SI9166 Vishay, SI9166 Datasheet - Page 7

SI9166

Manufacturer Part Number

SI9166

Description

High Frequency Programmable Topology Controller

Manufacturer

Vishay

Datasheet

1.SI9166.pdf (9 pages)

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Part Number:

SI9166BQ-T1

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PWM Mode

With PWM/PSM mode pin in logic high condition, the Si9166

operates in constant frequency (PWM) mode. As the load and

line varies, switching frequency remain constant.

switching frequency is programmed by the R

PWM mode, the synchronous drive is always enabled, even

when the output current reaches 0 A. Therefore, the converter

always operates in continuous conduction mode (CCM) if a

synchronous switch is used. In CCM, transfer function of the

converter remains almost constant, providing fast transient

response.

conduction mode (DCM), overall loop gain decreases and

transient response time can be ten times longer than if the

converter remain in continuous current mode. This transient

response time advantage can significantly decrease the

hold-up capacitors needed on the output of dc/dc converter to

meet the transient voltage regulation. The PWM/PSM pin is

available to dynamically program the controller.

synchronous rectifier switch is not used, the converter will

operate in DCM at light load.

The maximum duty cycle of the Si9166 can reach 100% in

buck mode. The duty cycle will continue to increase as the

input voltage decreases until it reaches 100%. This allows the

system designers to extract the maximum stored energy from

the battery. Once the controller delivers 100% duty cycle, the

converter operates like a saturated linear regulator. At 100%

duty cycle, synchronous rectification is completely turned off.

Up to 80% maximum duty cycle at 2-MHz switching frequency,

the controller maintains perfect output voltage regulation. If the

input voltage drops below the level where the converter

requires greater than 80% duty cycle, the controller will deliver

100% duty cycle. This instantaneous jump in duty cycle is due

to fixed BBM time, MOSFET delay/rise/fall time, and the

internal propagational delays. In order to maintain regulation,

controller might fluctuate its duty cycle back and forth from

100% to something lower than 80% while the converter is

operating in this input voltage range. If the input voltage drops

further, controller will remain on 100%. If the input voltage

increases to a point where it’s requiring less than 80% duty

cycle, synchronous rectification is once again activated.

The maximum duty cycle under boost mode is internally limited

to 70% to prevent inductor saturation. If the converter is turned

on for 100% duty cycle, inductor never gets a chance to

discharge its energy and eventually saturate. In boost mode,

synchronous rectifier is always turned on for minimum or

greater duration as long as the switch has been turned on. The

controller will deliver 0% duty cycle, if the input voltage is

greater than the programmed output voltage. Because of

signal propagation time and MOSFET delay/rise/fall time,

controller will not transition smoothly from minimum

controllable duty cycle to 0% duty cycle.

controller may decrease its duty cycle from 5% to 0% abruptly,

instead of gradual decrease you see from 70% to 5%.

Document Number: 70847

S-40701—Rev. C, 19-Apr-04

If the converter operates in discontinuous

OSC

For example,

value. In the

If the

The

Pulse Skipping Mode

The gate charge losses produced from the Miller capacitance

of MOSFETs are the dominant power dissipation parameter

during light load (i.e. < 10 mA). Therefore, less gate switching

will improve overall converter efficiency. This is exactly why

the Si9166 is designed with pulse skipping mode. If the

PWM/PSM pin is connected to logic low level, converter

operates in pulse skipping modulation (PSM) mode. During

the pulse skipping mode, quiescent current of the controller is

decreased to approximately 200 mA, instead of 500 mA during

the PWM mode. This is accomplished by turning off most of

internal control circuitry and utilizing a simple constant on-time

control with feedback comparator. The controller is designed

to have a constant on-time and a minimum off-time acting as

the feedback comparator blanking time. If the output voltage

drops below the desired level, the main switch is first turned on

and then off. If the applied on-time is insufficient to provide the

desired voltage, the controller will force another on and off

sequence, until the desired voltage is accomplished. If the

applied on-time forces the output to exceed the desired level,

as typically found in the light load condition, the converter stays

off. The excess energy is delivered to the output slowly, forcing

the converter to skip pulses as needed to maintain regulation.

The on-time and off-time are set internally based on inductor

used (1.5-mH typical), MODE pin selection and maximum load

current.

ranging from 0 to near 100% is possible depending on whether

buck or boost is chosen. In pulse skipping mode, synchronous

rectifier drive is also disabled to further decrease the gate

charge loss and increase overall converter efficiency.

Reference

The reference voltage for the Si9166 is set at 1.3 V. The

reference voltage is internally connected to the non-inverting

inputs of the error amplifier. The reference pin requires 0.1-mF

decoupling capacitor.

Error Amplifier

The error amplifier gain-bandwidth product and slew rate are

critical parameters which determines the transient response of

converter. The transient response is function of both small and

large signal responses.

determined by the feedback compensation network while the

large signal is determined by the error amplifier dv/dt and the

inductor di/dt slew rate. Besides the inductance value, error

amplifier determines the converter response time. In order to

minimize the response time, the Si9166 is designed with

2-MHz error amplifier gain-bandwidth product to generate the

widest converter bandwidth and 3.5 V/msec slew rate for

ultra-fast large signal response.

Therefore, with this control method, duty cycle

The small signal response is

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Si9166

SI9166 Vishay, SI9166 Datasheet - Page 7

SI9166

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