LM3481EVAL/NOPB National Semiconductor, LM3481EVAL/NOPB Datasheet - Page 9

LM3481EVAL/NOPB

Manufacturer Part Number

LM3481EVAL/NOPB

Description

EVAL BOARD FOR LM3481

Manufacturer

National Semiconductor

Datasheet

1.LM3481EVALNOPB.pdf (22 pages)

Specifications of LM3481EVAL/NOPB

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

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OVER VOLTAGE PROTECTION

The LM3481 has over voltage protection (OVP) for the output

voltage. OVP is sensed at the feedback pin (FB). If at anytime

the voltage at the feedback pin rises to V

triggered. See the electrical characteristics section for limits

on V

OVP will cause the drive pin (DR) to go low, forcing the power

MOSFET off. With the MOSFET off, the output voltage will

drop. The LM3481 will begin switching again when the feed-

back voltage reaches V

trical characteristics section for limits on V

The internal bias of the LM3481 comes from either the internal

bias voltage generator as shown in the block diagram or di-

rectly from the voltage at the VIN pin. At input voltages lower

than 6V the internal IC bias is the input voltage and at voltages

above 6V the internal bias voltage generator of the LM3481

provides the bias.

SLOPE COMPENSATION RAMP

The LM3481 uses a current mode control scheme. The main

advantages of current mode control are inherent cycle-by-cy-

cle current limit for the switch and simpler control loop char-

acteristics. It is easy to parallel power stages using current

mode control since current sharing is automatic. However

there is a natural instability that will occur for duty cycles, D,

greater than 50% if additional slope compensation is not ad-

dressed as described below.

The current mode control scheme samples the inductor cur-

rent, I

nally generated control signal, V

current, I

The rising and falling slopes, M

samp

SEN

such that:

, as shown in

are also proportional to the inductor current rising and

, and compares the sampled signal, V

and V

, to the voltage signal, V

OVP

Figure

samp

+ (V

5, converts the sampled inductor

= I

OVP

x R

. The current sense resistor,

samp

- V

and −M

SEN

FIGURE 1. Basic Operation of the PWM comparator

OVP(HYS)

, that is proportional to

OVP(HYS)

+ V

respectively, of

). See the elec-

samp

OVP

, to a inter-

, OVP is

falling slopes, M

inductor slope during the switch on-time and −M

ductor slope during the switch off-time and are related to M

and −M

For the boost topology:

Current mode control has an inherent instability for duty cy-

cles greater than 50%, as shown in

signal slope, M

the load current causes the sampled signal to increase by

ΔV

of the first switching cycle is :

From the above equation, when D > 0.5, ΔV

greater than ΔV

vergent. So a very small perturbation in the load will cause

the disturbance to increase. To ensure that the perturbed sig-

nal converges we must maintain:

samp0

. The effect of this load change, ΔV

by:

−M

, equals zero. In

samp0

−M

= [(V

and −M

= [(V

−M

. In other words, the disturbance is di-

off

= [V

OUT

= (V

= M

= −M

− V

off

− V

= V

respectively. Where M

/ L] x R

OUT

off

− V

x R

Figure

) / L] x R

x R

) / L] x R

/ L

OUT

Figure

SEN

) / L

2, a small increase in

2, where the control

SEN

samp1

www.national.com

20136507

, at the end

off

is the in-

will be

is the

LM3481EVAL/NOPB National Semiconductor, LM3481EVAL/NOPB Datasheet - Page 9

LM3481EVAL/NOPB

Specifications of LM3481EVAL/NOPB

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