MIC2169A Datasheet, PDF(7/17 Page) Micrel Semiconductor – 500kHz PWM Synchronous Buck Control IC

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MIC2169A Datasheet, PDF (7/17 Pages) Micrel Semiconductor – 500kHz PWM Synchronous Buck Control IC

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MIC2169A

is reduced to 8.5ÂµA and the COMP pin voltage rises from

0.65V to 0.95V, the bottom edge of the saw-tooth oscillator.

This is the beginning of 0% duty cycle and it increases slowly

causing the output voltage to rise slowly. The MIC2169A has

two hysteretic comparators that are enabled when VOUT is

within Â±3% of steady state. When the output voltage reaches

97% of programmed output voltage then the gm error ampliï¬er

is enabled along with the hysteretic comparator. This point

onwards, the voltage control loop (gm error ampliï¬er) is fully

in control and will regulate the output voltage.

Soft-start time can be calculated approximately by adding

the following four time frames:

t1 = Cap_COMP Ã 0.18V/8.5ÂµA

t2 = 12 bit counter, approx 2ms

t3 = Cap_COMP Ã 0.3V/8.5ÂµA

ï½

ï¦

ï¨ï§

VOUT

VIN

ï¶

ï¸ï·

ï´

0.5

ï´

Cap_COMP

8.5 ïA

Soft-Start Time(Cap_COMP=100nF) = t1 + t2 + t3 +

t4 = 2.1ms + 2ms + 3.5ms + 1.8ms = 10ms

Current Limit

The MIC2169A uses the RDS(ON) of the top power MOSFET

to measure output current. Since it uses the drain to source

resistance of the power MOSFET, it is not very accurate. This

scheme is adequate to protect the power supply and external

components during a fault condition by cutting back the time

the top MOSFET is on if the feedback voltage is greater than

0.67V. In case of a hard short when feedback voltage is less

than 0.67V, the MIC2169A discharges the COMP capacitor

to 0.65V, resets the digital counter and automatically shuts

off the top gate drive, and the gm error ampliï¬er and the

â3% hysteretic comparators are completely disabled and the

soft-start cycles restarts. This mode of operation is called the

âhiccup modeâ and its purpose is to protect the down stream

load in case of a hard short. The circuit in Figure 1 illustrates

the MIC2169A current limiting circuit.

VIN

CIN

0.1ÂµF

VSW

HSD

2â¦

RCS

LSD

MOSFET N

L1 Inductor

1.4â¦

1000pF

VOUT

COUT

200ïA

Figure 1. The MIC2169A Current Limiting Circuit

The current limiting resistor RCS is calculated by the follow-

ing equation:

Micrel

RCS

ï½

R ï´ DS(ON) Q1

200ïA

Equation (1)

ï½ I LOAD

ï« 2ï¨Inductor

Ripple

Currentï©

where:

Inductor Ripple Current =

ï¨ ï© VOUT

ï´

VIN

VIN â VOUT

ï´ FSWITCHING

ï´

FSWITCHING = 500kHz

200ÂµA is the internal sink current to program the

MIC2169A current limit.

The MOSFET RDS(ON) varies 30% to 40% with temperature;

therefore, it is recommended to add a 50% margin to the load

current (ILOAD) in the above equation to avoid false current

limiting due to increased MOSFET junction temperature rise.

It is also recommended to connect RCS resistor directly to

the drain of the top MOSFET Q1, and the RSW resistor to the

source of Q1 to accurately sense the MOSFETs RDS(ON). To

make the MIC2169A insensitive to board layout and noise

generated by the switch node, a 1.4â¦ resistor and a 1000pF

capacitor is recommended between the switch node and GND.

A 0.1ÂµF capacitor in parallel with RCS should be connected

to ï¬lter some of the switching noise.

Internal VDD Supply

The MIC2169A controller internally generates VDD for self bias-

ing and to provide power to the gate drives. This VDD supply

is generated through a low-dropout regulator and generates

5V from VIN supply greater than 5V. For supply voltage less

than 5V, the VDD linear regulator is approximately 200mV

in dropout. Therefore, it is recommended to short the VDD

supply to the input supply through a 10â¦ resistor for input

supplies between 2.9V to 5V.

MOSFET Gate Drive

The MIC2169A high-side drive circuit is designed to switch an

N-Channel MOSFET. The block diagram on page 6 shows a

bootstrap circuit, consisting of D1 and CBST, supplies energy

to the high-side drive circuit. Capacitor CBST is charged while

the low-side MOSFET is on and the voltage on the VSW pin

is approximately 0V. When the high-side MOSFET driver is

turned on, energy from CBST is used to turn the MOSFET

on. As the MOSFET turns on, the voltage on the VSW pin

increases to approximately VIN. Diode D1 is reversed biased

and CBST ï¬oats high while continuing to keep the high-side

MOSFET on. When the low-side switch is turned back on,

CBST is recharged through D1. The drive voltage is derived

from the internal 5V VDD bias supply. The nominal low-side

gate drive voltage is 5V and the nominal high-side gate drive

voltage is approximately 4.5V due the voltage drop across D1.

An approximate 20ns delay between the high- and low-side

driver transitions is used to prevent current from simultane-

ously ï¬owing unimpeded through both MOSFETs.

MOSFET Selection

The MIC2169A controller works from input voltages of 3V to

13.2V and has an internal 5V regulator to provide power to

turn the external N-Channel power MOSFETs for high- and

June 2005

M9999-111803

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