Battery/Charger Load Switch Approximates Ideal Diode

Maxim > Design Support > Technical Documents > Application Notes > Amplifier and Comparator Circuits > APP 4840
Maxim > Design Support > Technical Documents > Application Notes > Battery Management > APP 4840
Keywords: load switching, rechargeable battery-powered systems, Li+ battery chargers, power OK (POK)
outputs
APPLICATION NOTE 4840
Battery/Charger Load Switch Approximates Ideal
Diode
By: Budge Ing
Hubert Bugajski
Feb 10, 2011
Abstract: Two circuits are described. The first uses external MOSFETs driven by the Power OK (POK)
output of a Li-cell charger IC (MAX8814), to switch a load between battery and charging source without
intervention from a microcontroller or system software. For charger ICs without a POK output (such as
the MAX1507), the second circuit does the same switching using MOSFETs and a comparator
(MAX920).
A similar version of this article appeared in the July 19, 2010 issue of Electronic Design magazine.
Most rechargeable battery-powered systems include a switch that connects the load either to the battery
or to a source of charging power. Without it, a system with depleted battery may not operate
immediately when plugged in. A switching circuit also allows the system to operate on adapter power
while the battery is charging.
The simplest and lowest-cost method for this battery/adapter power handoff is a diode-OR connection.
The load connects to each power source (battery and adapter) through separate Schottky diodes, so
power is applied by the higher voltage—battery or adapter. The drawback to this approach is the power
loss (PD = IBATTERYVDIODE) and voltage drop (VDIODE = 0.350V at 0.5A, from the PMEG2010AEH data
sheet) incurred when the battery services the load. Such losses may not be significant for high-voltage
multicell batteries, but for 1-cell Li+ batteries or 2–4 cell NiMh batteries, the percentages of power loss
and diode drop across the blocking diode are considerable.
The circuit of Figure 1 switches loads with a voltage drop of only 45mV at 0.5A, which is a head-room
improvement of 350mV - 45mV = 305mV. When compared with the diode-OR connection (175mW vs.
22.5mW), the power saving is 152.5mW. At lower currents the dropout voltage is even lower. At 100mA,
for instance, a diode drops about 270mV but the Figure 1 circuit drops only 10mV.
Page 1 of 4
Figure 1. This circuit connects the load either to the battery voltage or to VDC IN, depending on which
voltage is higher.
The Figure 1 circuit manages load switching without intervention from a microcontroller or system
software. When operating on batteries and with VDC IN disconnected, the POK (Power OK) output for the
MAX8814 is high. This condition connects load and battery by turning on Q4 and Q3. Node 1 is biased
to the battery voltage through R2, which maintains Q1 and Q2 OFF. When VDC IN connects to a DC
source, Q1 and Q2 are held OFF because C1 raises node 1 to VBATT + VDC.
High voltage at the gates of Q1 and Q2 is generated instantly when VDC IN is applied. To prevent
damage at the POK input, Q5 is configured as a source follower (voltage buffer). With the gate biased to
the battery voltage, POK sees no voltage higher than the battery voltage. When POK goes low, current
flows through Q5 and pulls down the gates of Q1 and Q2, turning them ON. VDC IN services the load,
and the charger IC (U1) charges the battery. C1 and R1 provide a short delay that allows Q3 time to
turn off, preventing unregulated current from flowing to the battery.
When VDC IN is removed, POK becomes a high-impedance node, and battery current flows through the
body diode of Q3. The load voltage is VBATT - VDIODE. Because Q5's gate is biased at the battery
voltage, Q5 conducts until POK reaches a voltage level sufficient to to service the load by turning on Q4
and Q3. Figure 2 shows the response of the Figure 1 circuit (with battery installed), while VDC IN is
applied and removed.
Page 2 of 4
Figure 2. These waveforms illustrate behaviour of the Figure 1 circuit as the load is switched from DC
power to battery and back to DC power. (CH1 is voltage across the load, CH2 is the DC supply voltage,
CH3 is the active-low POK output, and CH4 is the battery current.)
A modified circuit (Figure 3) is suitable for battery-charging ICs such as the MAX1507, which does not
provide a POK output. The comparator (U3) provides a POK output by comparing VDC IN to the battery
voltage. Like Figure 2, Figure 4 shows voltage at the load when VDC IN is applied and removed, for the
Figure 3 circuit with battery installed.
Figure 3. For battery-charger ICs without a POK output, this circuit performs the same function as that of
Figure 1.
Page 3 of 4
Figure 4. These waveforms illustrate behaviour of the Figure 3 circuit as the load is switched from DC
power to battery and back to DC power. (CH1 is voltage across the load, CH2 is the DC supply voltage,
CH3 is the active-low POK output, and CH4 is the battery current.)
Related Parts
MAX1507
Linear Li+ Battery Charger with Integrated Pass FET and
Thermal Regulation in 3mm x 3mm Thin DFN
MAX8814
28V Linear Li+ Battery Charger with Smart Autoboot
Assistant
Free Samples MAX920
SOT23, 1.8V, Nanopower, Beyond-the-Rails
Comparators With/Without Reference
Free Samples More Information
For Technical Support: http://www.maximintegrated.com/support
For Samples: http://www.maximintegrated.com/samples
Other Questions and Comments: http://www.maximintegrated.com/contact
Application Note 4840: http://www.maximintegrated.com/an4840
APPLICATION NOTE 4840, AN4840, AN 4840, APP4840, Appnote4840, Appnote 4840, DI #839
Copyright © by Maxim Integrated Products
Additional Legal Notices: http://www.maximintegrated.com/legal
Page 4 of 4