MAX1680 Datasheet, PDF(7/12 Page) Maxim Integrated Products – 125mA, Frequency-Selectable, Switched-Capacitor Voltage Converters

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MAX1680 Datasheet, PDF (7/12 Pages) Maxim Integrated Products – 125mA, Frequency-Selectable, Switched-Capacitor Voltage Converters

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125mA, Frequency-Selectable,

Switched-Capacitor Voltage Converters

Operating Frequency Trade-Offs

It is important to recognize the trade-offs between

switching frequency, power consumption, noise, cost,

and performance. Higher frequency switching reduces

capacitor size while maintaining the same output

impedance, thus saving capacitor cost and board

space. Lower frequency designs use less supply cur-

rent. Table 2 summarizes the relative trade-offs.

Table 2. Switching-Frequency Trade-Offs

ATTRIBUTE

Output Ripple

C1, C2 Values

Supply Current

LOWER

FREQUENCY

Larger

Smaller

HIGHER

FREQUENCY

Smaller

Larger

Capacitor Selection

The MAX1680/MAX1681 are tested with capacitor val-

ues of 10ÂµF and 2.2ÂµF, respectively. Capacitor size

and switching speed determine output resistance.

Larger C1 values decrease the output resistance until

the internal switch resistance (3.5â¦ typ) becomes the

dominant term. Low-ESR capacitors minimize output

resistance and ripple voltage. The entire circuitâs output

resistance can be approximated by the following equa-

tion:

ROUT â RO + 4 x ESRC1 + ESRC2 + [1 / (fOSC x C1)] +

[1 / (fOSC x C2)]

where RO is the deviceâs internal effective switch resis-

tance and fOSC is the switching frequency. Output

resistance is a critical circuit component, as it deter-

mines the voltage drop that will occur at the output from

the ideal value of -VINPUT (or 2VINPUT when doubling).

To optimize performance, minimize overall resistance in

the system. In particular, equivalent series resistance

(ESR) in the capacitors produces significant losses as

large currents flow through them. Therefore, choose a

low-ESR capacitor for highest efficiency. Table 3 lists

recommended capacitors and their suppliers.

Calculate the output ripple voltage as follows:

VRIPPLE = [(IOUT) / (2 x fOSC x C2)] + 2 x (IOUT x ESRC2)

where IOUT is the load current, fS is the charge pumpâs

operating frequency, C2 is the output capacitor, and

ESRC2 is the output capacitorâs ESR.

Table 4 lists the minimum recommended capacitances

that allow for the maximum output current. The output

capacitor, C2, is normally equal to or greater than the

charge-pump capacitor, C1. Capacitor values can be

scaled directly proportional to the input voltage, fre-

quency, and load current. For example, for VINPUT =

5V, ILOAD = 125mA at fOSC = 125kHz, a 6.4ÂµF mini-

mum capacitor is recommended. For an output of only

62.5mA, a 3.2ÂµF capacitor is recommended. C1âs value

can be estimated as follows:

C1 = 6.4ÂµF x (VINPUT / 5.0V) x (125kHz / fOSC) x

(ILOAD / 125mA)

where fOSC is the switching frequency (kHz) and ILOAD

is the output current (mA) required.

Table 3. Low-ESR Capacitor Suppliers

SUPPLIER

AVX

Marcon/United Chemi-Con

Matsuo

Nichicon

Sanyo

Sprague

TDK

United Chemi-Con

Vishay/Vitramon

PHONE

(803) 946-0690

(800) 282-4975

(847) 696-2000

(714) 969-2491

USA: (847) 843-7500

Japan: 81-7-5231-8461

USA: (619) 661-6835

Japan: 81-7-2070-6306

(603) 224-1961

(847) 390-4373

(714) 255-9500

(203) 268-6261

FAX

(803) 626-3123

(847) 696-9278

(714) 960-6492

USA: (847) 843-2798

Japan: 81-7-5256-4158

USA: (619) 661-1055

Japan: 81-7-2070-1174

(603) 224-1430

(847) 390-4428

(714) 255-9400

(203) 452-5670

DEVICE TYPE

Surface mount, TPS series

Ceramic capacitors

Surface mount, 267 series

Through-hole, PL series

Through-hole, OS-CON series

Surface mount, 595D series

Ceramic capacitors

Through-hole, LXF series

SMT ceramic chip capacitors

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