LX1669 查看數據表（PDF） - Microsemi Corporation

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LX1669

PROGRAMMABLE DC : DC CONTROLLER

Microsemi Corporation 

PRODUCT DATABOOK 1996/1997

PROGRAMMABLE DC:DC CONTROLLER

PR O D U C T I O N D ATA S H E E T

LX1669

APPLICATION INFORMATION

OUTPUT CAPACITOR (continued)

excursion in the transient. Adaptive voltage positioning in-

creases the value of VEX, allowing a higher ESR value and

reducing the cost of the output capacitor. The positioning

voltage is 40mV (peak), using the LX1669, and the transient

tolerance is 100mV, resulting in a VEX of 140mV (see Figure 4).

Electrolytic capacitors can be used for the output capacitor,

but are less stable with age than tantalum capacitors. As they age,

their ESR degrades, reducing the system performance and

increasing the risk of failure. It is recommended that multiple

parallel capacitors be used, so that, as ESR increases with age,

overall performance will still meet the processor’s requirements.

There is frequently strong pressure to use the least expensive

components possible, however, this could lead to degraded

long-term reliability, especially in the case of filter capacitors.

Linfinity’s demonstration boards use Sanyo MV-GX filter capaci-

tors, which are aluminum electrolytic, and have demonstrated

reliability. The Oscon series from Sanyo generally provides the

very best performance in terms of long term ESR stability and

general reliability, but at a substantial cost penalty. The MV-GX

series provides excellent ESR performance at a reasonable cost.

Beware of off-brand, very low-cost filter capacitors, which have

been shown to degrade in both ESR and general electrolytic

characteristics over time.

INPUT CAPACITOR

The input capacitor and the input inductor are to filter the

pulsating current generated by the buck converter to reduce

interference to other circuits connected to the same 5V rail. In

addition, the input capacitor provides local de-coupling the buck

converter. The capacitor should be rated to handle the RMS

current requirement. The RMS current is:

IRMS = IL √ d(1-d)

where IL is the inductor current and the d is the duty cycle. The

maximum value, when d = 50%, IRMS = 0.5IL. For 5V input and

output in the range of 2 to 3V, the required RMS current is very

close to 0.5IL.

A high-frequency (ceramic) capacitor should be placed

across the drain of the top MOSFET and the source of the bottom

one to avoid ringing due to the parasitic inductor being switched

ON and OFF. See capacitor C7 in the Product Highlight.

SOFT-START CAPACITOR

The value of the soft-start capacitor determines how fast the

output voltage rises and how large the inductor current is

required to charge the output capacitor. The output voltage will

follow the voltage at SS pin if the required inductor current does

not exceed the maximum current in the inductor.

SOFT-START CAPACITOR (continued)

The SS pin voltage can be expressed as:

VSS = VSET (1-e-t/RssCss)

where VSET is the output of the DAC. RSS and CSS are soft start

resistor and capacitor, as shown in Figure 3. The required

inductor current for the output capacitor to follow the SS-pin

voltage equals the required capacitor current plus the load

current. The soft-start capacitor should be selected so that the

overall inductor current does not exceed it maximum.

The capacitor current to follow the SS-pin voltage is:

dV

ICout = COUT dt

= COUT * e-(t/RssCss )

CSS

where COUT is the output capacitance. The typical value of

CSS should be in the range of 0.1 to 0.2µF.

During the soft-start interval, before the PWRGD signal

becomes valid, the load current from a microprocessor is

negligible; therefore, the capacitor current is approximately the

required inductor current.

CURRENT LIMIT

Current limiting occurs when a sensed voltage, proportional to

load current, exceeds the current-sense comparator threshold

value. The current can be sensed either by using a fixed sense

resistor in series with the inductor to cause a voltage drop

proportional to current, or by using a resistor and capacitor in

parallel with the inductor to sense the voltage drop across the

parasitic resistance of the inductor. The LX1669 has a threshold

of 60mV.

Sense Resistor

The current sense resistor, RSENSE, is selected according to the

formula:

RSENSE = VTRIP / ITRIP

Where VTRIP is the current sense comparator threshold (60mV)

and ITRIP is the desired current limit. Typical choices are shown

below.

TABLE 2 - Current Sense Resistor Selection Guide

Load

Sense Resistor

Value

Pentium-Class Processor (<10A)

Pentium II Class (>10A)

5mΩ

2.5mΩ

A smaller sense resistor will result in lower heat dissipation

(I²R) and also a smaller output voltage droop at higher currents.

Copyright © 1999

Rev. 1.0 4/99

11

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