EL7562CU-T13 INTERSIL [Intersil Corporation], EL7562CU-T13 Datasheet - Page 8

EL7562CU-T13

Manufacturer Part Number

EL7562CU-T13

Description

Monolithic 2Amp DC-DC Step-Down Regulator

Manufacturer

INTERSIL [Intersil Corporation]

Datasheet

1.EL7562CU-T13.pdf (9 pages)

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will approach a one-pole system. The resulting system offers

several advantages over traditional voltage control systems,

including simpler loop compensation, pulse by pulse current

limiting, rapid response to line variation and good load step

response.

The heart of the controller is an input direct summing

comparator which sum voltage feedback, current feedback,

slope compensation ramp and power tracking signals

together. Slope compensation is required to prevent system

instability that occurs in current-mode topologies operating

at duty-cycles greater than 50% and is also used to define

the open-loop gain of the overall system. The slope

compensation is fixed internally and optimized for 500mA

inductor ripple current. The power tracking will not contribute

any input to the comparator steady-state operation. Current

feedback is measured by the patented sensing scheme that

senses the inductor current flowing through the high-side

switch whenever it is conducting. At the beginning of each

oscillator period the high-side NMOS switch is turned on.

The comparator inputs are gated off for a minimum period of

time of about 150ns (LEB) after the high-side switch is

turned on to allow the system to settle. The Leading Edge

Blanking (LEB) period prevents the detection of erroneous

voltages at the comparator inputs due to switching noise. If

the inductor current exceeds the maximum current limit

the high-side switch on time. If I

the feedback voltage FB derived from the regulator output

voltage V

reference voltage. The resultant error voltage is summed

with the current feedback and slope compensation ramp.

The high-side switch remains on until all four comparator

inputs have summed to zero, at which time the high-side

switch is turned off and the low-side switch is turned on.

However, the maximum on-duty ratio of the high-side switch

is limited to 95%. In order to eliminate cross-conduction of

the high-side and low-side switches a 15ns break-before-

make delay is incorporated in the switch drive circuitry. The

output enable (EN) input allows the regulator output to be

disabled by an external logic control signal.

Output Voltage Setting

In general:

However, due to the relatively low open loop gain of the

system, gain errors will occur as the output voltage and loop-

gain is changed. This is shown in the performance curves. A

LMAX

) a secondary over-current comparator will terminate

OUT

is then compared to the internal feedback

OUT

For V

0.985

0.975

= 3.3V

= 5V

LMAX













has not been reached,

------ -













100nA pull-up current from FB to V

in the event that FB is floating.

NMOS Power FETs and Drive Circuitry

The EL7562 integrates low on-resistance (60mΩ) NMOS

FETs to achieve high efficiency at 2A. In order to use an

NMOS switch for the high-side drive it is necessary to drive

the gate voltage above the source voltage (LX). This is

accomplished by bootstrapping the V

voltage with an external capacitor C

and diode. When the low-side switch is turned on and the LX

voltage is close to GND potential, capacitor C

through internal switch to V

beginning of the next cycle the high-side switch turns on and

the LX pins begin to rise from GND to V

LX pin rises the positive plate of capacitor C

eventually reaches a value of V

drive the gate of the high-side FET, via the V

of 0.1µF for C

Reference

A 1.5% temperature compensated bandgap reference is

integrated in the EL7562. The external V

as the dominant pole of the amplifier and can be increased

in size to maximize transient noise rejection. A value of

0.1µF is recommended.

Oscillator

The system clock is generated by an internal relaxation

oscillator with a maximum duty-cycle of approximately 95%.

Operating frequency can be adjusted through the C

or can be driven by an external source. If the oscillator is

driven by an external source care must be taken in selecting

the ramp amplitude. Since C

gain of the system.

When external synchronization is required, always choose

lower than that of sync source to accommodate component

DRV

OSC

SLOPE

OSC

ramp, changes to C

such that the free-running frequency is at least 20%

compensation ramp which determine the open-loop

=5V. This voltage is then level shifted and used to

VHI

is recommended.

OSC

DRV

SLOPE

, typically 5V. At the

DRV

ramp will change the

value is derived from the

VHI

forces V

pin above the LX

and internal switch

, typically 10V, for

REF

potential. As the

VHI

capacitor acts

OUT

pin. A value

follows and

is charged

OSC

to GND

EL7562CU-T13 INTERSIL [Intersil Corporation], EL7562CU-T13 Datasheet - Page 8

EL7562CU-T13

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