MAXIM DS2710G

Rev 0; 4/08
Single-Cell NiMH Charger
The DS2710 is ideal for in-system charging of single-cell
nickel metal hydride (NiMH) cells for low-current
portable applications. Inputs to the DS2710 include USB
voltage sources and 5V regulated adapters.
Temperature, voltage, and charge time are monitored to
provide proper fast-charging control algorithms for
single-cell NiMH or nickel cadmium (NiCd) batteries.
The DS2710 includes battery tests to detect defective or
inappropriate cells such as alkaline primary batteries.
Applications
Small Rechargeable Devices
Features
♦ Charges Single-Cell NiMH Cells
♦ Switch-Mode Topologies Supported by Hysteretic
Control Technique
♦ Precharges Deeply Depleted Cells
♦ Fast-Charges NiMH with -ΔV Termination
Sensitivity of 2mV (typ)
♦ Monitors Voltage, Temperature, and Time for
Safety and Secondary Termination
♦ Regulates Charge Current
♦ Designed for External pMOS
Voice Recorders
Cordless Mouse
♦ Rail-to-Rail MOSFET Driver
Battery-Powered Toys
♦ Tiny 10-Pin TDFN Package (3mm x 4mm)
Ordering Information
PART
PIN-PACKAGE
DS2710G+
10 TDFN-EP*
DS2710G+T&R
10 TDFN-EP*
+Denotes a lead(Pb)-free/RoHS-compliant package.
T&R = Tape and reel.
*EP = Exposed pad.
Pin Configuration
Typical Operating Circuit
TOP VIEW
CHARGE
SOURCE
CS
VDD
VP1
DS2710
THM
VN0
NiMH
CELL
VSS
1
CS
2
VDD
3
THM
4
STATUS
5
+
DS2710
*EP
10
VP1
9
VN1
8
VN0
7
TMR
6
CTEST
VN1
TDFN
(3mm × 4mm)
SENSE
GROUND
*EXPOSED PAD.
________________________________________________________________ Maxim Integrated Products
For pricing, delivery, and ordering information, please contact Maxim Direct at 1-888-629-4642,
or visit Maxim’s website at www.maxim-ic.com.
1
DS2710
General Description
DS2710
Single-Cell NiMH Charger
ABSOLUTE MAXIMUM RATINGS
Voltage Range on All Pins Relative to VSS ............-0.3V to +6.0V
Continuous Source/Sink Current CS ...................................20mA
Continuous Source Current STATUS ..................................10mA
Operating Temperature Range ...........................-40°C to +85°C
Storage Temperature Range .............................-55°C to +125°C
Soldering Temperature...........................Refer to the IPC/JEDEC
J-STD-020 Specification.
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional
operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to
absolute maximum rating conditions for extended periods may affect device reliability.
RECOMMENDED DC OPERATING CONDITIONS
(4.0V ≤ VDD ≤ 5.5V, TA = -20°C to +70°C.)
PARAMETER
Supply Voltage
SYMBOL
VDD
Input Voltage Range
CONDITIONS
MIN
(Note 1)
CTEST, TMR, THM, VP1, VN1
TYP
MAX
UNITS
4.0
5.5
V
-0.3
VDD
V
DC ELECTRICAL CHARACTERISTICS
(4.0V ≤ VDD ≤ 5.5V, TA = -20°C to +70°C, unless otherwise noted.)
PARAMETER
Supply Current, VDD
SYMBOL
IDD
TYP
MAX
UNITS
Operating mode (Note 2)
CONDITIONS
250
1000
μA
3.5
3.9
V
UVLO Threshold
VUVLO
VDD rising (Note 1)
UVLO Hysteresis
VUHYS
VDD falling from above VUVLO
MIN
30
Output-Voltage Low, CS
VOL1
VDD = 5.0V, I OL = +20mA (Note 1)
Output-Voltage High, CS
VOH1
4.0
Output-Voltage Low, STATUS
VOL2
VDD = 5.0V, I OL = -20mA (Note 1)
VDD = 5.0V, I OL = +2mA (Notes 1, 3)
Output-Voltage High, STATUS
VOH2
VDD = 5.0V, I OH = -2mA (Notes 1, 3)
4.0
Threshold Voltage,
-V Termination
V-V
After tTHO (Note 4)
1.0
Current-Sense Reference
Voltage
VIREF
(Notes 1, 5)
Hysteresis, Current-Sense
Comparator
VHYSCOMP
Centered ~ 0.113V
Propagation Time, Current-Sense
Comparator to Driver Output
t PDLY
2mV overdrive/underdrive at trip threshold
(Notes 4, 6)
CS Pin Pullup Current
ICS
mV
1.0
V
0.50
2.0
3.0
125
VDD < VUVLO (Note 4)
V
V
-6
18
V
23
2
mV
mV
+6
%
27
mV
0.1
μs
10
μA
STATUS Pin Pulldown Current
I STAT
VDD < VUVLO (Note 4)
2
10
μA
Depleted Cell Voltage Threshold
VLOW
VP1 - VN1
0.9
1.0
1.1
V
VP1 - VN1, CS = high (Note 7)
1.55
1.65
1.75
V
VP1 - VN1, CS = low (Note 7)
1.64
1.75
1.86
V
98
100
102
mV
Overcharge Voltage Threshold
VMAXOPEN
Open Socket Voltage Threshold
VMAXCHARGE
Offset, VMAX-OPEN - VMAX-CHARGE
2
VOS
(Note 7)
_______________________________________________________________________________________
Single-Cell NiMH Charger
(4.0V ≤ VDD ≤ 5.5V, TA = -20°C to +70°C, unless otherwise noted.)
PARAMETER
SYMBOL
CONDITIONS
Cold Temperature Detect
Threshold
VTHM-MIN
(Notes 1, 5, 8)
Hot Temperature No-Start
Threshold
VTHM-MAX
(Notes 1, 5, 8)
Hot Temperature Safety
Shutdown Threshold
VTHM-STOP (Notes 1, 5, 8)
SUSPEND Current Threshold
I SUSPEND
Reverse-Leakage Current, VP1
Impedance-Voltage Test Range
TYP
MAX
0.73
0.30
0.33
(Note 9)
1.0
0.36
VDD
VDD
0.1
0.5
μA
10
15
μA
VDD = 0V, VP1 = 1.5V
VCTEST
UNITS
VDD
0.29
VDD 4.0V
Presence-Test Current, VP1
MIN
32
2
μA
400
mV
MAX
UNITS
ELECTRICAL CHARACTERISTICS: TIMING
(4.0V ≤ VDD ≤ 5.5V, TA = -20°C to +70°C, unless otherwise noted.)
PARAMETER
Internal Time-Base Period
SYMBOL
CONDITIONS
tBASE
TYP
0.96
Internal Time-Base Accuracy
CS Output Duty Factor
MIN
-10
DF1
FAST-CHARGE
DF2
PRECHARGE/TOP-OFF
25.0
DF3
MAINTENANCE
1.56
CELL TEST Interval
tCTST
PRECHARGE Timeout
t PCHG
Seconds
+10
%
96.9
VCELL < VLOW
%
31
Seconds
34
Minutes
4
Minutes
FAST-CHARGE Termination
Hold-Off Period
tTHO
FAST-CHARGE Flat Voltage
Timeout
tFLAT
VCELL not increasing
16
Minutes
Charge-Timer Period
tCTMR
RTMR = 40k
1.0
Hours
Charge-Timer Accuracy
Charge-Timer Range
Toggle Rate, Charging
Toggle Rate, FAULT State
Note 1:
Note 2:
Note 3:
Note 4:
Note 5:
Note 6:
Note 7:
Note 8:
Note 9:
RTMR = 40k
tCTMR-RANGE
-6
+6
%
0.5
5.0
Hours
fCHARGE
1
Hz
fFAULT
4
Hz
Voltages relative to VSS.
Specification does not include CS and STATUS pin currents.
STATUS pin is active high.
Specification is guaranteed by design.
Specification applicable during charge cycle with TA = 0°C to +70°C.
50mV overdrive while connected to a pMOS transistor (such as ZXM62P02 from Zetex).
VBAT-MAX1 and VBAT-MAX1 ranges never overlap.
VTHM-MIN, VTHM-MAX, and VTHM-STOP are fixed ratios of VDD. Their ranges never overlap.
Maximum allowable leakage on TMR to maintain SUSPEND state.
_______________________________________________________________________________________
3
DS2710
DC ELECTRICAL CHARACTERISTICS (continued)
Single-Cell NiMH Charger
DS2710
Pin Description
PIN
NAME
1
VSS
Device Ground. Connects directly to the negative terminal of the charge source.
FUNCTION
2
CS
Charge Source. Feedback control for switching circuitry.
3
VDD
Power-Supply Input. Connects to the positive terminal of the charge source through a decoupling
network.
4
THM
Thermistor Input. Connects to a thermistor located near the cell and a resistor-divider from the VDD pin.
5
STATUS
6
CTEST
7
TMR
Status Output. Drives an external LED or microprocessor input to indicate charge status.
Impedance Test. Connects to VSS through an external resistor to set the impedance-test threshold.
Fast-Charge Timer. Connects to V SS through an external resistor to set the fast-charge timeout period.
8
VN0
Current-Sense Negative Input. Connects to the charge source side of the external sense resistor.
9
VN1
Current-Sense Positive Input. Connects to the cell side of the external sense resistor.
10
VP1
Cell Voltage Sense. The voltage of the cell is monitored through this input pin.
—
EP
Exposed Pad. Connects to V SS.
VDD
BIAS
OSCILLATOR
3.5V
IPTST
WATCHDOG
UVLO
ABORT
STATE MACHINE
VP1
VOLTAGE
AND
TEMPERATURE
MEASUREMENT
PRESENSE TEST
VN1
THM
PRECHARGE
STATUS
FAST-CHARGE AND
CELL TESTS
STATUS
CTEST
TMR
CELL
TEST
TOP-OFF CHARGE
CHARGE
TIMER
MAINTENANCE CHARGE
0.1μA
VN0
DUTYFACTOR
CONTROL
VSS
CS
0.125V
SUSPEND
DS2710
Figure 1. Block Diagram
4
_______________________________________________________________________________________
Single-Cell NiMH Charger
Charge Algorithm Overview
The DS2710 controls switch-mode topology charging of
a single NiMH cell from a voltage-regulated charge
source. The IC is reset in one of two ways: with the
application of power to the DS2710 or after exiting
SUSPEND state. Once one of these conditions occurs,
the DS2710 enters the PRESENCE state and waits for a
cell to be inserted before starting a charge cycle.
Once a cell is detected, the DS2710 enters PRECHARGE
state and begins qualification to prevent fast charging
of deeply depleted cells or charging under extreme
temperature conditions. Precharging is performed at a
reduced rate until the cell reaches 1V. The algorithm
then proceeds to the FAST-CHARGE state, which
includes cell tests to avoid accidental charging of alkaline cells or NiMH cells that are worn out or damaged.
Fast charging continues as long as all the cell qualification criteria are met. Fast charging terminates by the
-ΔV (negative delta voltage) method. The TOP-OFF
charge phase follows to completely charge the cell.
After the TOP-OFF charge timer expires, the DS2710
enters the MAINTENANCE state to indefinitely keep the
cell at a full state of charge. Maximum voltage, temperature, and charge-time monitoring during all charge
phases act as secondary or safety termination methods
to provide additional protection from overcharge. Any
error condition occurring during charge forces the
DS2710 into the FAULT state and charging terminates.
Charging can be halted at any time by floating the TMR
pin, which forces the DS2710 into SUSPEND state.
Once a charge is complete either normally or by
FAULT, the DS2710 remains in the final state (MAINTENANCE or FAULT) until the cell is removed, the IC is
power cycled, or the IC is forced into SUSPEND state.
Afterwards, the DS2710 returns to PRESENCE state
and the charge cycle begins again.
An internal oscillator provides the main clock source
used to generate timing signals for chip operation. The
PRECHARGE timer, hold-off timers, and timing for CS
operation and cell testing are derived from this time
base. If the internal clock should ever fail, a watchdogdetection circuit halts charging. The watchdog-safety
circuit and charge timer set by the TMR pin are derived
from oscillators other than the main clock source. Figure
1 is the DS2710 block diagram and Figure 2 is the state
diagram.
POWER-ON RESET (POR)
The UVLO circuit serves as a power-up and brownout
detector by monitoring VDD to prevent charging until
V DD rises above V UVLO, or when V DD drops below
V UVLO - V UHYS . If undervoltage lockout is active,
charging is prevented, the state machine is forced to
the POR state, and all charge timers are reset.
PRESENCE
The DS2710 enters the PRESENCE state whenever the
TMR pin is not floating and VDD > VUVLO, indicating
that the charge source is present. The DS2710 remains
in the PRESENCE state until a cell is inserted into the
circuit, causing the voltage of VP1 - VN1 to fall below
1.65V (VMAX-OPEN) and the cell temperature is inside a
valid charging range between 0°C and +45°C
(TTHM-MIN and TTHM-MAX when used with recommended thermistor and resistor values). If both these conditions are met, the DS2710 enters PRECHARGE. If a cell
is inserted but the temperature is outside the valid
charging range, the DS2710 remains in the PRESENCE
state until the cell temperature falls within the valid
charging range.
PRECHARGE
The DS2710 enters the PRECHARGE state when a valid
cell voltage is detected and the cell temperature as
measured by the DS2710 thermistor circuit is within the
valid charging range. The DS2710 precharges the cell
by regulating the voltage drop across the sense resistor to 113mV with a 25% duty cycle. The STATUS output toggles at 1Hz to indicate the cell is being
precharged. Precharging lasts until the measured cell
voltage exceeds 1.0V (V LOW ), at which time the
DS2710 enters the FAST-CHARGE state. If the cell voltage does not exceed VLOW within 30min (tPCHG) or if
the cell temperature exceeds +50°C (TTHM-STOP) at
any time during PRECHARGE, the DS2710 enters the
FAULT state. If at any time during PRECHARGE the cell
voltage exceeds 1.75V (VMAX-CHARGE), the DS2710
determines that the cell has been removed and enters
the FAULT state.
FAST-CHARGE
In the FAST-CHARGE state, the DS2710 regulates the
average voltage across the sense resistor to 113mV.
The STATUS output is held high to indicate the cell
pack is being charged. During FAST-CHARGE, the
DS2710 performs a cell test every 31s. The CELL TEST
state is responsible for determining when charge is
complete. As secondary overcharge protection, the
DS2710 terminates FAST-CHARGE and enters TOPOFF based on a time delay set by the external resistor
on the TMR pin. This resistor value can set the secondary charge termination delay to anywhere from
30min up to 5hr. If the cell temperature exceeds +50°C
at any time during FAST-CHARGE, the DS2710 enters
_______________________________________________________________________________________
5
DS2710
Detailed Description
DS2710
Single-Cell NiMH Charger
RTMR > RSUSPEND
(ASYNCHRONOUSLY FROM ANYWHERE)
SUSPEND
RTMR < RSUSPEND
CS = INACTIVE
STATUS = LOW
VDD < VUVLO - VUHYS
(ASYNCHRONOUSLY FROM ANYWHERE)
PRESENCE
VDD > VUVLO (3.5V)
POR
CS = INACTIVE
STATUS = LOW
CS = INACTIVE
PRECHARGE
t < tPCHG
AND
VCELL < 1.0V
VCELL < VMAX-OPEN
CS = ACTIVE 25% DF
STATUS = 1Hz TOGGLE
t > tPCHG
OR
T > +50°C
OR
VCELL > VMAX*
VCELL > 1.0V
AND
t < tPCHG
AND
T < +50°C
VCELL > 1.75V
OR
T < 0°C
OR
T > +45°C
VCELL > 1.75V
FAULT
CS = INACTIVE
STATUS = 4Hz TOGGLE
CELL TEST
CS = INACTIVE
STATUS = HIGH
FAIL: VCELL > VMAX-OPEN
OR ΔV > CTEST
PASS
31s INTERVAL
VCELL > VMAX*
FAST-CHARGE
t < FAST TIMEOUT
t > FAST TIMEOUT
TOP-OFF
t < TOP-OFF TIMEOUT
VCELL > VMAX*
CS = ACTIVE
STATUS = HIGH
CS = ACTIVE 25% DF
STATUS = HIGH
-ΔV DETECT
OR
FLAT VOLTAGE DETECT
T > +50°C
OR
t > TOP-OFF TIMEOUT
T > +50°C
MAINTENANCE
CS = ACTIVE 1.56% DF
STATUS = LOW
*VMAX REPRESENTS VMAX-CHARGE WHEN THE CS OUTPUT IS ACTIVE AND VMAX-OPEN WHEN THE CS OUTPUT IS INACTIVE.
Figure 2. State Diagram
6
_______________________________________________________________________________________
Single-Cell NiMH Charger
the cell voltage is greater than VMAX-CHARGE during
the 25% of time when charge current is applied or
VMAX-OPEN during the remaining time, TOP-OFF is exited early and the DS2710 goes to FAULT.
CELL TEST
MAINTENANCE
CELL TEST is performed once every 31s during FASTCHARGE to determine if charging is complete. During
CELL TEST, the CS output is held high to prevent
charging. The cell’s voltage is measured and compared against prior readings. The maximum cell voltage measurement during the charge is retained. If a
cell’s voltage falls more than 2mV (V-ΔV) from its peak
reading, the FAST-CHARGE terminates successfully
and moves to TOP-OFF. The DS2710 also moves to
TOP-OFF if the cell’s voltage reading does not exceed
the maximum over a 16min period (tFLAT). A hold-off
period for -ΔV and flat voltage detection begins at the
start of fast charging and prevents false termination in
the first 4min of the charge cycle (tTHO).
The impedance of the cell is also measured during
CELL TEST. The cell’s open-circuit voltage is compared
against the voltage of the cell under charge. The difference is compared against the impedance threshold set
by the CTEST pin. If the difference exceeds the threshold set by CTEST, the cell’s impedance is considered
to be too high for charging and the DS2710 enters the
FAULT state. The DS2710 also enters FAULT state if
any voltage reading in CELL TEST exceeds the
VMAX-OPEN threshold.
The DS2710 enters the MAINTENANCE state whenever
the charge completes normally or if the measured cell
temperature exceeds +50°C during the charge. The
STATUS pin is driven low to indicate TOP-OFF has
completed. The cell’s state of charge is maintained
indefinitely by continuing a 1.56% duty-cycle charge of
the cell. The DS2710 remains in the MAINTENANCE
state until the cell is removed, the DS2710 is power
cycled, or the DS2710 is forced into SUSPEND state.
FAULT
TOP-OFF
The DS2710 can enter FAULT from any charge state if
the cell voltage exceeds VMAX-CHARGE any time when
charge current is applied (CS low) or VMAX-OPEN at any
time when no charge current is flowing (CS high). In
addition, FAULT can be entered during PRECHARGE if
the cell’s temperature exceeds +50°C or the
PRECHARGE timer expires, or during FAST-CHARGE if
impedance threshold is exceeded. In the FAULT state,
CS is forced high to prevent charging and the STATUS
output toggles at a 4Hz rate to indicate that an error
has occurred. The DS2710 remains in FAULT until a
cell voltage greater than 1.75V (V MAX-CHARGE ) is
detected, indicating that the cell has been removed.
The DS2710 then enters the PRESENCE state and waits
for the next cell insertion.
In the TOP-OFF state, the DS2710 charges at 25% the
rate of FAST-CHARGE. The voltage across the sense
resistor is regulated to 113mV with a 25% duty cycle.
The STATUS output is held high to indicate the cell
pack is being charged. The charge timer is reset and
restarted with a timeout period of one-half the
FAST-CHARGE duration. When the charge timer
expires or if the measured temperature exceeds
+50°C, the charger enters the MAINTENANCE state. If
Suspension of charge activity is possible by floating the
TMR pin (RTMR > RSUSPEND). The CS output is pulled
to VDD to disable the charge control FET to prevent current flow to the cell. When the TMR connection is
restored, charging begins from the PRESENCE state
with all timers reset. The SUSPEND state is useful as a
means to stop charging by the application circuit, such
as with a microcontroller signal.
SUSPEND
_______________________________________________________________________________________
7
DS2710
the MAINTENANCE state. If at any time during FASTCHARGE the cell voltage exceeds VMAX-CHARGE, the
DS2710 determines that the cell is either overcharged
or has been removed, and enters the FAULT state.
Charge-Current Regulation
The DS2710 regulates charge current by maintaining a
constant average voltage across an external sense
resistor connected between the VN1 and VN0 pins.
VN1 and VN0 drive an internal comparator in the
DS2710 to switch the CS output ON and OFF to drive a
regulating pnp bipolar or a pMOS transistor. Hysteresis
on the comparator input provides noise rejection. The
DS2710 regulates the charge current during FASTCHARGE to maintain a voltage drop across the sense
resistor as follows:
VSENSE = VIREF - 0.5 x VHYS-COMP = 0.113V (typ)
Figure 3 shows the sense resistor voltage and CS pin
voltage of the regulating circuit during normal operation.
Charging with Load Applied
NiMH cells have a low, but finite, impedance. If load
current is flowing out of the battery, an internal voltage
drop appears at the battery terminals. This can interfere
with the CTEST and -ΔV detection. If the load current is
variable, early termination is more likely than if the load
current is constant. If the load’s ground is connected to
the negative terminal of the cell (VN0), load current
flows through the current-sense resistor, resulting in less
charge current to the battery. The load-current return
path should be to charger ground to reduce the likelihood of false termination or impedance-test errors.
Charging with load applied is not recommended.
Temperature Monitoring
Accurate temperature sensing is needed to detect temperature FAULT conditions. Connecting an external
10kΩ NTC thermistor between THM and V SS and a
10kΩ bias resistor between VDD and THM allows the
DS2710 to sense temperature. To accurately monitor
the cell, the thermistor should make physical contact
either to the cell or cell tabs. Table 1 shows several recommended 10kΩ thermistors.
MIN, MAX Temperature Compare
The voltage thresholds of the THM input (VTHM-MIN,
VTHM-MAX) are set to allow charging to start if the thermistor temperature is between 0°C and +45°C when
using the recommended 10kΩ bias resistor and 10kΩ
thermistor circuit. If precharging is in progress and the
voltage on THM reaches V THM-STOP , precharging
stops and a FAULT condition is generated. If the voltage on THM reaches V THM-STOP during FASTCHARGE or TOP-OFF, charging stops and the DS2710
enters the MAINTENANCE state. FAST-CHARGE and
Table 1. THM Thresholds
THM THRESHOLD
RATIO OF VCBIAS
THERMISTOR
RESISTANCE
(k)
MIN
MAX
STOP
0.73
0.33
0.29
27.04
4.925
4.085
TEMPERATURE (°C)
Semitec 103AT-2
Fenwal
197-103LAG-A01,
173-103LAF-301
0
+45
+50
+4
+42
+47
NOT DRAWN TO SCALE
DIVIDER OUTPUT
VOH1
VCS
VOL1
VIREF
VSENSE
VSENSE (DC)
VIREF - VHYS-COMP
TIME
Figure 3. Ideal Comparator Input and Charge Control Output
Waveforms
8
VOLTAGE RATIO
DS2710
Single-Cell NiMH Charger
0.75
0.70
0.65
0.60
0.55
0.50
0.45
0.40
0.35
0.30
0
10
20
30
40
TEMPERATURE (°C)
Figure 4. Ratio of THM Pin to VDD Pin Over Temperature
_______________________________________________________________________________________
50
Single-Cell NiMH Charger
Used with a 10kΩ resistor, the Semitec 103AT-2 provides approximately 0.9% full scale-per-degree sensitivity. Figure 4 shows this linearity curve. The left axis is
the ratio of the sensed voltage to the divider’s input
voltage (VDD).
Charge-Status Output
The DS2710 indicates the state of charge and the
charge results on the STATUS output pin. When no cell
is present, the output is driven to a logic-low. Any LED
attached to the STATUS pin is off. When a cell is inserted, STATUS oscillates in a 1Hz, 50% duty-cycle pattern
to indicate the cell is precharging. Once the DS2710
transitions to FAST-CHARGE, the STATUS output goes
to logic-high and stays high until the end of TOP-OFF.
STATUS returns to logic-low for MAINTENANCE charge
and remains at logic-low until the cell is removed or the
DS2710 is power cycled. If a FAULT occurs during
charging, STATUS toggles at a fast 4Hz, 50% dutycycle rate until the cell is removed. Table 2 summarizes
the STATUS output and LED operation for each charge
condition.
Charge-Rate Selection
The charge rate is determined by an external sense
resistor connected between the VN1 and VN0 pins. The
DS2710 regulates the charge current to maintain a voltage drop of VIREF - 0.5 x VHYS-COMP across the sense
resistor during FAST-CHARGE:
VSENSE = VIREF - 0.5 x VHYS-COMP = 0.113V (typ)
The sense resistor can therefore be selected by:
RSENSE = 0.113V/Desired FAST-CHARGE Current
The effective FAST-CHARGE rate is equal to 0.969 times
the regulated current limit, TOP-OFF rate is 0.25 times
the regulated current, and MAINTENANCE charge rate
is 0.0156 times the regulated current. Table 3 shows
the charge rates for charging three different cell capacities using a 565mA (0.200Ω sense) current source and
a 1130mA (0.100Ω sense) current source.
Table 2. LED Display Patterns Based on Charge State
CHARGE STATE
NO BATTERY
PRECHARGE
FAST-CHARGE/
TOP-OFF
MAINTENANCE
FAULT
STATUS PIN
Logic-low
Oscillates at 1Hz,
50% duty cycle
Logic-high
Logic-low
Oscillates at 4Hz,
50% duty cycle
STATUS PIN LED
Off
1Hz toggle
On
Off
4Hz toggle
Table 3. Charge-Rate Examples
565mA CHARGE RATE (0.200)
AT CELL CAPACITY
STATE
900mAH
1700mAH
2200mAH
FAST-CHARGE
C/1.64
C/3.10
PRECHARGE/TOP-OFF
C/6.37
C/12.0
MAINTENANCE
C/102
C/193
C/249
1130mA CHARGE RATE (0.100)
AT CELL CAPACITY
900mAH
1700mAH
2200mAH
C/4.00
C/0.82
C/1.55
C/2.0
C/15.5
C/3.19
C/6.0
C/7.75
C/51
C/96
C/125
_______________________________________________________________________________________
9
DS2710
TOP-OFF complete normally if the cell temperature
remains below this threshold.
DS2710
Single-Cell NiMH Charger
Timeout Selection
Application Circuit
FAST-CHARGE state normally operates until -ΔV termination. In the event that termination does not occur correctly, a safety timeout is required. This timeout is set
by an external resistor on the TMR pin to VSS and provides secondary protection against significant overcharging. The value of the TMR resistor should be
chosen so that the timeout is greater than the FASTCHARGE time expected in the application, but not so
much greater that its protection is compromised. If the
timer expires during FAST-CHARGE, the timer count is
reset and charging proceeds to the TOP-OFF charge
state. The TMR resistor also sets the timed charge
duration of TOP-OFF state. The TOP-OFF timeout period is fixed at half the FAST-CHARGE timeout period.
When the timer expires in TOP-OFF, the DS2710 enters
the MAINTENANCE state.
Resistors can be selected to support FAST-CHARGE
timeout periods of 0.5hr to 5hr and TOP-OFF timeout
periods of 0.25hr to 2.5hr. The programmed FASTCHARGE time approximately follows the equation:
Figure 5 shows a typical DS2710 application circuit for
charging a NiMH cell from a USB port or other 5V
charge source capable of supplying 0.5A. Q1, L1, C2,
and D2 form a switching buck-regulator circuit controlled by the CS pin of the DS2710. Current is regulated through the current-sense resistor, R9, by switching
Q1 on and off as the sense resistor voltage ramps up
and down toward the preset sense voltage thresholds.
The 0.100Ω sense resistor along with the DC groundreferenced sense threshold level of VIREF - 1/2 VHYSCOMP sets the average charge current in the example
to 1.13A. The sense resistor should have a proper
power rating for the chosen charge current.
The TMR resistor is set to 100kΩ for a timeout of 2.5hr.
This is appropriate for cells with a capacity of approximately 2200mAh when charged with the 1.13A charge
current. The CTEST resistor is set to 47kΩ for an impedance-test threshold of approximately 0.150Ω when
charging at 1.13A. Additionally, R6 protects the VP1 pin
from any stress applied to the exposed tabs of a loose
NiMH cell; R3 creates a weak pullup to offset the leakage through D2, which might otherwise cause a false
cell detection; and R1/C1 creates a bypass filter on the
VDD pin of the IC.
The value of L1 in Figure 5 represents a moderate
switching speed of ~ 200kHz for FAST-CHARGE state.
L1 can be adjusted to fit specific application goals as
long as the associated change in switching speed
does not exceed the circuit’s ability to maintain proper
regulation of the sense-resistor voltage. All capacitors
should be ceramic surface-mount types of good quality
where possible. The 10µF capacitor can be of any type
that meets the application requirements. All resistors
not previously mentioned are standard surface-mount
types.
t(minutes) = 1.5 x RTMR(Ω)/1000
Impedance-Test Threshold
Selection
The DS2710 tests the cell impedance every 31s while
in FAST-CHARGE state. Impedance is measured by
comparing the cell voltage during normal charging to
the cell voltage with no charge current (CS output held
high). The resulting voltage difference is compared
against the threshold set by an external resistor from
CTEST to VSS. The detection threshold can be set from
32mV to 400mV. The following formula approximates
the setting for the detection threshold:
VTEST = 8000/RCTEST (Value in Volts)
Since the charge rate is controlled by the external
sense resistor (RSENSE) between VN1 and VN0, the test
threshold can be expressed as impedance as follows:
Impedance Threshold =
( 8000/RCTEST )/( 0.113/RSENSE ) =
70796 x ( RSENSE/RCTEST )
For example, an application charging at 1.13A (RSENSE
= 0.100Ω) would use a 47kΩ resistor on the CTEST pin
to set the impedance threshold to 0.150Ω.
10
Application PCB Layout
Proper layout rules must be followed to ensure a successful application circuit. For all modes of operation,
currents in excess of 1A can flow through the charge
and discharge paths (USB charging is specification limited to 500mA). All these paths should be properly sized
to handle the worst-case current flow, whether from
charging or from powering the load with the battery.
Switch-mode operation presents challenges with fast
voltage and current transients. Proper switch-mode
buck power-supply layout should always be observed.
______________________________________________________________________________________
Single-Cell NiMH Charger
DS2710
R3
270kΩ
Q1
ZXM62P02E6
+5V
(USB+)
R1
150Ω
L1
15μH
SISCDRH74M-150R
C2
10μF
CERAMIC
C3
10μF
CERAMIC
D2
1W B340A-13
SCHOTTKY
R6
1kΩ
CS
VP1
VDD
1S
NiMH
CELL
R4
10kΩ
THM
C1
1μF
VN1
DS2710
R9
0.1Ω
1W
STATUS
RT1
103AT-2
GROUND
(USB-)
VN0
TMR
R2
1kΩ
D1
GREEN
SMA
CTEST
R7
100kΩ
VSS
R8
47kΩ
Figure 5. Typical Application Circuit for USB Port Charging
Referring to the example circuit and layout of Figure 6,
the loop labeled as Loop1 encompassing C IN ,
QSWITCH, and DSWITCH should be kept as small as
possible to minimize the change in loop area that
occurs when switching from the OFF to the ON state
and vice versa. Loop2 should also be minimized as
much as practical, although it contains DC current
components for the most part. The returning ground
currents should be allowed to follow a path on a layer
directly under the outgoing path since the high-frequency components try to follow the path of least
impedance. Low ESR and ESL capacitors should be
used when possible and for all capacitors 10µF and
smaller. Typical surface-mount ceramic types with an
X5R or better dielectric are recommended.
Another important layout detail is the connection of the
sense resistor. Proper Kelvin connection layout should
be used to ensure the signal quality viewed by the
sensing circuit inside the DS2710 is adequate. Figure 7
shows a recommended connection of the sense lines to
the resistor footprint.
Package Information
For the latest package outline information and land patterns, go
to www.maxim-ic.com/packages.
PACKAGE TYPE
PACKAGE CODE
DOCUMENT NO.
10 TDFN-EP
T1034+1
21-0268
______________________________________________________________________________________
11
DS2710
Single-Cell NiMH Charger
CONTROL
RGATE
LSWITCH
QSWITCH
CHARGE SOURCE SIDE
LOOP1
CIN
DSWITCH
LOOP2
COUT
BATTERY SIDE
LOOP AREAS MINIMIZED
CHARGE SOURCE SIDE
CI
RG
DS
QS
BATTERY SIDE
CO
LS
BACKSIDE
GROUND PLANE
CONTROL
Figure 6. Switching Circuit with Example Layout
SENSE+
SENSE-
SENSE+
SENSE-
SENSE TRACES RUN CLOSE
TOGETHER TO MINIMIZE LOOP
INDUCTANCE
PROPER KELVIN CONNECTION
AT SENSE RESISTOR
RSNS
CHARGE SOURCE-
BATTERY-
CHARGE SOURCE-
RSNS
BATTERY-
Figure 7. Sense Resistor Connection Layout
Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are
implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.
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