lm22680mrx-adj National Semiconductor Corporation, lm22680mrx-adj Datasheet - Page 10

lm22680mrx-adj

Manufacturer Part Number

lm22680mrx-adj

Description

2a Simple Switcher ?step-down Voltage Regulator With Features

Manufacturer

National Semiconductor Corporation

Datasheet

1.LM22680MRX-ADJ.pdf (16 pages)

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Thermal Protection

Internal Thermal Shutdown circuitry protects the LM22680 in

the event the maximum junction temperature is exceeded.

When activated, typically at 150°C, the regulator is forced into

a low power reset state. There is a typical hysteresis of 15

degrees.

Internal Compensation

The LM22680 has internal compensation designed for a sta-

ble loop with a wide range of external power stage compo-

nents.

Insuring stability of a design with a specific power stage (in-

ductor and output capacitor) can be tricky. The LM22680

stability can be verified over varying loads and input and out-

put voltages using WEBENCH® Designer online circuit sim-

ulation tool at www.national.com. A quick start spreadsheet

can also be downloaded from the online product folder.

The typical location of the internal compensation poles and

zeros as well as the DC gain is given in Table 1. The LM22680

has internal type III compensation allowing for the use of most

output capacitors including ceramics.

This information can be used to calculate the transfer function

from the FB pin to the internal compensation node (input to

the PWM comparator in the block diagram).

For the power stage transfer function the standard voltage

mode formulas for the double pole and the ESR zero apply:

The peak ramp level of the oscillator signal feeding into the

PWM comparator is V

this modulator stage of the IC. The LM22680 has a compen-

sation tranfer function gain of 37.5dB.

Generally, calculation as well as simulation can only aid in

selecting good power stage components. A good design prac-

tice is to test for stability with load transient tests or loop

measurement tests. Application note AN-1889 shows how to

easily perform a loop transfer function measurement with only

an oscilloscope and a function generator.

Application Information

EXTERNAL COMPONENTS

The following design procedures can be used to design a non-

synchronous buck converter with the LM22680.

Corners

DC gain

Zero 1

Zero 2

Pole 1

Pole 2

Pole 3

/10 which equals a gain of 20dB of

TABLE 1.

Frequency

150 kHz

250 kHz

1.5 kHz

37.5 dB

100 Hz

15 kHz

Inductor

The inductor value is determined based on the load current,

ripple current, and the minimum and maximum input voltage.

To keep the application in continuous current conduction

mode (CCM), the maximum ripple current, I

less than twice the minimum load current.

The general rule of keeping the inductor current peak-to-peak

ripple around 30% of the nominal output current is a good

compromise between excessive output voltage ripple and ex-

cessive component size and cost. Using this value of ripple

current, the value of inductor, L, is calculated using the fol-

lowing formula:

where F is the switching frequency which is 500 kHz without

an external frequency set resistor or external sync signal ap-

plied to the RT/SYNC pin. If the switching frequency is set

higher than 500kHz, the inductance value may not be reduced

accordingly due to stability requirements. The internal com-

pensation is optimized for circuits with a 500 kHz switching

frequency. See the internal compensation section for more

details. This procedure provides a guide to select the value of

the inductor L. The nearest standard value will then be used

in the circuit.

Increasing the inductance will generally slow down the tran-

sient response but reduce the output voltage ripple amplitude.

Reducing the inductance will generally improve the transient

response but increase the output voltage ripple.

The inductor must be rated for the peak current, I

vent saturation. During normal loading conditions, the peak

current occurs at maximum load current plus maximum ripple.

Under an overload condition as well as during load transients,

the peak current is limited to 2.8A typical (3.4A maximum).

This requires that the inductor be selected such that it can run

at the maximum current limit and not only the steady state

current.

Depending on inductor manufacturer, the saturation rating is

defined as the current necessary for the inductance to reduce

by 30% at 20°C. In typical designs the inductor will run at

higher temperatures. If the inductor is not rated for enough

current, it might saturate and due to the propagation delay of

the current limit circuitry, the power supply may get damaged.

Input Capacitor

Good quality input capacitors are necessary to limit the ripple

voltage at the VIN pin while supplying most of the switch cur-

rent during on-time. When the switch turns on, the current into

the VIN pin steps to the peak value, then drops to zero at turn-

off. The average current into VIN during switch on-time is the

load current. The input capacitance should be selected for

RMS current, I

proximation for the required ripple current rating necessary is

Quality ceramic capacitors with a low ESR should be selected

for the input filter. To allow for capacitor tolerances and volt-

age effects, multiple capacitors may be used in parallel. If step

input voltage transients are expected near the maximum rat-

ing of the LM22680, a careful evaluation of ringing and pos-

sible voltage spikes at the VIN pin should be completed. An

additional damping network or input voltage clamp may be

required in these cases.

Usually putting a higher ESR electrolytic input capacitor in

parallel to the low ESR bypass capacitor will help to reduce

RMS

> I

OUT

/ 2.

RMS

, and minimum ripple voltage. A good ap-

RIPPLE

, should be

PK+

, to pre-

lm22680mrx-adj National Semiconductor Corporation, lm22680mrx-adj Datasheet - Page 10

lm22680mrx-adj

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