MAX684EUA+T Datasheet MAX682ESA+, MAX682ESA+T, MAX684EUA+T | P7-P9

MAX682/MAX683/MAX684

3.3V-Input to Regulated 5V-Output

Charge Pumps

_______________________________________________________________________________________ 7

output noise contains well-defined frequency compo-

nents, and the circuit requires much smaller external

capacitors for a given output ripple. However, constant-

frequency mode, due to higher operating current, is

less efficient at light loads than skip mode. Note: For

input voltages above 3.6V, the devices must operate in

constant-frequency mode. Table 1 summarizes the

tradeoffs between the two operating modes.

Frequency Selection and Shutdown

The SHDN pin on the MAX682/MAX683/MAX684 per-

forms a dual function: it shuts down the device and

determines the oscillator frequency. The SHDN input

looks like a diode to ground and should be driven

through a resistor.

Driving SHDN low places the device in shutdown

mode. This disables all switches, the oscillator, and

control logic. The device typically draws 0.1µA (5µA

max) of supply current in this mode and the output pre-

sents a 50kΩ impedance to ground. The device exits

shutdown once SHDN is forward biased (minimum of

1µA of current). The typical no-load shutdown exit time

is 50µs.

When SHDN is pulled high through an external resistor

to V

, the bias current into SHDN determines the

charge-pump frequency. To select the frequency, cal-

culate the external resistor value, R

EXT

, using the fol-

lowing formula:

EXT

= 45000 (V

- 0.69V) / f

OSC

where R

EXT

is in kΩ and f

OSC

is in kHz. Program the

frequency in the 50kHz to 2MHz range. This frequency

range corresponds to SHDN input currents between

1µA and 50µA. Proper operation of the oscillator is not

guaranteed beyond these limits. Currents lower than

1µA may shut down the device. The forward-biased

diode voltage from the SHDN input to GND has a tem-

perature coefficient of -2mV/°C.

Undervoltage Lockout

The MAX682/MAX683/MAX684 have an undervoltage-

lockout feature that deactivates the devices when the

input voltage falls below 2.25V. Regulation at low input

voltages cannot be maintained. This safety feature

ensures that the device shuts down before the output

voltage falls out of regulation by a considerable amount

(typically 10% with no load). Once deactivated, hys-

teresis holds the device in shutdown until the input volt-

age rises 100mV above the lockout threshold.

Applications Information

Capacitor Selection

The MAX682/MAX683/MAX684 require only three exter-

nal capacitors (Figure 5). Their values are closely linked

to the output current capacity, oscillator frequency, out-

put noise content, and mode of operation.

Generally, the transfer capacitor (C

) will be the small-

est, and the input capacitor (C

) is twice as large as

. Higher switching frequencies allow the use of

smaller C

and C

. The output capacitor (C

OUT

) can

be anywhere from 5-times to 50-times larger than C

depending on the mode of operation and ripple toler-

ance. In continuous switching mode, smaller output rip-

ple allows smaller C

OUT

. In skip mode, a larger C

OUT

required to maintain low output ripple. Tables 2 and 3

show capacitor values recommended for lowest sup-

ply-current operation (skip mode) and smallest size oper-

ation (constant-frequency mode), respectively.

OUT

OSC

N-CHANNEL

Figure 4. Constant-Frequency-Mode Regulation

FEATURE

SKIP MODE

(

SKIP = LOW)

CONSTANT-

FREQUENCY MODE

(SKIP = HIGH)

Best Light-Load

Efficiency

✔

Smallest External

Component Size

✔

Output Ripple

Amplitude and

Frequency

Relatively large

amplitude, variable

frequency

Relatively small

amplitude, constant

frequency

Load Regulation Very Good Good

Table 1. Tradeoffs Between Operating

Modes

MAX682/MAX683/MAX684

In addition, the following two equations approximate

output ripple for each mode. In skip mode, output rip-

ple is dominated by ESR, and is approximately:

RIPPLE(SKIP)

≅ (2V

- V

OUT

)ESR

COUT

/ R

where ESR

COUT

is the ESR of the output filter capaci-

tance, and R

is the open-loop output transfer resist-

ance of the IC. R

is typically 0.8Ω for the MAX682,

1.6Ω for the MAX683, and 3Ω for the MAX684. In con-

stant-frequency mode, output ripple is dominated by

OUT

and is approximately:

RIPPLE(const-freq)

≅ I

OUT

/ (2 x f

OSC

x C

OUT

)

All capacitors must maintain a low (<100mΩ) equiva-

lent series resistance (ESR). Table 4 lists the manufac-

turers of recommended capacitors. Surface-mount

tantalum capacitors will work well for most applications.

Ceramic capacitors will provide the lowest ripple due to

their typically lower ESR.

If the source impedance or inductance of the input sup-

ply is large, additional input bypassing (2.2µF to 22µF)

may be needed. This additional capacitance need not

be a low-ESR type.

3.3V-Input to Regulated 5V-Output

Charge Pumps

8 _______________________________________________________________________________________

PART

(µF)

MAX682 2.2 47

MAX683 1 22

MAX684 0.47 10

OUT

RIPPLE

(mV)

100

(µF)

0.47

0.22

OUTPUT

(mA)

250

100

Table 2. Recommended Capacitor Values

for Quiescent Current (Skip Mode)

Table 3. Recommended Capacitor Values

for Smallest Size (Constant-Frequency

Mode, I

SSHHDDNN

= 22µA, 1MHz)

PART

(µF)

CERAMIC

OUT

(µF)

MAX682 1 2.2

MAX683 0.47 1

MAX684 0.22 0.47

OUT

RIPPLE

(mV)

(µF)

0.47

0.22

0.1

OUTPUT

(mA)

250

100

MANUFACTURER

PHONE

NUMBER

Sprague (603) 224-1961

AVX (803) 946-0690

VALUE

47µF to

10µF

47µF to

10µF

CXP

3.3V

CXN

SHDN

OUTIN

1µF

0.47µF

100k 100k

4.7µF

SKIP

GND PGND

MAX682

SKIP

CXP

CXN

OUT

5V/500mA

SHDN

GND PGND

Figure 6. Paralleling Two MAX682s

TDK (847) 390-4373

0.1µF to

2.2µF

Table 4. Recommended Capacitor

Manufacturers

OUT

CXN

CXP

SHDN

OUT

4 5

OFF

EXT

SKIP

GND PGND

MAX682

MAX683

MAX684

Figure 5. Standard Operating Circuit

TANTALUM

OUT

(µF)

4.7

2.2

CERAMIC

Ceramic

surface mount

DESCRIPTION

595D-series

tantalum

surface mount

TPS-series

surface mount

MAX682/MAX683/MAX684

3.3V-Input to Regulated 5V-Output

Charge Pumps

_______________________________________________________________________________________ 9

Power Dissipation

The power dissipated in the MAX682/MAX683/MAX684

depends on output current and is accurately described

by:

DISS

= I

OUT

(2V

- V

OUT

)

DISS

must be less than that allowed by the package

rating. See the

Absolute Maximum Ratings

for 8-pin

µMAX (MAX683/MAX684) and SO (MAX682) power-

dissipation limits and deratings.

Layout Considerations

All capacitors should be soldered in close proximity to

the IC. Connect ground and power ground through a

short, low-impedance trace. If a high-value resistor is

driving the shutdown input and is picking up noise (i.e.,

frequency jitter at CXP and CXN), bypass SHDN to

GND with a small capacitor (0.01µF).

Paralleling Devices

The MAX682/MAX683/MAX684 can be paralleled to

yield higher load currents. The circuit of Figure 6 can

deliver 500mA at 5V. It uses two MAX682s in parallel.

The devices can share the output capacitors, but each

one requires its own transfer capacitor (C

) and input

capacitor. For best performance, the paralleled devices

should operate in the same mode (skip or constant fre-

quency).

Chip Information

TRANSISTOR COUNT: 659

SUBSTRATE CONNECTED TO GND

Package Information

8LUMAXD.EPS

P1-P3 P4-P6 P7-P9 P10-P12

MAX684EUA+T

Mfr. #:

Buy MAX684EUA+T

Manufacturer:

Maxim Integrated

Description:

Switching Voltage Regulators 3.3Vin to Reg 5Vout Charge Pump

Lifecycle:

New from this manufacturer.

Delivery:

DHL FedEx Ups TNT EMS

Payment:

T/T Paypal Visa MoneyGram Western Union

MAX684EUA+T

MAX684EUA+T

Products related to this Datasheet