18
5
mV
33
mV
VRCH comparator(Battery Recharge Threshold)
V(RCH)
Recharge threshold
EUP8051A-4.2
VOL(STAT)
Output(low)voltage
IOL=10mA
VOH(STAT)
Output(high)voltage
IOH=5mA
VOL(CC)
Output low voltage
IO(CC)=5mA(sink)
IO(CC)
Sink current
VO(REG)- VO(REG)- VO(REG)102mV 100mV 98mV
V
STAT Pin
0.7
VCC-0.8
V
CC Pin
DS8051A Ver 1.1
Nov. 2006
Not to exceed power rating specification(PD)
6
5
2
V
40
mA
EUP8051A
Typical Operating Characteristics
Battery Recharge Threshold vs. Temperature
4.30
4.35
4.25
Battery Recharge Threshold(V)
Battery Voltage Regulation(V)
Battery Voltage Regulation vs. Temperature
4.40
4.30
4.25
4.20
4.15
4.10
4.05
4.20
4.15
4.10
4.05
4.00
3.95
3.90
4.00
-20
0
20
40
60
-20
80
0
20
40
60
80
60
80
o
o
Temperature( C)
Temperature( C)
Precharge Threshold vs. Temperature
Current Regulation vs. Temperature
3.40
1300
1200
3.30
Current Regulation(mA)
Precharge Threshold(V)
3.35
3.25
3.20
3.15
3.10
1100
1000
900
3.05
3.00
-20
0
20
40
60
800
80
-20
0
o
Temperature( C)
20
40
o
Temperature( C)
Precharge Threshold vs. Temperature
Battery Voltage Regulation vs. Supply Voltage
4.40
4.35
Battery Voltage Regulation(V)
Precharge Threshold(mA)
140
120
100
80
60
-20
0
20
40
60
4.20
4.15
4.10
4.05
4.5
Temperature( C)
Nov. 2006
4.25
4.00
80
o
DS8051A Ver 1.1
4.30
5.0
5.5
6.0
Supply Voltage(V)
7
6.5
7.0
EUP8051A
Precharge Threshold vs. Supply Voltage
Current Regulation vs. Supply Voltage
1300
140
Precharge Threshold(mA)
Current Regulation (mA)
1200
1100
1000
900
120
100
80
60
800
4.5
5.0
5.5
6.0
4.5
6.5
Supply voltage(V)
DS8051A Ver 1.1
Nov. 2006
5.0
5.5
Supply Voltage(V)
8
6.0
EUP8051A
Application Information
Functional Description
The EUP8051A is an advanced 1A linear charge controller for single Li-Ion of Li-Pol applications. Refer to Blocking
Diagram (Figure3) and Operation Flow Chart (Figure4) in this section.
DS8051A Ver 1.1
Nov. 2006
9
EUP8051A
Power On Reset
VCC
Applied
NO
Sleep Mode
YES
Temperature
Fault
NO
Temperature
Test
TS>VTS1
TS<VTS2
YES
Preconditioning
Test
VMIN > VBAT
YES
Low Current
Conditioning
Charge
(Trickle Charge)
NO
Current
Phase Test
VREG>VBAT
YES
Constant
Current
Charging
Mode
NO
Voltage Phase
Test
IBAT>ITERM
YES
Constant
Voltage
Charging
Mode
NO
Charge
Termination
NO
Recharge Test
VRCH>VBAT
YES
Figure4. Operation Flow Chart
DS8051A Ver 1.1
Nov. 2006
10
EUP8051A
Qualification and Precharge
When power is applied, the EUP8051A starts a
charge-cycle if a battery is already present or when a
battery is inserted. Charge qualification is based on
battery temperature and voltage.
The EUP8051A suspends charge if the battery
temperature is outside the V(TS1) to V(TS2) range and
suspends charge until the battery temperature is within
the allowed range. The EUP8051A also checks the
battery voltage. If the battery voltage is below the
precharge threshold V(min), the EUP8051A uses
precharge to condition the battery. The conditioning
charge rate I(PRECHG) is set at approximately 10% of the
regulation current. The conditioning current also
minimizes heat dissipation in the external pass-element
during the initial stage of charge. See Figure5 for a
typical charge-profile.
Voltage Regulation Phase
The voltage regulation feedback is through the BAT pin.
This input is tied directly to the positive side of the
battery pack. The EUP8051A monitors the battery-pack
voltage between the BAT and VSS pins. The EUP8051A
is offered in two fixed-voltage versions:4.2V.
FB/CE Pin Function
This pin has two functions, one is to enable/disable the
charge function, and the other is to finely adjust battery
regulation voltage. Connect this pin to VDD to enable
EUP8051A, and connect to ground to disable it (Figure7).
If this pin is connected to a voltage divider as shown in
Figure8, it can be a 2.15V reference voltage to adjust the
output regulation voltage as desired.
Current Regulation Phase
The EUP8051A regulates current while the battery-pack
voltage is less than the regulation voltage, VO(REG). The
EUP8051A monitors charge current at the SNS input by
the voltage drop across a sense-resistor, RSNS, in series
with the battery pack. In current sensing configuration
(Figure6), RSNS is between the VCC and SNS pins,
charge-current feedback, applied through pin SNS,
maintains a voltage of V(SNS) across the current sense
resistor. The following formula calculates the value of the
sense resistor:
R
SNS
=
V
(SNS)
I
---------------------------- (1)
O(REG)
Where IO(REG) is the desired charging current.
Example: For 0.55A, RSNS: 0.22V/0.55A: 0.4Ω
For 1.0A, RSNS: 0.22V/1.0A: 0.22Ω
DS8051A Ver 1.1
Nov. 2006
11
EUP8051A
For PTC Thermistors
R
R
V
= 2.15 × (1 + FB1 )V
O(REG)
R
FB2
Charge Termination and Recharge
The EUP8051A monitors the charging current during the
voltage-regulation phase. The EUP8051A declares a done
condition and terminates charge when the current drops
to the charge termination threshold, I(TERM). A new charge
cycle begins when the battery voltage falls below the
V(RCH) threshold.
Battery Temperature Monitoring
The EUP8051A continuously monitors temperature by
measuring the voltage between the TS and VSS pins. A
negative-or a positive-temperature coefficient thermistor
(NTC, PTC) and an external voltage divider typically
develop this voltage (See Figure9). The EUP8051A
compares this voltage against its internal V(TS1) and V(TS2)
thresholds to determine if charging is allowed. (See
Figure10). The temperature sensing circuit is immune to
any fluctuation in VCC, since both the external voltage
divider and the internal thresholds (V(TS1) and V(TS2)) are
referenced to VCC.
The resistor values of R(T1) and R(T2) are calculated by the
following equations:
For NTC Thermistors
R
T1
T2
=
=
5× R
3 × (R
TH
TC
×R
-R
TC
TH
)
----------------------- (3)
5× R
×R
TH
TC
--------------- (4)
[(2 × (R
) - (7 × R
)]
TH
TC
DS8051A Ver 1.1
Nov. 2006
T2
=
5× R
3 × (R
TH
TH
5× R
×R
-R
TC
TC
)
---------------------- (5)
×R
TH
TC
[(2 × (R
) - (7 × R
)]
TH
TC
------------- (6)
Where R(TC) is the cold temperature resistance and R(TH)
is the hot temperature resistance of thermistor, as
specified by the thermistor manufacturer.
RT1 or RT2 can be omitted if only one temperature (hot or
cold) setting is required. Applying a voltage between the
V(TS1) and V(TS2) thresholds to pin TS disables the
temperature-sensing feature.
R
R
T1
=
12
EUP8051A
Charge Inhibit Function
The TS pin can be used as charge-inhibit input. The user
can inhibit charge by connecting the TS pin to VCC or
VSS (or any level outside the V(TS1) to V(TS2) thresholds).
Applying a voltage between the V(TS1) and V(TS2)
thresholds to pin TS returns the charger to normal
operation.
Charge Status Indication
The EUP8051A reports the status of the charger on the
3-state STAT pin. The following table summarized the
operation of the STAT pin.
Condition
Battery conditioning and charging
Charge complete(done)
Temperature fault or sleep mode
STAT pin
High
Low
Hi-Z
The STAT pin can be used to drive a single LED
(Figure1), dual-chip LEDs (Figure2) or for interface to a
host or system processor (Figure11). When interfacing
the EUP8051A to a processor, the user can use an output
port, to recognize the high-Z state of the STAT pin. In
this configuration, the user needs to read the input pin,
toggle the output port and read the STAT pin again. In a
high-Z condition, the input port always matches the
signal level on the output port.
Selecting Input Capacitor
In most applications, all that is needed is high-frequency
decoupling capacitor. A 0.1µF ceramic, placed in
proximity to VCC and VSS pins, works well. The
EUP8051A works with both regulated and unregulated
external dc supplies. If a non-regulated supply is chosen,
the supply unit should have enough capacitance to hold
up the supply voltage to the minimum required input
voltage at maximum load. If not, more capacitance must
be added to the input of the charger.
Selecting Output Capacitor
The EUP8051A does not require any output capacitor for
loop stability.
In order to maintain good AC stability in the Constant
Voltage mode, a minimum capacitance of 10µF is
recommenced to bypass the VBAT pin to VSS. This
capacitance provides compensation when there is no
battery load. In addition, the battery and interconnections
appear inductive at high frequencies. These elements are
in the control feedback loop d＞uring Constant Voltage
mode. Therefore, the bypass capacitance may be
necessary to compensate for the inductive nature of the
battery pack.
Virtually any good quality output filter capacitor can be
used, independent of the capacitor’s minimum ESR
(Effective Series Resistance) value. The actual value of
the capacitor and its associated ESR depends on the
forward transconductance (gm) and capacitance of the
external pass transistor. A 10µF tantalum or aluminum
electrolytic capacitor at the output is usually sufficient to
ensure stability for up to a 1A output current.
Selecting An External Pass-Device (PMOS or PNP)
The EUP8051A is designed to work with both P-channel
MOSFET or PNP transistor. The device should be chosen
to handle the required power dissipation, given the circuit
parameters, PCB layout and heat sink configuration. The
following examples illustrate the design process for
PMOS device:
Low-Power Sleep Mode
When the input supply is disconnected, the charger
automatically enters power-saving sleep mode.
Only consuming an ultra-low 1µA in sleep mode, the
EUP8051A minimizes battery drain when it is not
charging.
DS8051A Ver 1.1
Nov. 2006
13
P-Channel MOSFET
Selection steps for a P-channel MOSFET: We will use
the following conditions: VI=5V (with 10% supply
tolerance); I(REG)=1A, 4.2-V single-cell Li-Ion. VI is the
input voltage to the charger and I(REG) is the desired
charge current. (See Figure2)
EUP8051A
1.
Determine the maximum power dissipation, PD , in
the transistor.
The worst case power dissipation happens when the
cell voltage, V(constant), is at its lowest (typically 3.1V
at the beginning of current regulation phase) and VI
is at its maximum. Where VD is the forward voltage
drop across the reverse-blocking diode (if one is
used), and VCS is the voltage drop across the current
sense resistor.
Determine the package size needed in order to keep
the junction temperature below the manufacturer’s
recommended value, TJMAX. Calculate the total theta,
θ(°C/W), needed.
θ
θ
JA
JA
=
=
DS8051A Ver 1.1
(T
-T
)
max(J) A(max)
P
D
(150 - 40)
1.8
Nov. 2006
3.
4.
5.
PD=(VI(MAX)－VD－VCS－VBAT)×IREG --------- (7)
PD=(5.5－0.4－0.2－3.1)×1A
PD=1.8W
2.
It is recommended to choose a package with a lower θJA
than the number calculated above.
--------------(8)
θJA = 61°C/W
Select a drain-source voltage, V(DS), rating greater
than the maximum input voltage. A 12V device will
be adequate in this example.
Select a device that has at least 50% higher drain
current (ID) rating than the desired charge current
I(REG).
Verify that the available drive is large enough to
supply the desired charge current.
V(GS)=(VD+V(CS)+VOL(CC))－VI(min) -------------- (9)
V(GS)=(0.4+0.2+1) － 4.5
V(GS)=-2.9
Where V(GS) is the gate-to-source voltage, VD is the
forward voltage drop across the reverse-blocking diode
(if one is used), and VCS is the voltage drop across the
current sense resistor, and VOL(CC) is the CC pin output
low voltage specification for the EUP8051A.
Select a MOSFET with gate threshold voltage, V(GSth),
rating less than the calculated V(GS).
Reverse Blocking Protection
The optional reverse-blocking protection diode,
depicted in Figure1&2 provides protection from a
faulted or shorted input, or from a reversed-polarity
input source. Without the protection diode, a faulted of
shorted input would discharge the battery pack through
the body diode of the external pass transistor.
If a reverse-protection diode is incorporated in the
design, it should be chosen to handle the fast charge
current continuously at the maximum ambient
temperature. In addition, the reverse-leakage current of
the diode should be kept as small as possible.
14
EUP8051A
Packaging Information
8-Pin MSOP
NOTE
1. Package body sizes exclude mold flash and gate burrs
2. Dimension L is measured in gage plane
3. Tolerance 0.10mm unless otherwise specified
4. Controlling dimension is millimeter. Converted inch dimensions are not necessarily exact.
SYMBOLS
A
A1
A2
b
C
D
E
E1
e
L
y
θ
DS8051A Ver 1.1
Nov. 2006
DIMENSIONS IN MILLIMETERS
MIN.
NOM.
MAX.
0.81
0.95
1.10
0.05
0.09
0.15
0.76
0.86
0.97
0.28
0.30
0.38
0.13
0.15
0.23
2.90
3.00
3.10
4.70
4.90
5.10
2.90
3.00
3.10
-----0.65
----0.40
0.53
0.66
----------0.10
0
-----6
15
DIMENSIONS IN INCHES
MIN.
NOM.
MAX.
0.032
0.0375
0.043
0.002
0.004
0.006
0.030
0.034
0.038
0.011
0.012
0.015
0.005
0.006
0.009
0.114
0.118
0.122
0.185
0.193
0.201
0.114
0.118
0.122
-----0.026
-----0.016
0.021
0.026
----------0.004
0
-----6