SI9135 Datasheet, PDF(13/14 Page) Vishay Siliconix – SMBus Multi-Output Power-Supply Controller

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SI9135 Datasheet, PDF (13/14 Pages) Vishay Siliconix – SMBus Multi-Output Power-Supply Controller

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Si9135

Vishay Siliconix

Normal Operation: Buck Converters

In normal operation, the buck converter high-side MOSFET is

turned on with a delay (known as break-before-make time -

tBBM), after the rising edge of the clock. After a certain on

time, the high-side MOSFET is turned off and then after a

delay (tBBM), the low-side MOSFET is turned on until the next

rising edge of the clock, or the inductor current reaches zero.

The tBBM (approximately 25 ns to 60 ns), has been optimized

to guarantee the efficiency is not adversely affected at the

high switching frequency and a specified minimum to account

for variations of possible MOSFET gate capacitances.

During the normal operation, the high-side MOSFET switch

on-time is controlled internally to provide excellent line and

load regulation over temperature. Both buck converters

should have load, line, regulation to within 0.5% tolerance.

Pulse Skipping: Buck Converters

When the buck converter switching frequency is less than the

internal clock frequency, its operation mode is defined as

pulse skipping mode. During this mode, the high-side

MOSFET is turned on until VCS-VFB reaches 20 mV, or the on

time reaches its maximum duty ratio. After the high-side

MOSFET is turned off, the low-side MOSFET is turned on

after the tBBM delay, which will remain on until the inductor

current reaches zero. The output voltage will rise slightly

above the regulation voltage after this sequence, causing the

controller to stay idle for the next one, or several clock cycles.

When the output voltage falls slightly below the regulation

level, the high-side MOSFET will be turned on again at the

next clock cycle. With the converter remaining idle during

some clock cycles, the switching losses are reduced in order

to preserve conversion efficiency during the light output

current condition.

Current Limit: Buck Converters

When the buck converter inductor current is too high, the

voltage across pin CS3(5) and pin FB3(5) exceeds

approximately 120 mV, the high-side MOSFET would be

turned off instantaneously regardless of the input, or output

condition. The Si9135 features clock cycle by clock cycle

current limiting capability.

Flyback Converter Operation

Designed mainly for PCMCIA or EEPROM programming, the

Si9135 has a 12-V output non-isolated buck boost converter,

called for brevity a flyback. It consists of two n-channel

MOSFET switches that are turned on and off in phase, and

two diodes. Similar to the buck converter, during the light load

conditions, the flyback converter will switch at a frequency

lower than the internal clock frequency, which can be defined

as pulse skipping mode (PSM); otherwise, it is operating in

normal PWM mode.

Normal Operation: Flyback Converter

In normal operation mode, the two MOSFETs are turned on at

the rising edge of the clock, and then turned off. The on time

is controlled internally to provide excellent load, line, and

temperature regulation. The flyback converter has load, line

and temperature regulation well within 0.5%.

Pulse Skipping: Flyback Converter

Under the light load conditions, similar to the buck converter,

the flyback converter will enter pulse skipping mode. The

MOSFETs will be turned on until the inductor current

increases to such a level that the voltage across the pin CSP

and pin CSN reaches 100 mV, or the on time reaches the

maximum duty cycle. After the MOSFETs are turned off, the

inductor current will conduct through two diodes until it

reaches zero. At this point, the flyback converter output will

rise slightly above the regulation level, and the converter will

stay idle for one or several clock cycle(s) until the output falls

back slightly below the regulation level. The switching losses

are reduced by skipping pulses and so the efficiency during

light load is preserved.

Current Limit: Flyback Converter

Similar to the buck converter; when the voltage across pin

CSP and pin CSN exceeds 410-mV typical, the two

MOSFETs will be turned off regardless of the input and

output conditions.

SMBus Commands

After completion of startup, Si9135âs converters can be

individually or as a group commanded on or off using a code

word on the SMBus, as detailed in the SMBus Truth Table.

The command sequence is:

A. Receive a start bit, which is a falling edge on the

SDA line while the SCL line is high.

B. Receive a one-byte address, which for Si9135 is

01100000.

C. Send an acknowledge bit.

D. Receive a one-byte command.

E. Send an acknowledge bit.

F. Receive a stop bit, which is a rising edge on the SDA

line while the SCL line is high.

This is a total of 20 bits, which at the maximum clock

frequency of 100 kHz translates into 200 Âµsec before any

change in the status of Si9135 ban be accomplished.

If Si9135 receives a command to turn on (respectively, off) a

converter that is already on (respectively, off) it shall not

falsely command the converter off (respectively, on).

Si9135 must be able to receive a stop command at any time

during a command sequence. If Si9135 receives a stop

command during a command sequence, it must not change

the state of any converter, and must be ready to receive the

next command sequence.

FaxBack 408-970-5600, request 70817

www.siliconix.com

S-60752âRev. B, 05-Apr-99

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