Simple Methods Reduce Input Ripple for All Charge Pumps

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TUTORIAL 2027
Simple Methods Reduce Input Ripple for All Charge
Pumps
May 13, 2003
Abstract: Charge pumps are a form of DC-DC converter that rely on capacitors instead of inductors for energy
storage and transfer. The absence of inductors makes them attractive in situations requiring a low-power auxiliary
supply (output currents up to about 150mA). They use less circuit-board area, offer minimal component height, and
are easy to use.
Charge pumps can have regulated or unregulated outputs. An unregulated charge pump either doubles or inverts
the voltage that powers it and the output voltage is a function of the supply voltage. A regulated charge pump
either boosts or inverts the supply voltage. Its output voltage is independent of the supply.
Techniques that reduce capacitor size and optimize output current—fast switching speed and low-on-resistance
switches—also produce noise and transient ripple at the input supply pin. Noise can propagate back along the
input supply pins, creating problems for crystal-controlled oscillators, VCOs, and other sensitive circuits with poor
power-supply rejection. This article focuses on methods for reducing the noise.
Simplified Operation
First, consider a charge pump connected as an inverter. In the simplified version (Figure 1), operation is controlled
by 2-phase clock signals with 50% duty cycles. The pump capacitor (charge-transfer component) is charged to VIN
via closure of SW1A and SW1B. SW2A and SW2B are open at this time. On the next clock cycle, the closure of
SW2A and SW2B connects the pump capacitor to C OUT , thereby producing -VIN at the output.
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Figure 1. Simplified diagram of a charge pump connected as an inverter.
Next, connect the charge pump as a doubler (Figure 2). As before, operation is controlled by 2-phase, 50%-dutycycle clock signals. The pump capacitor is the charge transfer device and is charged up to VIN by closure of SW2A
and SW2B (SW1A and SW2B are open at this time). On the next clock cycle, the closure of SW1A and SW1B
produces +2V IN at the output by connecting the pump capacitor to C OUT .
Figure 2. Simplified diagram of a charge pump connected as a doubler.
Input and output ripple is caused by rapid charging and discharging of the pump capacitor. An inverter circuit
(Figure 3) built around the MAX665 charge pump and producing 5V across 51Ω, illustrates the input-ripple
artifacts (Figure 4). (Ripple produced by the high-current, low-frequency (≤ 100kHz) MAX665 is easily measured.)
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Figure 3. This charge-pump inverter circuit is used for measurements.
Figure 4. Input voltage and current ripple for standard inverter circuit: C IN = C PUMP = C OUT = 100µF,
R LOAD = 51Ω, VIN = +5.73V, and VOUT = -5.06V. Input current ripple (upper trace): 100mA/div. Input voltage ripple
(lower trace): 200mV/div, AC coupled.
Ripple-reduction Methods
To reduce ripple, you must isolate ripple sources from the rest of the circuit. For best conversion efficiency in the
charge pump, you should also minimize ESR and ensure that the input-, output-, and pump-capacitor values are
as close as possible to those recommended in the data sheet. The following discussion covers four techniques for
minimizing ripple and its effects.
1. Reducing ESR in the input capacitor implies multiple capacitors connected in parallel: N identical capacitors in
parallel reduces the input ripple by N -1 . Unfortunately, that approach is not very effective in terms of cost and pcboard area.
2. Instead, add an LC filter at the input supply pin (Figure 5). The additional filtering prevents ripple from
propagating to other circuits via the input supply trace. As a second-order filter, the LC network minimizes the
component count. In addition, its small series inductance produces a minimal voltage drop between the input
supply and the charge pump.
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Figure 5. Charge-pump inverter with input LC filter.
The ripple-frequency fundamental equals the pump frequency (F CLOCK/2). Second-order filters attenuate at
40dB/decade, so the ideal filter frequency should be a minimum of one decade below the chosen FCLOCK/2.
The inductor must handle dc currents greater than 1.5IOUT without saturation. For critical damping (ie., with no
peaking),
The filter should be critically damped or close to it, given the low impedance values of R SOURCE and R LOAD.
Critical damping is not essential to the circuit operation, however. Filtering remains effective even with some
peaking at the point of roll-off. A 10µF filter capacitor and 10µH filter choke together provide a 3dB frequency of
15.9kHz and a critical R SOURCE of 1Ω. Figure 6 shows the Figure 5 circuit's amplitude response for various
damping ratios, and Figure 7 shows its lower levels of ripple (vs. the circuit of Figure 3).
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Figure 6. Amplitude characteristic for various damping ratios in the LC-Filter circuit of Figure 5.
Figure 7. Input voltage and current ripple of LC-filter circuit (Figure 5). C IN = C FILTER = 100µF, and
L FILTER = 10µH. Charge pump is MAX665. Input current ripple (upper trace): 100mA/div. Input voltage ripple (lower
trace): 50mV/div, AC coupled.
3. Adding a low-dropout linear regulator to the charge pump's input supply (Figure 8) yields an effective generalpurpose circuit for preventing the effects of ripple on the rest of the system. The input LDO also operates with
smaller capacitors than those associated with a passive LC filter: the 300mA MAX8860 LDO (available in an 8-pin
µMAX® package) requires 2.2µF capacitors at input and output; the MAX8863–MAX8864 family of 120mA linear
regulators (available in SOT23 packages) requires only 1µF ceramic capacitors. The LDO must handle at least
twice the charge pump's output load current, however. When compared with an equivalent passive filter, the added
expense of that extra-current capability can place the LDO approach out of bounds in terms of cost and
performance (pcb area and attenuation).
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Figure 8. Charge pump doubler with LDO for input-ripple protection.
4. Adding an RC to the input supply (Figure 9) is a single-order version of the LC-filter approach. The RC input is
not generally recommended, because the low value of R FILTER required for minimal efficiency loss (< 5Ω) forces a
very large C FILTER. Figure 10 shows the effect of adding an RC filter at the input of the Figure 9 circuit, in which a
MAX665 with 100µF capacitors generates a 5V output with a load resistance of 51Ω.
Figure 9. Battery application featuring a charge pump inverter with input RC ripple filter.
If the input supply is a battery, then the effective bulk capacitance of the battery can serve as C FILTER. Because
C FILTER is a very large capacitance, the resulting filter is very effective in reducing ripple effects at the battery. An
example helps to illustrate the point: the capacitance of an 800mAH Li cell can be derived from:
Q = C.V
I.T = C.V
, where I = 800mA, T = 3600s (1Hr), and V = 3.4V.
Thus, C = 847 farads and fFILTER = 0.12mHz. The sum of ESR and battery contact resistance (about 100mΩ)
limits the attenuation to a maximum of 21dB, assuming the ripple source resistance (RFILTER) equals 1Ω. The
model for an actual battery is more complex, with the central bulk capacitance modified by ESR, ESL, and
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parasitic capacitance. In practice one should add capacitance close to R FILTER, thereby providing high frequency
assistance and low ESR above 250kHz (< 50mΩ) to the battery and its interconnect leads. A typical value for the
additional C FILTER is 470nF. For the MAX665 circuit of Figure 10, increasing C FILTER to 1500µF lowers the input
voltage and current ripple as shown in Figure 11.
Figure 10. Input Voltage and Current Ripple for the RC-filter circuit (Figure 9): C IN = C FILTER = 100µF, and
R FILTER = 2.2Ω. Charge pump is a MAX665. Input current ripple (upper trace): 100mA/div. Input voltage ripple
(lower trace): 20mV/div, AC coupled.
Figure 11. Input voltage and current ripple for the RC-filter circuit of Figure 7, with 1500µF quasi-battery capacitor:
C IN =100µF, C FILTER = 1500µF, R FILTER = 2.2Ω, and MAX665 charge pump. Input current ripple (upper trace):
100mA/div. Input voltage ripple (lower trace): 20mA/div, AC coupled.
Conclusion
Several methods are available for reducing the effect of input power-supply ripple caused by charge pumps.
Placing an LC filter in addition to the input capacitor recommended by the data sheet, for instance, (#2) provides
excellent voltage-ripple protection to the rest of the system (Figure 10) with minimal effect on the overall
conversion efficiency. An effective alternative for battery systems is a simple series resistor (#4), which occupies
minimal space. The resistor is also suitable in non-battery applications for which large storage values (> 50µF) are
appropriate. Results of a simulated battery application are shown in Figure 11.
An overview of Maxim's charge-pump ICs (Table 1) is included to help the reader choose an appropriate device
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according to the desired clock frequency, mode of operation, and level of output current required.
Table 1 Product Selection
Part No
MAX660
MAX665
MAX860
MAX861
Package
8-SO
16-wSO
8-µMax/SO
8-µMax/SO
I/P Volts
1.5V to 5.5V
1.5V to 8V
1.5V (inv) or 2.5V to 5.5V
1.5V (inv) or 2.5V to 5.5V
O/P
Current
100mA
100mA
50mA
50mA
Pump
Rate
10kHz/80kHz
10kHz/45kHz
3kHz/50kHz/130kHz
13kHz/100kHz/250kHz
Mode
-VIN, +2V IN
-VIN, +2V IN
-VIN, +2V IN
-VIN, +2V IN
No
No
No
Regulated No
Part No
MAX1680
MAX1681
MAX1682
MAX1683
Package
8-SO
8-SO
5-SOT23
5-SOT23
I/P Volts
2.0V to 5.5V
2.0V to 8V
1.5V (inv) or 2.5V to 5.5V
1.5V (inv) or 2.5V to 5.5V
O/P
Current
125mA
125mA
45mA
45mA
Clock
Freq
125kHz/250kHz 500kHz/1MHz
12kHz
35kHz
Mode
-VIN, +2V IN
-VIN, +2V IN
+2V IN
+2V IN
No
No
No
Regulated No
Part No
MAX870
MAX871
MAX 1697 R,S,T,U
MAX1720
Package
5-SOT23
5-SOT23
6-SOT23
6-SOT23
I/P Volts
1.4V to 5.5V
1.4V to 5.5V
1.5V to 5.5V
1.5V to 5.5V
O/P
Current
25mA
25mA
60mA
25mA
Clock
Freq
125kHz
500kHz
12kHz/35kHz/125kHz/250kHz 12kHz
Mode
-VIN
-VIN
-VIN
-VIN
No
No
No
Regulated No
Part No
MAX1719
/MAX1721
MAX864
MAX865
MAX680
Package
6-SOT23
16-QSOP
8-µMax
8-SO
I/P Volts
1.5V to 5.5V
2.0V to 6.0V
1.5V to 6.0V
2.0V to 6.0V
O/P
Current
25mA
±10mA
±10mA
±10mA
Clock
Freq
125kHz
7kHz/33kHz/100kHz/185kHz 24kHz
8kHz
Mode
-VIN
+2V IN and -VIN
+2V IN and -VIN
+2V IN and -VIN
No
No
No
Regulated No
Part No
Package
MAX619
8-µMax
MAX622A
8-SO
MAX679
8-µMax
MAX682
8-SO
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I/P Volts
2.0V to 3.6V
4.5V to 5.5V
1.8V to 3.6V
2.7V to 5.5V
O/P
Current
60mA
30mA
20mA
250mA
Clock
Freq
500kHz
500kHz
330kHz/1MHz
200kHz/1MHz
Yes
Yes
Yes
Regulated Yes
Part No
MAX683
MAX684
MAX768
MAX840/MAX843/MAX844
Package
8-µMax
8-µMax
16-QSOP
8-SO
I/P Volts
2.7V to 5.5V
2.7V to 5.5V
3.0V to 5.5V
2.5V to 10.0V
O/P
Current
100mA
50mA
±5mA
4mA
Clock
Freq
5.0V
5.0V
±5V, Adj
-2.0V, Adj
Mode
200kHz/1MHz
200kHz/1MHz
25kHz/100kHz, 20kHz240kHz ext sync
20kHz/100kHz
Yes
Yes
Yes
Regulated Yes
Part No
MAX850/
MAX851/
MAX852/
MAX853
MAX868
MAX881R
MAX1673
Package
8-SO
10-µMax
10-µMax
8-SO
I/P Volts
4.5V to 10.0V
1.8V to 5.5V
2.5V to 5.5V
2.0V to 5.5V
O/P
Current
5mA
30mA
4mA
125mA
Adj, -2VIN max
-2V, Adj
Adj, -VIN max
100kHz
350kHz
Yes
Yes
O/P Volts -4.1V, Adj
Clock
Freq
100kHz 50kHz250kHz ext
450kHz
sync
Regulated Yes
Part No
Yes
MAX1686
/MAX1686H
MAX1730
MAX1759
Package
8-µMax
10-µMax
8-µMax
I/P Volts
2.7V to 4.2V
2.7V to 5.5V
1.6V to 5.5V
O/P
Current
12mA
50mA
100mA
O/P Volts 4.75V/5.0V
1.8V/1.9V Adj
3.3V, Adj
Clock
Freq
450kHz
1.5MHz
Yes
Yes
1MHz
Regulated Yes
µMAX is a registered trademark of Maxim Integrated Products, Inc.
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Free Samples More Information
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