MIC5219-3.3YM5 - Micrel, Inc.

June 2009 1 M0371-061809

Micrel, Inc. MIC5219

Typical Applications

MIC5219

500mA-Peak Output LDO Regulator

General Description

The MIC5219 is an efcient linear voltage regulator with high

peak output current capability, very-low-dropout voltage, and

better than 1% output voltage accuracy. Dropout is typically

10mV at light loads and less than 500mV at full load.

The MIC5219 is designed to provide a peak output current for

start-up conditions where higher inrush current is demanded.

It features a 500mA peak output rating. Continuous output

current is limited only by package and layout.

The MIC5219 can be enabled or shut down by a CMOS or

TTL compatible signal. When disabled, power consumption

drops nearly to zero. Dropout ground current is minimized to

help prolong battery life. Other key features include reversed-

battery protection, current limiting, overtemperature shutdown,

and low noise performance with an ultra-low-noise option.

The MIC5219 is available in adjustable or xed output volt-

ages in the space-saving 6-pin (2mm × 2mm) MLF®, 6-pin

(2mm × 2mm) Thin MLF® SOT-23-5 and MM8® 8-pin power

MSOP packages. For higher power requirements see the

MIC5209 or MIC5237.

All support documentation can be found on Micrel’s web site

at www.micrel.com.

Features

• 500mA output current capability

SOT-23-5 package - 500mA peak

2mm×2mm MLF® package - 500mA continuous

2mm×2mm Thin MLF® package - 500mA

continuous

MSOP-8 package - 500mA continuous

• Low 500mV maximum dropout voltage at full load

• Extremely tight load and line regulation

• Tiny SOT-23-5 and MM8™ power MSOP-8 package

• Ultra-low-noise output

• Low temperature coefcient

• Current and thermal limiting

• Reversed-battery protection

• CMOS/TTL-compatible enable/shutdown control

• Near-zero shutdown current

Applications

• Laptop, notebook, and palmtop computers

• Cellular telephones and battery-powered equipment

• Consumer and personal electronics

• PC Card VCC and VPP regulation and switching

• SMPS post-regulator/DC-to-DC modules

• High-efciency linear power supplies

MIC5219-5.0BMM

2.2µF

tantalum

VOUT5V

VIN 6V

ENABLE

SHUTDOWN

470pF

5V Ultra-Low-Noise Regulator

2.2µF

tantalum

470pF

VOUT3.3V

MIC5219-3.3BM5

VIN 4V

ENABLE

SHUTDOWN

3.3V Ultra-Low-Noise Regulator

Micrel, Inc. • 2180 Fortune Drive • San Jose, CA 95131 • USA • tel + 1 (408) 944-0800 • fax + 1 (408) 474-1000 • http://www.micrel.com

MM8 is a registered trademark of Micrel, Inc.

MicroLeadFrame and MLF are registered trademarks of Amkor Technology, Inc..

ENABLE

SHUTDOWN

MIC5219-x.xYML

EN 6CBYP

(optional)

VIN VOUT

COUT

Ultra-Low-Noise Regulator (Fixed)

ENABLE

SHUTDOWN

MIC5219YMT

EN 6

470pF

VIN VOUT

2.2µF

Ultra-Low-Noise Regulator (Adjustable)

Micrel, Inc. MIC5219

June 2009 2 M0371-061809

Ordering Information

Part Number Marking

Standard Pb-Free Standard Pb-Free* Volts Temp. Range Package

MIC5219-2.5BMM MIC5219-2.5YMM — — 2.5V –40°C to +125°C MSOP-8

MIC5219-2.85BMM MIC5219-2.85YMM — — 2.85V –40°C to +125°C MSOP-8

MIC5219-3.0BMM MIC5219-3.0YMM — — 3.0V –40°C to +125°C MSOP-8

MIC5219-3.3BMM MIC5219-3.3YMM — — 3.3V –40°C to +125°C MSOP-8

MIC5219-3.6BMM MIC5219-3.6YMM — — 3.6V –40°C to +125°C MSOP-8

MIC5219-5.0BMM MIC5219-5.0YMM — — 5.0V –40°C to +125°C MSOP-8

MIC5219BMM MIC5219YMM — — Adj. –40°C to +125°C MSOP-8

MIC5219-2.5BM5 MIC5219-2.5YM5 LG25 LG25 2.5V –40°C to +125°C SOT-23-5

MIC5219-2.6BM5 MIC5219-2.6YM5 LG26 LG26 2.6V –40°C to +125°C SOT-23-5

MIC5219-2.7BM5 MIC5219-2.7YM5 LG27 LG27 2.7V –40°C to +125°C SOT-23-5

MIC5219-2.8BM5 MIC5219-2.8YM5 LG28 LG28 2.8V –40°C to +125°C SOT-23-5

MIC5219-2.8BML MIC5219-2.8YML G28 G28 2.8V –40°C to +125°C 6-Pin 2×2 MLF®

MIC5219-2.85BM5 MIC5219-2.85YM5 LG2J LG2J 2.85V –40°C to +125°C SOT-23-5

MIC5219-2.9BM5 MIC5219-2.9YM5 LG29 LG29 2.9V –40°C to +125°C SOT-23-5

MIC5219-3.1BM5 MIC5219-3.1YM5 LG31 LG31 3.1V –40°C to +125°C SOT-23-5

MIC5219-3.0BM5 MIC5219-3.0YM5 LG30 LG30 3.0V –40°C to +125°C SOT-23-5

MIC5219-3.0BML MIC5219-3.0YML G30 G30 3.0V –40°C to +125°C 6-Pin 2×2 MLF®

MIC5219-3.3BM5 MIC5219-3.3YM5 LG33 LG33 3.3V –40°C to +125°C SOT-23-5

MIC5219-3.3BML MIC5219-3.3YML G33 G33 3.3V –40°C to +125°C 6-Pin 2×2 MLF®

MIC5219-3.6BM5 MIC5219-3.6YM5 LG36 LG36 3.6V –40°C to +125°C SOT-23-5

MIC5219-5.0BM5 MIC5219-5.0YM5 LG50 LG50 5.0V –40°C to +125°C SOT-23-5

MIC5219BM5 MIC5219YM5 LGAA LGAA Adj. –40°C to +125°C SOT-23-5

MIC5219YMT GAA Adj. –40°C to +125°C 6-Pin 2x2 Thin MLF®**

MIC5219-5.0YMT G50 5.0V –40°C to +125°C 6-Pin 2x2 Thin MLF®**

Other voltages available. Consult Micrel for details.

* Over/underbar may not be to scale. ** Pin 1 identier = ▲.

GND

OUT

BYP

MIC5219-x.xBMM / MM8® / MSOP-8

Fixed Voltages

(Top View)

GND

OUT

BYP

MIC5219YMM / MIC5219BMM

MM8® MSOP-8

Adjustable Voltage

(Top View)

OUTBYP

LGxx

4 5

GND

MIC5219-x.xBM5 / SOT-23-5

Fixed Voltages

(Top View)

Part

Identification

OUTADJ

LGAA

GND

MIC5219BM5 / SOT-23-5

Adjustable Voltage

(Top View)

Pin Conguration

1EN

GND

6BYP

OUT

MIC5219-x.xBML

6-Pin 2mm × 2mm MLF® (ML)

(Top View)

1EN

GND

6NC

ADJ

OUT

MIC5219YMT

6-Pin 2mm × 2mm Thin MLF® (MT)

(Top View)

June 2009 3 M0371-061809

Micrel, Inc. MIC5219

Pin Description

Pin No. Pin No. Pin No. Pin Name Pin Function

MLF-6 MSOP-8 SOT-23-5

TMLF-6

3 2 1 IN Supply Input.

2 5–8 2 GND Ground: MSOP-8 pins 5 through 8 are internally connected.

4 3 5 OUT Regulator Output.

1 1 3 EN Enable (Input): CMOS compatible control input. Logic high = enable; logic

low or open = shutdown.

6 4 (xed) 4 (xed) BYP Reference Bypass: Connect external 470pF capacitor to GND to reduce

output noise. May be left open.

5(NC) 4 (adj.) 4 (adj.) ADJ Adjust (Input): Feedback input. Connect to resistive voltage-divider network.

EP — — GND Ground: Internally connected to the exposed pad. Connect externally to

GND pin.

Micrel, Inc. MIC5219

June 2009 4 M0371-061809

Electrical Characteristics(3)

VIN = VOUT + 1.0V; COUT = 4.7µF, IOUT = 100µA; TJ = 25°C, bold values indicate –40°C ≤ TJ ≤ +125°C; unless noted.

Symbol Parameter Conditions Min Typical Max Units

VOUT Output Voltage Accuracy variation from nominal VOUT –1 1 %

–2 2 %

ΔVOUT/ΔT Output Voltage Note 4 40

ppm/°C

Temperature Coefcient

ΔVOUT/VOUT Line Regulation VIN = VOUT + 1V to 12V 0.009 0.05 %/V

0.1

ΔVOUT/VOUT Load Regulation IOUT = 100µA to 500mA, Note 5 0.05 0.5 %

0.7

VIN – VOUT Dropout Voltage(6) I

OUT = 100µA 10 60 mV

OUT = 50mA 115 175 mV

250

OUT = 150mA 175 300 mV

400

OUT = 500mA 350 500 mV

600

IGND Ground Pin Current(7, 8) V

EN ≥ 3.0V, IOUT = 100µA 80 130 µA

170

EN ≥ 3.0V, IOUT = 50mA 350 650 µA

900

EN ≥ 3.0V, IOUT = 150mA 1.8 2.5 mA

3.0

EN ≥ 3.0V, IOUT = 500mA 12 20 mA

Ground Pin Quiescent Current(8) V

EN ≤ 0.4V 0.05 3 µA

EN ≤ 0.18V 0.10 8 µA

PSRR Ripple Rejection f = 120Hz 75 dB

ILIMIT Current Limit VOUT = 0V 700 1000 mA

ΔVOUT/ΔPD Thermal Regulation Note 9 0.05 %/W

eno Output Noise(10) I

OUT = 50mA, COUT = 2.2µF, CBYP = 0 500

nV/ Hz

OUT = 50mA, COUT = 2.2µF, CBYP = 470pF 300

nV/ Hz

ENABLE Input

VENL Enable Input Logic-Low Voltage VEN = logic low (regulator shutdown) 0.4 V

0.18

EN = logic high (regulator enabled) 2.0 V

IENL Enable Input Current VENL ≤ 0.4V 0.01 –1 µA

ENL ≤ 0.18V 0.01 –2 µA

IENH V

ENH ≥ 2.0V 2 5 20 µA

Absolute Maximum Ratings(1)

Supply Input Voltage (VIN) ..............................–20V to +20V

Power Dissipation (PD) ............................. Internally Limited

Junction Temperature (TJ) ........................ –40°C to +125°C

Storage Temperature (TS) ........................ –65°C to +150°C

Lead Temperature (Soldering, 5 sec.) ....................... 260°C

Operating Ratings(2)

Supply Input Voltage (VIN) ............................ +2.5V to +12V

Enable Input Voltage (VEN)....................................0V to VIN

Junction Temperature (TJ) ........................ –40°C to +125°C

Package Thermal Resistance ........................... see Table 1

June 2009 5 M0371-061809

Micrel, Inc. MIC5219

Notes:

1. Absolute maximum ratings indicate limits beyond which damage to the component may occur. Electrical specications do not apply when operating

the device outside of its operating ratings. The maximum allowable power dissipation is a function of the maximum junction temperature, TJ(max),

the junction-to-ambient thermal resistance, θJA, and the ambient temperature, TA. The maximum allowable power dissipation at any ambient

temperature is calculated using: PD(max) = (TJ(max) – TA) ÷ θJA. Exceeding the maximum allowable power dissipation will result in excessive die

temperature, and the regulator will go into thermal shutdown. See Table 1 and the “Thermal Considerations” section for details.

2. The device is not guaranteed to function outside its operating rating.

3. Specication for packaged product only.

4. Output voltage temperature coefcient is dened as the worst case voltage change divided by the total temperature range.

5. Regulation is measured at constant junction temperature using low duty cycle pulse testing. Parts are tested for load regulation in the load range

from 100µA to 500mA. Changes in output voltage due to heating effects are covered by the thermal regulation specication.

6. Dropout voltage is dened as the input to output differential at which the output voltage drops 2% below its nominal value measured at 1V differen-

tial.

7. Ground pin current is the regulator quiescent current plus pass transistor base current. The total current drawn from the supply is the sum of the load

current plus the ground pin current.

8. VEN is the voltage externally applied to devices with the EN (enable) input pin.

9. Thermal regulation is dened as the change in output voltage at a time “t” after a change in power dissipation is applied, excluding load or line regu-

lation effects. Specications are for a 500mA load pulse at VIN = 12V for t = 10ms.

10. CBYP is an optional, external bypass capacitor connected to devices with a BYP (bypass) or ADJ (adjust) pin.

Micrel, Inc. MIC5219

June 2009 6 M0371-061809

Typical Characteristics

-100

-80

-60

-40

-20

1E+1 1E+2 1E+3 1E+4 1E+5 1E+6 1E+7

FREQUENCY (Hz)

Power Supply

Rejection Ratio

IOUT = 100µA

COUT = 1µF

VIN = 6V

VOUT = 5V

10 100 1k 10k 100k 1M 10M

-100

-80

-60

-40

-20

1E+1 1E+2 1E+3 1E+4 1E+5 1E+6 1E+7

FREQUENCY (Hz)

Power Supply

Rejection Ratio

IOUT = 1mA

COUT = 1µF

VIN = 6V

VOUT = 5V

10 100 1k 10k 100k 1M 10M

-100

-80

-60

-40

-20

1E+1 1E+2 1E+3 1E+4 1E+5 1E+6 1E+7

FREQUENCY (Hz)

Power Supply

Rejection Ratio

IOUT = 100mA

COUT = 1µF

VIN = 6V

VOUT = 5V

10 100 1k 10k 100k 1M 10M

-100

-80

-60

-40

-20

1E+1 1E+2 1E+3 1E+4 1E+5 1E+6 1E+7

FREQUENCY (Hz)

Power Supply

Rejection Ratio

IOUT = 100µA

COUT = 2.2µF

CBYP = 0.01µF

VIN = 6V

VOUT = 5V

10 100 1k 10k 100k 1M 10M

-100

-80

-60

-40

-20

1E+1 1E+2 1E+3 1E+4 1E+5 1E+6 1E+7

FREQUENCY (Hz)

Power Supply

Rejection Ratio

IOUT = 1mA

COUT = 2.2µF

CBYP = 0.01µF

VIN = 6V

VOUT = 5V

10 100 1k 10k 100k 1M 10M

0 0.1 0.2 0.3 0.4

VOLTAGE DROP (V)

Power Supply Ripple Rejection

vs. Voltage Drop

IOUT = 100mA

10mA

1mA

COUT = 1µF

100

0 0.1 0.2 0.3 0.4

VOLTAGE DROP (V)

Power Supply Ripple Rejection

vs. Voltage Drop

IOUT = 100mA

10mA

1mA

COUT = 2.2µF

CBYP = 0.01µF

0.0001

0.001

0.01

0.1

1E+1 1E+2 1E+3 1E+4 1E+5 1E+6 1E+7

FREQUENCY (Hz)

Noise Performance

10 100 1k 10k 100k 1M 10M

10mA, C OUT = 1µF

VOUT = 5V

0.0001

0.001

0.01

0.1

1E+1 1E+2 1E+3 1E+4 1E+5 1E+6 1E+7

FREQUENCY (Hz)

Noise Performance

10mA

1mA

100mA

10 100 1k 10k 100k 1M 10M

VOUT = 5V

COUT = 10µF

electrolytic

0.0001

0.001

0.01

0.1

1E+1 1E+2 1E+3 1E+4 1E+5 1E+6 1E+7

FREQUENCY (Hz)

Noise Performance

10mA

1mA

100mA

10 100 1k 10k 100k 1M 10M

VOUT = 5V

COUT = 10µF

electrolytic

CBYP = 100pF

100

200

300

400

0 100 200 300 400 500

OUTPUT CURRENT (mA)

Dropout Voltage

vs. Output Current

0.5

1.0

1.5

2.0

2.5

3.0

3.5

0123456789

INPUT VOLTAGE (V)

Dropout Characteristics

IL =100µA

IL=100mA

IL=500mA

June 2009 7 M0371-061809

Micrel, Inc. MIC5219

0 100 200 300 400 500

OUTPUT CURRENT (mA)

Ground Current

vs. Output Current

0.5

1.0

1.5

2.0

2.5

3.0

02468

INPUT VOLTAGE (V)

Ground Current

vs. Supply Voltage

IL=100 mA

IL=100µA

0123456789

INPUT VOLTAGE (V)

Ground Current

vs. Supply Voltage

IL=500mA

Micrel, Inc. MIC5219

June 2009 8 M0371-061809

Block Diagrams

OUT

BYP

(optional)

GND

REF

Bandgap

Ref.

Current Limit

Thermal Shutdown

OUT

MIC5219-x.xBM5/M/YMT

Ultra-Low-Noise Fixed Regulator

OUT

BYP

(optional)

GND

REF

Bandgap

Ref.

Current Limit

Thermal Shutdown

OUT

MIC5219BM5/MM/YMT

Ultra-Low-Noise Adjustable Regulator

June 2009 9 M0371-061809

Micrel, Inc. MIC5219

Applications Information

The MIC5219 is designed for 150mA to 200mA output current

applications where a high current spike (500mA) is needed for

short, start-up conditions. Basic application of the device will

be discussed initially followed by a more detailed discussion

of higher current applications.

Enable/Shutdown

Forcing EN (enable/shutdown) high (>2V) enables the

regulator. EN is compatible with CMOS logic. If the enable/

shutdown feature is not required, connect EN to IN (supply

input). See Figure 5.

Input Capacitor

A 1µF capacitor should be placed from IN to GND if there is

more than 10 inches of wire between the input and the AC

lter capacitor or if a battery is used as the input.

Output Capacitor

An output capacitor is required between OUT and GND to

prevent oscillation. The minimum size of the output capacitor

is dependent upon whether a reference bypass capacitor is

used. 1µF minimum is recommended when CBYP is not used

(see Figure 5). 2.2µF minimum is recommended when CBYP

is 470pF (see Figure 6). For applications < 3V, the output

capacitor should be increased to 22µF minimum to reduce

start-up overshoot. Larger values improve the regulator’s

transient response. The output capacitor value may be in-

creased without limit.

The output capacitor should have an ESR (equivalent series

resistance) of about 1Ω or less and a resonant frequency

above 1MHz. Ultra-low-ESR capacitors could cause oscilla-

tion and/or underdamped transient response. Most tantalum

or aluminum electrolytic capacitors are adequate; lm types

will work, but are more expensive. Many aluminum electro-

lytics have electrolytes that freeze at about –30°C, so solid

tantalums are recommended for operation below –25°C.

At lower values of output current, less output capacitance is

needed for stability. The capacitor can be reduced to 0.47µF

for current below 10mA, or 0.33µF for currents below 1mA.

No-Load Stability

The MIC5219 will remain stable and in regulation with no load

(other than the internal voltage divider) unlike many other

voltage regulators. This is especially important in CMOS

RAM keep-alive applications.

Reference Bypass Capacitor

BYP is connected to the internal voltage reference. A 470pF

capacitor (CBYP) connected from BYP to GND quiets this

reference, providing a signicant reduction in output noise

(ultra-low-noise performance). CBYP reduces the regulator

phase margin; when using CBYP

, output capacitors of 2.2µF

or greater are generally required to maintain stability.

The start-up speed of the MIC5219 is inversely proportional

to the size of the reference bypass capacitor. Applications

requiring a slow ramp-up of output voltage should consider

larger values of CBYP

. Likewise, if rapid turn-on is necessary,

consider omitting CBYP

Thermal Considerations

The MIC5219 is designed to provide 200mA of continuous

current in two very small prole packages. Maximum power

dissipation can be calculated based on the output current and

the voltage drop across the part. To determine the maximum

power dissipation of the package, use the thermal resistance,

junction-to-ambient, of the device and the following basic

equation.

PD(max ) = TJ(max ) − TA

( )

θJA

TJ(max) is the maximum junction temperature of the die,

125°C, and TA is the ambient operating temperature. θJA

is layout dependent; Table 1 shows examples of thermal

resistance, junction-to-ambient, for the MIC5219.

Package θJA Recommended θJA 1" Squareθ

Minimum Footprint 2oz. Copper

MM8® (MM) 160°C/W 70°C/W 30°C/W

SOT-23-5 (M5) 220°C/W 170°C/W 130°C/W

2×2 MLF® (ML) 90°C/W — —

2×2 Thin

MLF® (MT) 90°C/W — —

Table 1. MIC5219 Thermal Resistance

The actual power dissipation of the regulator circuit can be

determined using one simple equation.

D = (VIN – VOUT) IOUT + VIN IGND

Substituting PD(max) for PD and solving for the operating

conditions that are critical to the application will give the

maximum operating conditions for the regulator circuit. For

example, if we are operating the MIC5219-3.3BM5 at room

temperature, with a minimum footprint layout, we can deter-

mine the maximum input voltage for a set output current.

PD(max ) = 125 °C−25°C

( )

220°C/W

D(max) = 455mW

The thermal resistance, junction-to-ambient, for the minimum

footprint is 220°C/W, taken from Table 1. The maximum power

dissipation number cannot be exceeded for proper opera-

tion of the device. Using the output voltage of 3.3V, and an

output current of 150mA, we can determine the maximum

input voltage. Ground current, maximum of 3mA for 150mA

of output current, can be taken from the “Electrical Charac-

teristics” section of the data sheet.

455mW = (VIN – 3.3V) × 150mA + VIN × 3mA

455mW = (150mA) × VIN + 3mA × VIN – 495mW

950mW = 153mA × VIN

IN = 6.2VMAX

Therefore, a 3.3V application at 150mA of output current

can accept a maximum input voltage of 6.2V in a SOT-23-5

package. For a full discussion of heat sinking and thermal

effects on voltage regulators, refer to the “Regulator Ther-

mals” section of Micrel’s Designing with Low-Dropout Voltage

Regulators handbook.

Micrel, Inc. MIC5219

June 2009 10 M0371-061809

Peak Current Applications

The MIC5219 is designed for applications where high start-up

currents are demanded from space constrained regulators.

This device will deliver 500mA start-up current from a SOT-

23-5 or MM8 package, allowing high power from a very low

prole device. The MIC5219 can subsequently provide output

current that is only limited by the thermal characteristics of

the device. You can obtain higher continuous currents from

the device with the proper design. This is easily proved with

some thermal calculations.

If we look at a specic example, it may be easier to follow.

The MIC5219 can be used to provide up to 500mA continuous

output current. First, calculate the maximum power dissipa-

tion of the device, as was done in the thermal considerations

section. Worst case thermal resistance (θJA = 220°C/W for

the MIC5219-x.xBM5), will be used for this example.

PD(max ) = TJ(max ) − TA

( )

θJA

Assuming a 25°C room temperature, we have a maximum

power dissipation number of

PD(max ) = 125 °C−25°C

( )

220 °C/W

D(max) = 455mW

Then we can determine the maximum input voltage for a

5-volt regulator operating at 500mA, using worst case ground

current.

D(max) = 455mW = (VIN – VOUT) IOUT + VIN IGND

OUT = 500mA

OUT = 5V

GND = 20mA

455mW = (VIN – 5V) 500mA + VIN × 20mA

2.995W = 520mA × VIN

VIN(max ) = 2.955W

520mA =5.683V

Therefore, to be able to obtain a constant 500mA output cur-

rent from the 5219-5.0BM5 at room temperature, you need

extremely tight input-output voltage differential, barely above

the maximum dropout voltage for that current rating.

You can run the part from larger supply voltages if the proper

precautions are taken. Varying the duty cycle using the en-

able pin can increase the power dissipation of the device by

maintaining a lower average power gure. This is ideal for

applications where high current is only needed in short bursts.

Figure 1 shows the safe operating regions for the MIC5219-x.

xBM5 at three different ambient temperatures and at differ-

ent output currents. The data used to determine this gure

assumed a minimum footprint PCB design for minimum heat

sinking. Figure 2 incorporates the same factors as the rst

gure, but assumes a much better heat sink. A 1" square cop-

per trace on the PC board reduces the thermal resistance of

the device. This improved thermal resistance improves power

dissipation and allows for a larger safe operating region.

Figures 3 and 4 show safe operating regions for the MIC5219-x.

xBMM, the power MSOP package part. These graphs show

three typical operating regions at different temperatures. The

lower the temperature, the larger the operating region. The

graphs were obtained in a similar way to the graphs for the

MIC5219-x.xBM5, taking all factors into consideration and

using two different board layouts, minimum footprint and 1"

square copper PC board heat sink. (For further discussion

of PC board heat sink characteristics, refer to “Application

Hint 17, Designing PC Board Heat Sinks” .)

The information used to determine the safe operating regions

can be obtained in a similar manner such as determining

typical power dissipation, already discussed. Determining

the maximum power dissipation based on the layout is the

rst step, this is done in the same manner as in the previous

two sections. Then, a larger power dissipation number multi-

plied by a set maximum duty cycle would give that maximum

power dissipation number for the layout. This is best shown

through an example. If the application calls for 5V at 500mA

for short pulses, but the only supply voltage available is

8V, then the duty cycle has to be adjusted to determine an

average power that does not exceed the maximum power

dissipation for the layout.

Avg.P D=% DC

100





 



 VIN – V OUT

( )

I OUT +VIN I GND

455mW = % DC

100





 



 8V – 5V

( )

500mA +8V ×20mA

455mW = % Duty Cycle

100





 



 1.66W

0.274 = % Duty Cycle

100

% Duty Cycle Max = 27.4%

With an output current of 500mA and a three-volt drop across

the MIC5219-xxBMM, the maximum duty cycle is 27.4%.

Applications also call for a set nominal current output with a

greater amount of current needed for short durations. This is a

tricky situation, but it is easily remedied. Calculate the average

power dissipation for each current section, then add the two

numbers giving the total power dissipation for the regulator.

For example, if the regulator is operating normally at 50mA,

but for 12.5% of the time it operates at 500mA output, the

total power dissipation of the part can be easily determined.

First, calculate the power dissipation of the device at 50mA.

We will use the MIC5219-3.3BM5 with 5V input voltage as

our example.

D × 50mA = (5V – 3.3V) × 50mA + 5V × 650µA

D × 50mA = 173mW

However, this is continuous power dissipation, the actual

on-time for the device at 50mA is (100%-12.5%) or 87.5%

of the time, or 87.5% duty cycle. Therefore, PD must be mul-

tiplied by the duty cycle to obtain the actual average power

dissipation at 50mA.

June 2009 11 M0371-061809

Micrel, Inc. MIC5219

0 20 40 60 80 100

DUTY CYCLE (%)

500mA

400mA

300mA

200mA

100mA

0 20 40 60 80 100

DUTY CYCLE (%)

500mA

400mA

300mA

200mA

100mA

0 20 40 60 80 100

DUTY CYCLE (%)

500mA

400mA

300mA

200mA

100mA

0 20 40 60 80 100

DUTY CYCLE (%)

500mA

400mA

300mA

200mA

0 20 40 60 80 100

DUTY CYCLE (%)

500mA

400mA

300mA

200mA

100mA

0 20 40 60 80 100

DUTY CYCLE (%)

500mA

400mA

300mA

200mA

100mA

0 20 40 60 80 100

DUTY CYCLE (%)

500mA

400mA

300mA

200mA

100mA

0 20 40 60 80 100

DUTY CYCLE (%)

500mA

400mA

300mA

200mA

0 20 40 60 80 100

DUTY CYCLE (%)

500mA

400mA

300mA

200mA

100mA

0 20 40 60 80 100

DUTY CYCLE (%)

500mA

400mA 300mA

200mA

100mA

0 20 40 60 80 100

DUTY CYCLE (%)

500mA

400mA

300mA

200mA

100mA

0 20 40 60 80 100

DUTY CYCLE (%)

500mA

400mA

300mA

200mA

100mA

a. 25°C Ambient b. 50°C Ambient c. 85°C Ambient

Figure 4. MIC5219-x.xBMM (MSOP-8) on 1-inch2 Copper Cladding

a. 25°C Ambient b. 50°C Ambient c. 85°C Ambient

Figure 3. MIC5219-x.xBMM (MSOP-8) on Minimum Recommended Footprint

a. 25°C Ambient b. 50°C Ambient c. 85°C Ambient

Figure 2. MIC5219-x.xBM5 (SOT-23-5) on 1-inch2 Copper Cladding

a. 25°C Ambient b. 50°C Ambient c. 85°C Ambient

Figure 1. MIC5219-x.xBM5 (SOT-23-5) on Minimum Recommended Footprint

Micrel, Inc. MIC5219

June 2009 12 M0371-061809

D × 50mA = 0.875 × 173mW

D × 50mA = 151mW

The power dissipation at 500mA must also be calculated.

D × 500mA = (5V – 3.3V) 500mA + 5V × 20mA

D × 500mA = 950mW

This number must be multiplied by the duty cycle at which it

would be operating, 12.5%.

D × = 0.125 × 950mW

D × = 119mW

The total power dissipation of the device under these condi-

tions is the sum of the two power dissipation gures.

D(total) = PD × 50mA + PD × 500mA

D(total) = 151mW + 119mW

D(total) = 270mW

The total power dissipation of the regulator is less than the

maximum power dissipation of the SOT-23-5 package at room

temperature, on a minimum footprint board and therefore

would operate properly.

Multilayer boards with a ground plane, wide traces near the

pads, and large supply-bus lines will have better thermal

conductivity.

For additional heat sink characteristics, please refer to Mi-

crel “Application Hint 17, Designing P.C. Board Heat Sinks”,

included in Micrel’s Databook. For a full discussion of heat

sinking and thermal effects on voltage regulators, refer to

“Regulator Thermals” section of Micrel’s Designing with Low-

Dropout Voltage Regulators handbook.

Fixed Regulator Circuits

MIC5219-x.x

IN OUT

GND 1µF

OUT

EN BYP

Figure 5. Low-Noise Fixed Voltage Regulator

Figure 5 shows a basic MIC5219-x.xBMX xed-voltage regu-

lator circuit. A 1µF minimum output capacitor is required for

basic xed-voltage applications.

MIC5219-x.x

IN OUT

GND

470pF

EN BYP

2.2µF

OUT

Figure 6. Ultra-Low-Noise Fixed Voltage Regulator

Figure 6 includes the optional 470pF noise bypass capacitor

between BYP and GND to reduce output noise. Note that the

minimum value of COUT must be increased when the bypass

capacitor is used.

Adjustable Regulator Circuits

MIC5219

IN OUT

GND

EN ADJ

1µF

OUT

Figure 7. Low-Noise Adjustable Voltage Regulator

Figure 7 shows the basic circuit for the MIC5219 adjustable

regulator. The output voltage is congured by selecting values

for R1 and R2 using the following formula:

VOUT =1.242V R2

R1 +1





 





Although ADJ is a high-impedance input, for best performance,

R2 should not exceed 470kΩ.

MIC5219

IN OUT

GND

EN ADJ

2.2µF

OUT

470pF

Figure 8. Ultra-Low-Noise Adjustable Application

Figure 8 includes the optional 470pF bypass capacitor from

ADJ to GND to reduce output noise.

June 2009 13 M0371-061809

Micrel, Inc. MIC5219

Package Information

8-Pin MSOP (MM)

SOT-23-5 (M5)

Micrel, Inc. MIC5219

June 2009 14 M0371-061809

6-Pin MLF® (ML)

6-Pin Thin MLF® (MT)

MICREL, INC. 2180 FORTUNE DRIVE SAN JOSE, CA 95131 USA

t e l + 1 (408) 944-0800 f a x + 1 (408) 474-1000 w e b http://www.micrel.com

The information furnished by Micrel in this data sheet is believed to be accurate and reliable. However, no responsibility is assumed by Micrel for its use.

Micrel reserves the right to change circuitry and specications at any time without notication to the customer.

Micrel Products are not designed or authorized for use as components in life support appliances, devices or systems where malfunction of a product can

reasonably be expected to result in personal injury. Life support devices or systems are devices or systems that (a) are intended for surgical implant into

the body or (b) support or sustain life, and whose failure to perform can be reasonably expected to result in a signicant injury to the user. A Purchaser’s

use or sale of Micrel Products for use in life support appliances, devices or systems is at Purchaser’s own risk and Purchaser agrees to fully indemnify

Micrel for any damages resulting from such use or sale.