MIC2184YM TR Micrel Inc, MIC2184YM TR Datasheet - Page 11

MIC2184YM TR

Manufacturer Part Number

MIC2184YM TR

Description

SO-16 Low Vin Buck PWM Control IC ( )

Manufacturer

Micrel Inc

Datasheet

1.MIC2184YQS.pdf (12 pages)

Specifications of MIC2184YM TR

Pwm Type

Current Mode

Number Of Outputs

Frequency - Max

440kHz

Duty Cycle

100%

Voltage - Supply

2.9 V ~ 14 V

Buck

Yes

Boost

Flyback

Inverting

Doubler

Divider

Cuk

Isolated

Operating Temperature

-40°C ~ 125°C

Package / Case

16-SOIC (3.9mm Width)

Frequency-max

440kHz

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Other names

MIC2184YMTR
MIC2184YMTR

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fied free running frequency of the MIC2184. If the synchroniz-

ing frequency is lower, double pulsing of the gate drive

outputs will occur. When not used, the sync pin must be

connected to ground.

The maximum recommended output switching frequency is

600kHz. Synchronizing to higher frequencies may be pos-

sible, however, higher power dissipation in the internal gate

drive circuits will occur. The MOSFET gates require charge

to turn on the device. The average current required by the

MOSFET gate increases with switching frequency.

Soft Start

Soft start reduces the power supply input surge current at

start up by controlling the output voltage risetime. The input

surge appears while the output capacitance is charged up. A

slower output risetime will draw a lower input surge current.

Soft start may also be used for power supply sequencing.

The soft start voltage is applied directly to the PWM compara-

tor. A 5µA internal current source is used to charge up the soft

start capacitor. The capacitor is discharged when either the

enable pin voltage drops below the standby threshold or the

The part switches at a low duty cycle when the soft start pin

voltage is zero. As the soft start voltage rises from 0V to 0.7V,

the duty cycle increases from the minimum duty cycle to the

operating duty cycle. The oscillator runs at the foldback

frequency (1/4 of the switching frequency) until the feedback

voltage rises above 0.3V. The risetime of the output is

dependent of the soft start capacitor output capacitance,

input and output voltage and load current.

Voltage Setting Components

The MIC2184 requires two resistors to set the output voltage

as shown in Figure 5.

The output voltage is determined by the equation below.

Where: V

Lower values of R1 are preferred to prevent noise from

appearing on the FB pin. A typically recommended value is

10kΩ. If R1 is too small in value it will decrease the efficiency

of the power supply, especially at low output loads.

Once R1 is selected, R2 can be calculated with the following

formula.

April 2005

MIC2184

voltage drops below its UVLO level.

OUT

REF

OUT

REF

for the MIC2184 is typically 1.245V.

REF

× +

REF

Amplifier

MIC2184

Voltage

1.245V

Figure 5

REF

Pin 6

OUT

Efficiency Considerations

Efficiency is the ratio of output power to input power. The

difference is dissipated as heat in the buck converter. Under

light output load, the significant contributors are:

To maximize efficiency at light loads:

Under heavy output loads the significant contributors to

power loss are (in approximate order of magnitude):

To minimize power loss under heavy loads:

• The V

• Core losses in the output inductor

• Use a low gate charge MOSFET or use the smallest

• Use a ferrite material for the inductor core, which has

• Resistive on time losses in the MOSFET

• Switching transition losses in the MOSFET

• Inductor resistive losses

• Current sense resistor losses

• Input capacitor resistive losses (due to the capacitors

• Use low on resistance MOSFETs. Use low threshold

• Slow transition times and oscillations on the voltage

• For the same size inductor, a lower value will have

• Lowering the current sense resistor value will de

• Use low ESR input capacitors to minimize the power

required to switch the external MOSFET

MOSFET, which is still adequate for maximum output

current.

less core loss than an MPP or iron power core.

ESR)

logic level MOSFETs when the input voltage is below

5V. Multiplying the gate charge by the on resistance

gives a figure of merit, providing a good balance

between low load and high load efficiency.

and current waveforms dissipate more power during

the turn on and turn off of the MOSFET. A clean

layout will minimize parasitic inductance and capaci

tance in the gate drive and high current paths. This

will allow the fastest transition times and waveforms

without oscillations. Low gate charge MOSFETs will

transition faster than those with higher gate charge

requirements.

fewer turns and therefore, lower winding resistance.

However, using too small of a value will require more

output capacitors to filter the output ripple, which will

force a smaller bandwidth, slower transient response

and possible instability under certain conditions.

crease the power dissipated in the resistor. However,

it will also increase the overcurrent limit and will

require larger MOSFETs and inductor components.

dissipated in the capacitors ESR.

A supply current

P supply current, which includes the current

M9999-042205

Micrel, Inc.

MIC2184YM TR Micrel Inc, MIC2184YM TR Datasheet - Page 11

MIC2184YM TR

Specifications of MIC2184YM TR

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