FAIRCHILD AN-9720

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AN-9720
Power Path Implementation Tradeoffs, Featuring the
FAN5400 Family of PWM Battery Chargers
Overview
Many battery-powered systems, such as smart phones, must be
fully functional and their electronics up and running shortly
after the user plugs a charger into the phone. The system
electronics need to be functional regardless of the state of the
battery, even if the battery is fully discharged or absent. The
FAN5400 family charger IC allows power to be delivered to
the system when the charger is plugged in, whether the battery
is absent or present, and allows the system to power up and be
functional quickly after the charger is plugged in. Other
approaches, such as power path, add additional impedance in
series with the battery.
This application note describes how the FAN5400 family of
battery chargers distributes power between the system and
battery to achieve similar results of power path, often without
the overhead and power loss of an additional switch element.
While this implementation meets the criteria for power path,
an ideal diode is never truly ideal. For example, the internal
ideal diode of one such IC is actually a PMOS with a typical
value of 180mΩ. This means that there is a permanent 180mΩ
power dissipating series element between battery and system
load that creates significant additional power loss during
periods of high-current drain from the battery, such as GSM
pulses. A parallel diode PMOS switch can reduce this
resistance; however, this increases the solution size and cost.
The implementation in Figure 1 differs from the FAN540X
approach in the block diagram in Figure 2. Although on the
surface it may seem like FAN5400 does not have power path
functionality; it serves almost all the same needs and, in
addition, can provide the benefit of having no power
dissipating series element between system load and battery.
Q1
The block diagram in Figure 1 is a typical implementation of
power path using an “ideal” diode. Current flow is indicated
by the arrows, which reveal that the “ideal” diode (whether
internal or external) helps to steer current appropriately.
Figure 1. Typical Implementation of Power Path using an “Ideal” Diode
© 2010 Fairchild Semiconductor Corporation
Rev. 1.0.0 • 12/23/10
www.fairchildsemi.com
AN-9720
APPLICATION NOTE
VREG
1.8V / PMID REG
CREG
PMID
1 F
PMID
Q3
VBUS
CMID
Q1
CHARGE
PUMP
CBUS
1 F
4.7 F
Q2
Q1A
VBUS
OVP
PWM
MODULATOR
I_IN
CONTROL
RSENSE
COUT
PGND 0.1 F
ISNS
VCC
DAC
Q1B
L1 1 H
SW
POWER
OUTPUT
STAGE
+
CSIN
VREF
Battery
VBAT
SDA
SCL
DISABLE
OTG/USB#
PMID
I2C
INTERFACE
30mA
CBAT
SYSTEM
LOAD
STAT
OSC
LOGIC
AND
CONTROL
Figure 2. FAN5400 Block Diagram
Example 1: 1500mAh Battery (1C Maximum Charge
Current Capability of Battery is 1500mA), Input
Power Source USB 2.0, 5V 500mA
System and Battery Power Sharing
Power sharing between the system and the battery means that
power can be steered or prioritized to go to the system in the
case that the input power is not sufficient to power both the
system and charge the battery.
Scenario A)
Partially charged battery at 3.6V and
system load turns on at 400mA
Before the system load turns on, the charger is already in CC
mode. Because the input power source is 5V 500mA and the
battery is at 3.6V, there is ~632mA of current available to
charge the battery. This is computed by accounting for the
charger conversion efficiency and also the output current
multiplication factor achieved when bucking down a voltage:
The typical configuration for the FAN5400, as shown in
Figure 3, is one where the system is connected in parallel to
the battery. The way in which this configuration can steer
power similar to power path is sometimes confusing, so
scenarios based on real-world battery capacity and input
power numbers are provided below.
I OUTMAX = VIN / VOUT ∗ I IN ∗ Efficiency
(1)
Using the values in this example reveals that
5V/3.6V•500mA•91%=632mA. The 91% efficiency data
point can be found in Figure 4.
94%
Efficiency
92%
Figure 3. Typical Application Circuit, System Parallel
with Battery
90%
88%
86%
4.5VBUS
5.0VBUS
5.5VBUS
84%
2.5
2.7
2.9
3.1
3.3
3.5
3.7
3.9
4.1
4.3
Battery Voltage, VBAT (V)
Figure 4.
FAN5400 Conversion Efficiency vs.
Battery Voltage vs. VBUS Voltage
© 2010 Fairchild Semiconductor Corporation
Rev. 1.0.0 • 12/23/10
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AN-9720
APPLICATION NOTE
Once the system load turns on, 400mA is diverted to the
system and only 232mA is left to charge the battery. This is
the equivalent of power steering; the charger is prioritizing the
system over the battery. Once the system load turns off, the
full 632mA once again flows to the battery. The benefit of
FAN5400, as configured in Figure 3, is that there is no powerdissipating series element between the system and load.
Scenario D)
Battery is fully charged at 4.2V and system
load turns on at 2000mA
Before the system load turns on, the charger is off. When the
system load turns on, the power first comes from the battery
and almost immediately the battery charger turns on and goes
into CC Mode. This is because Li-Ion batteries typically have
an output impedance of 150mΩ, which almost instantly forces
VBAT < VOREG - VRCH. Similar to Scenario C, the charger
attempts to charge the battery at 575mA. (Actually slightly
higher than 575mA because battery voltage is lower in this
case, as compared to Scenario C, and the multiplication factor
is slightly higher. For the sake of this exercise, it is
inconsequential.) The charger attempts to charge; however,
because the system load is 2000mA, the 575mA flows to the
load and the remaining system load of 1425mA comes from
the battery.
Scenario B)
Partially charged battery at 3.6V and
system load turns on at 2000mA
Before the system load turns on, the charger is already in CC
mode and using all input power to charge the battery at
632mA, similar to Scenario A. When the system load turns on,
632mA is diverted to the system and the remaining system
load of 1368mA comes from the battery.
This is the equivalent of power steering; the charger is
prioritizing the system over the battery. Once the system load
turns off, the full 632mA once again flows to the battery.
Again, the circuit in Figure 3 has an advantage of no
dissipating element between the system and load.
This is the equivalent of power steering; the charger is
prioritizing the system over the battery. Once the system load
turns off, the full 575mA flows to the battery until the battery
enters CV Mode, at which point, the charge current decreases.
Again, the circuit in Figure 3 has an advantage of no
dissipating element between system and load.
Scenario C)
Battery is fully charged at 4.2V and system
load turns on at 400mA
Example 2: Assume a 700mAh Battery (1C
Maximum Charge Current Capability of Battery
700mA), Input Power Source AC/DC Adaptor 5V
900mA or USB 3.0, 5V, 900mA
Before the system load turns on, the charger is off. When the
load turns on, all the system power first comes from the
battery. As soon as VBAT < VOREG - VRCH, the charger turns on.
VRCH is the recharge threshold and has a value of 120mV.
Because the input power source is 5V 500mA, the maximum
available current the charger can provide is computed as
5V/4V•500mA•92%=575mA (battery is assumed to have to
4V for the sake of this exercise). The charger turns on,
attempting to charge the battery at 575mA. However, because
the system load is still present, only 575mA-400mA=175mA
is flowing into the battery.
Scenario A)
Partially charged battery at 3.6V and
system load turns on at 400mA
Before the system load turns on, the charger is in CC Mode.
Because the battery is at 3.6V, there is 5V/3.6V•900mA•91%
=1138mA of current available to charge the battery. However,
the battery is limited to a maximum 1C charge current of
700mA and, therefore, the charger is set to charge at 700mA.
What is unique in Example 2, in comparison to Example 1, is
that the input power supply can supply more power than the
battery is able to accept in 1C scenario. When the system load
turns on, 400mA is diverted to the system and only 300mA is
left to charge the battery.
This is the equivalent of power steering; the charger is
prioritizing the system over the battery. Once the system load
turns off, the full 575mA flows to the battery until the battery
enters CV Mode; at which point, the charge current decreases.
Again, the circuit in Figure 3 has an advantage of no
dissipating element between system and load.
Some designers might object because the input power supply
is not being used to the full extent that the combination of the
battery and system load can accept. One solution is to connect
the system load to CSIN, as shown in Figure 5.
Figure 5. Application Circuit with System Load Connected to CSIN
© 2010 Fairchild Semiconductor Corporation
Rev. 1.0.0 • 12/23/10
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AN-9720
APPLICATION NOTE
Connecting the system load to CSIN allows the AC/DC
adaptor or USB source to supply current up to maximum
power level even if that is higher than the battery’s 1C level.
In this configuration, before the load turns on, the battery is
charging at its 1C maximum charge capability of 700mA.
When the 400mA system load turns on, the entire 400mA
system load is supplied by the charger and the battery
continues to charge at 700mA.
Scenario D)
Battery is fully charged at 4.2V and system
load turns on at 2000mA
Before the system load turns on, the charger is off. When the
system load turns on; if the configuration from Figure 3 is
used, the power comes first from the battery and almost
immediately the battery charger turns on and goes into CC
Mode. This is because Li-Ion batteries typically have an
output impedance of 150mΩ, which almost instantly forces
VBAT < VOREG - VRCH. Similar to Scenario C, the charger
attempts to charge the battery at 700mA. However, because
the system load is 2000mA, the 700mA flows from the
charger to the system load and the remaining system load of
1300mA comes from the battery.
One drawback to this configuration is that there is a power
dissipating 68mΩ series element always in the path between
the battery and the system load. This constant power
dissipating element between battery and system load is similar
to the one found in the power path implementation in Figure 1.
However, the 68mΩ in FAN5400 is substantially less than the
180mΩ found in some products with power path.
If the configuration in Figure 5 is used; when the load turns
on, 1035mA flows from the charger to the load and the
remaining 965mA is supplied by the battery. Once the system
load turns off, 700mA flows to the battery until the battery
enters CV Mode; at which point, the charge current begins to
decrease. Again, the tradeoff is the 68Ω-series element
between the battery and system load.
Scenario B)
Partially charged battery at 3.6V and
system load turns on at 2000mA
Before the system load turns on, the charger is in CC Mode
and charging the battery at 700mA, similar to Scenario A.
When the system load turns on, if the configuration from
Figure 3 is used, 700mA is supplied to the system load from
the charger and the remaining 1300mA by the battery.
Charge Termination when System Load is
Connected to CSIN
If the configuration from Figure 5 is used instead, 1138mA is
supplied to the system load from the charger and the
remaining 862mA is supplied by the battery.
When the system load is connected to CSIN as it is in Figure
5; if the system load is larger than the power that can be
supplied from the USB port with the IBUS limit (e.g.
500mA), the battery current is reduced below the
termination threshold. Normally, when the battery current is
reduced below the termination threshold, charge is
terminated. However, if the charger input is in current limit,
the FAN540X does not allow charge termination. Charge
termination occurs only if IBAT is less than ITERM and the
charger input is not in current limit for at least 32ms. This
prevents false termination from system loading.
Both configurations are the equivalent of power steering; but
in the configuration of Figure 5, all the input power is being
used. The tradeoff is the 68mΩ-series element between battery
and system load. Once the system load turns off, 700mA flows
to the battery in both configurations.
Scenario C)
Battery is fully charged at 4.2V and system
load turns on at 400mA
Before the system load turns on, the charger is off. When the
load turns on, the system power first comes from the battery.
As soon as VBAT < VOREG - VRCH, the charger turns on. VRCH is
the recharge threshold and has a value of 120mV. Because the
input power source is 5V 900mA, the maximum available
current the charger can provide is 5V/4V•900mA•92%
=1035mA (assume the battery has dropped to 4V for the sake
of this exercise). The charger turns on, attempting to charge
the battery at 700mA. However, because the system load is
still present, if the configuration in Figure 3 is used; only
300mA is left to charge the battery.
After charge termination occurs, the charger stops running and
system power is drawn from the battery. Charge termination
can be disabled by disabling the TE bit through I2C. Charge
termination may, however, be desired if the phone or data card
is in a low-power mode and a drain on the USB port is not
desired. In that case, recharge occurs automatically when the
battery voltage drops VRCH (120mV) below VOREG or if it is
desired to turn on before 120mV, the system can manually
turn on the charger as soon a drop in VBAT is sensed.
If the configuration in Figure 5 is used; when the load turns
on, 635mA flows to the battery and 400mA is supplied from
the charger to the system load. This makes sense because there
is a total of 1035mA charger output current. Once the system
load turns off, the full 700mA flows to the battery until the
battery enters CV Mode; at which point, the charge current
decreases. The tradeoff is the 68mΩ-series element between
the battery and system load.
The FAN5402 and FAN5405 continues charging after VBUS
POR with the default parameters, regulating the VBAT line to
3.54V until the host processor issues commands or the 15minute timer expires. In this way, the FAN5402/05 can start
the system without a battery.
The FAN5400 family’s soft-start function can interfere with
the system supply with battery absent. The soft-start activates
© 2010 Fairchild Semiconductor Corporation
Rev. 1.0.0 • 12/23/10
Powering the System with No Battery
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AN-9720
APPLICATION NOTE
To understand how quickly the battery voltage rises, it is
necessary to examine the internal operation of the battery
pack. Inside every battery pack is a protection IC, as shown in
Figure 6, that features two back-to-back MOSFETs and an
analog control circuit to prevent over-charging and overdischarging by monitoring the cell voltage and discharge
current. The protection circuit is also referred to as “secondary
protection” since the charging system must also ensure that the
battery is not over-charged. The protection circuit provides a
back-up safety circuit where overcharging is concerned.
whenever VOREG, IINLIM, or IOCHARGE are set from a lower to
higher value. During soft-start, the IIN limit drops to 100mA
for about 1ms, unless IINLIM is set to 11 (“no limit”). This
could cause the system processor to fail to start. To avoid this
behavior, use the following sequence.
1. Set the OTG pin HIGH. When VBUS is plugged in,
IINLIM is set to 500mA until the system processor powers
up and can set parameters through I2C.
2. Program the Safety Register
3. Set IINLIM to 11 (no limit).
4. Set OREG to the desired value (typically 4.18)
5. Reset IOLEVEL bit, then set IOCHARGE.
6. Set IINLIM to 500mA if a USB source is connected or any
other level that is preferred.
CELL
ESR
PROTECTION
CIRCUIT
Q1
Q2
+
+
During the initial system startup, while the charger IC is being
programmed, the system current is limited to 340mA for 1ms
during steps 4 and 5. This is the value of the soft-start ICHARGE
current used when IINLIM is set to no limit.
CONTROL
If the system powers up without a battery present, the CV bit
should be set. When a battery is inserted, the CV bit clears.
–
Figure 6. Li-Ion Battery Pack
Powering a System when the
Battery is Deeply Discharged
Q2 in the protection circuit opens if the cell is deeply
discharged (VCELL < 2.7V). Charging is therefore still
possible by driving current into the pack through Q2’s body
diode. Refer to Figure 7 for the different states.
When the battery voltage is lower than the voltage required
to power the system load, the power routing implementation
(Error! Reference source not found. and Figure 5) cannot
bring up the system.
In contrast, power path, as implemented in Figure 1, can still
power the system even if the battery voltage is substantially
lower than the system load needs to operate. This is the
primary advantage of the circuit in Figure 1 as compared to
FAN5400. However, it is important to realize that the slope
of the curve during this phase of the charge cycle is
incredibly steep, which means that the battery voltage is
brought up to the minimum system load requirement within
a matter of seconds.
© 2010 Fairchild Semiconductor Corporation
Rev. 1.0.0 • 12/23/10
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AN-9720
Table 1.
APPLICATION NOTE
Internal Batter Protections Scheme
Condition
Detection
Response
Reset
Over-Charge
VCELL>4.25
Open Q1
VCELL>4.10
Over-Discharge
VCELL<2.7
Open Q2
VCELL>2.95
Over IDISCHARGE
VCELL – VBAT>X
Open Q2
VCELL ≈ VBAT
to Table 2). The charger continues to run in “auto” mode until
the applications processor wakes up at 3.4V in about 15seconds time. The applications processor then enumerates
with USB and sets IBUS = 500mA and ICHARGE = 700mA.
In the extreme case that the battery is deeply discharged, the
discharge protection switch (Q2) is open. When the charger is
plugged in the USB port; if OTG = 0, the trickle charge of
30mA charges the system capacitor to 2V in 20ms time (refer
Table 2.
Bringing Battery Out of Deep Discharge
Condition
VBAT
IBAT
Linear Charge (20ms)
0 to
2.0
30mA
Comment
VBAT=EMF+0.7
Charger is charging system cap.
t15MIN (default) PWM Charge
with IBUS set by OTG Pin (15s)
VBAT=(EMF=+0.7+.1•ESR)
2.0 to
100mA Some charge going to VCELL
3.4
Apps processor wakes up at VBAT≈3.4V
High-Current PWM Charge
1s to Q2 Close
3.5+
Higher charge current set by processor. This causes VCELL to rise, which
700mA causes Q2 to close at point A in Figure 7. VBAT drops to about 2.9 and
charging continues from there.
The charge cycle behavior is shown graphically in Figure 7.
The time it takes to charge a typical battery to a stable 3.4V
is 40 seconds. This process is explained below.
4.00
0.6
3.00
0.5
VBAT
2.50
Battery Current (A)
0.4
2.00
IBAT (A)
B
Q2 closes about 1s after
the processor programs
the IC for higher charge
current. This causes VBAT
to drop (no more diode in
series with VBAT).
0.7
3.50
VBAT (V)
A
Processor wakes up when
VBAT > 3.4V, which occurs
about 15s after VBUS is
plugged in.
0.8
A
0.3
1.50
0.2
1.00
0.1
0.50
0
20
40
60
80
100
120
0
140
Time (seconds)
Figure 7. Charge Characteristics for Deeply Discharged and Dead Batteries
© 2010 Fairchild Semiconductor Corporation
Rev. 1.0.0 • 12/23/10
www.fairchildsemi.com
6
AN-9720
APPLICATION NOTE
Conclusion
the FAN5400, configured as in Figure 3, does not have a
power-dissipating series element between battery and system
load and provides the two more critical aspects of dynamic
power routing… power sharing between the system and the
battery and powering the system with no battery.
Although there are situations where the FAN540X partial
power path in Figure 2 cannot immediately power the system
load when the battery is very low or deeply discharged, this
timeframe for a typical cell phone battery is only 40 seconds.
It is important to weigh this against the benefits offered by the
FAN540X. This benefit was discussed in detail, showing that
Related Resources
FAN5400 Family — USB-Compliant Single-Cell Li-Ion Switching Charger with USB-OTG Boost Regulator
AN-1721 — Li-Ion Battery Charging Basics, Featuring the FAN5400 / FAN5420 Family of PWM Battery Chargers
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FAIRCHILD SEMICONDUCTOR RESERVES THE RIGHT TO MAKE CHANGES WITHOUT FURTHER NOTICE TO ANY PRODUCTS
HEREIN TO IMPROVE RELIABILITY, FUNCTION, OR DESIGN. FAIRCHILD DOES NOT ASSUME ANY LIABILITY ARISING OUT OF THE
APPLICATION OR USE OF ANY PRODUCT OR CIRCUIT DESCRIBED HEREIN; NEITHER DOES IT CONVEY ANY LICENSE UNDER ITS
PATENT RIGHTS, NOR THE RIGHTS OF OTHERS.
LIFE SUPPORT POLICY
FAIRCHILD’S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT DEVICES OR SYSTEMS
WITHOUT THE EXPRESS WRITTEN APPROVAL OF THE PRESIDENT OF FAIRCHILD SEMICONDUCTOR CORPORATION.
As used herein:
1.
Life support devices or systems are devices or systems
which, (a) are intended for surgical implant into the body, or
(b) support or sustain life, or (c) whose failure to perform
when properly used in accordance with instructions for use
provided in the labeling, can be reasonably expected to
result in significant injury to the user.
© 2010 Fairchild Semiconductor Corporation
Rev. 1.0.0 • 12/23/10
2.
A critical component is any component of a life support
device or system whose failure to perform can be
reasonably expected to cause the failure of the life support
device or system, or to affect its safety or effectiveness.
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