MAX774CPA View Datasheet(PDF) - Maxim Integrated

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MAX774CPA

-5V/-12V/-15V or Adjustable, High-Efficiency, Low IQ Inverting DC-DC Controllers

Maxim Integrated 

-5V/-12V/-15V or Adjustable,

High-Efficiency, Low IQ Inverting DC-DC Controllers

0.1µF

VOUT

RZ

1

OUT

8

GND

R2

MAX774

2

FB

MAX775

R1

MAX776

0.1µF

4 REF

6V ≤ VZ + VIN ≤ 10V

VOUT – VZ

RZ

> IZ

IZ = ZENER BREAKDOWN CURRENT

VZ = ZENER BREAKDOWN VOLTAGE

VIN = INPUT SUPPLY VOLTAGE

Figure 5. Connection Using Zener Diode to Boost Base Drive

using bootstrapped or non-bootstrapped mode will

directly affect the gate drive to the FET. EXT swings

from V+ to VOUT. In bootstrapped operation, OUT is

connected to the output voltage (-5V, -12V, -15V). In

non-bootstrapped operation, OUT is connected to

ground, and EXT now swings from V+ to ground.

At high input-to-output differentials, it may be neces-

sary to use non-bootstrapped mode to avoid the 21V

V+ to VOUT maximum rating. Also, observe the VGS

maximum rating of the external transistor. At intermedi-

ate voltages and currents, the advantages of boot-

strapped vs. non-bootstrapped operation are slight.

When input voltages are less than about 4V, always use

the bootstrapped circuit.

Shutdown and Quiescent Current

The MAX774/MAX775/MAX776 are designed to save

power in battery-powered applications. A TTL/CMOS

logic-level shutdown input (SHDN) has been provided

for the lowest-power applications. When shut down

(SHDN = V+), most internal bias current sources and

the reference are turned off so that less than 5µA of

current is drawn.

In normal operation, the quiescent current will be less

than 100µA. However, this current is measured by

forcing the external switch transistor off. Even with no

load, in an actual application, additional current will be

drawn to supply the feedback resistors’ and the diode’s

and capacitor’s leakage current. Under no-load condi-

tions, you should see a short current pulse at half the

peak current approximately every 100ms (the exact

period depends on actual circuit leakages).

EXT Drive Voltages

EXT swings from OUT to V+ and provides the drive out-

put for an external power MOSFET. When using the on-

chip feedback resistors for the preset output voltages,

the voltage at OUT equals the output voltage. When

using external feedback resistors, OUT may be tied to

GND or some other potential between VOUT and GND.

Always observe the V+ to OUT absolute maximum rat-

ing of 21V. For V+ to output differentials greater than

21V, OUT must be tied to a potential more positive than

the output and, therefore, the output voltage must be

set with an external resistor divider.

In non-bootstrapped operation with low input voltages

(<4V), tie OUT to a negative voltage to fully enhance the

external MOSFET. Accomplish this by creating an inter-

mediate voltage for VOUT with a zener diode (Figure 5).

__________________Design Procedure

Setting the Output Voltage

The MAX774/MAX775/MAX776 are preset for -5V, -12V,

and -15V output voltages, respectively; however, they

may also be adjusted to other values with an external

voltage divider. For the preset output voltage, connect

FB to REF and connect OUT to the output (Figure 3). In

this case, the output voltage is sensed by OUT.

For an adjustable output (Figures 3 and 4), connect an

external resistor divider from the output voltage to FB,

and from FB to REF. In this case, the divided-down

output voltage is sensed via the FB pin.

There are three reasons to use the external resistor divider:

1) You desire an output voltage other than a preset

value

2) The input-to-output differential exceeds 21V

or

3) The output voltage (VOUT to GND) exceeds -15V.

For adjustable operation, refer to Figures 3 and 4. The

impedance of the feedback network should be low

enough that the input bias current of FB is not a factor.

For best efficiency and precision, allow 10µA to flow

through the network. Calculate (VREF - VFB) / R1 =

10µA. Since VREF = 1.5V and VFB = 0V, R1 becomes

150kΩ. Then calculate R2 as follows:

_R_2_ = _V__O_U__T_

R1 VREF

(or, _V_O__U_T_= 10µA)

R2

______________________________________________________________________________________ 11

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