MIC20xx Family Datasheet by Microchip Technology

E'I'IIEREU www.micrel.com mm «T—W‘

MIC20XX Family

Fixed and Adjustable Current Limiting

Power Distribution Switches

Kickstart is a trademark of Micrel, Inc.

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

CableCARD is a trademark of CableLabs.

Protected by U.S. Patent No. 7,170,732

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

General Description

MIC20XX family of switches are current limiting, high-side

power switches, designed for general purpose power

distribution and control in digital televisions (DTV), printers,

set top boxes (STB), PCs, PDAs, and other peripheral

devices (see Functionality Table and Pin Configuration

drawings)

MIC20XX family’s primary functions are current limiting

and power switching. They are thermally protected and will

shutdown should their internal temperature reach unsafe

levels, protecting both the device and the load, under high-

current or fault conditions

Features include fault reporting, fault blanking to eliminate

noise-induced false alarms, output slew rate limiting, under

voltage detection, automatic-on output, and enable pin

with choice of either active low or active high enable. The

FET is self-contained, with a fixed- or user-adjustable

current limit. The MIC20XX family is ideal for any system

where current limiting and power control are desired.

The MIC201X (3  x  9) and MIC2019A switches offer a

unique new patented feature: Kickstart™, which allows

momentary high-current surges up to the secondary

current limit (ILIMIT_2nd) without sacrificing overall system

safety.

The MIC20xx family is offered, depending on the desired

features, in a space-saving 5-pin SOT-23, 6-pin SOT-23,

and 2mm x 2mm MLF® packages.

Datasheets and support documentation can be found on

Micrel’s web site at: www.micrel.com.

Features

• MIC20X3 – MIC20X9

70mΩ typical on-resistance @ 5V

• MIC2005A/20X9A

170mΩ typical on-resistance @ 5V

• Enable active high or active low

• 2.5V – 5.5V operating range

• Pre-set current limit values of 0.5A, 0.8A, and 1.2A*

• Adjustable current limit 0.2A to 2.0A* (MIC20X7-

MIC20X9)

• Adjustable current limit 0.1A to 0.9A* (MIC20X9A)

• Undervoltage lock-out (UVLO)

• Variable UVLO allows adjustable UVLO thresholds*

• Automatic load discharge for capacitive loads*

• Soft-start prevents large current inrush

• Adjustable slew rate allows custom slew rates*

• Automatic-on output after fault

• Thermal protection

* Available on some family members

Applications

• Digital televisions (DTV)

• Set top boxes

• PDAs

• Printers

• USB / IEEE 1394 power distribution

• Desktop and laptop PCs

• Game consoles

• Docking stations

___________________________________________________________________________________________________________

Typical Application

VIN VOUT

MIC2005A

VBUS

USB

Port

GND

EN FAULT/

5V Supply

VIN

Logic

Controller

ON/OFF

OVERCURRENT/ 1µF

120µF

Figure 1. Typical Application Circuit

August 2011 M9999-080211-D

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Ordering Information

MIC2003/2013

Part Number(1) Marking(2) Current Limit Kickstart™ Package

MIC2003-0.5YM5 FD05 0.5A

MIC2003-0.8YM5 FD08 0.8A

MIC2003-1.2YM5 FD12 1.2A

5-Pin SOT-23

MIC2003-0.5YML 50D 0.5A

MIC2003-0.8YML 80D 0.8A

MIC2003-1.2YML 21D 1.2A

6-Pin 2mm x 2mm MLF®

MIC2013-0.5YM5 FL05 0.5A

MIC2013-0.8YM5 FL08 0.8A

MIC2013-1.2YM5 FL12 1.2A

5-Pin SOT-23

MIC2013-0.5YML 50L 0.5A

MIC2013-0.8YML 90L 0.8A

MIC2013-1.2YML 21L 1.2A

Yes

6-Pin 2mm x 2mm MLF®

MIC2004/2014

Part Number(1) Marking(2) Current Limit Kickstart™ Package

MIC2004-0.5YM5 FE05 0.5A

MIC2004-0.8YM5 FE08 0.8A

MIC2004-1.2YM5 FE12 1.2A

5-Pin SOT-23

MIC2004-0.5YML 50E 0.5A

MIC2004-0.8YML 80E 0.8A

MIC2004-1.2YML 21E 1.2A

6-Pin 2mm x 2mm MLF®

MIC2014-0.5YM5 FM05 0.5A

MIC2014-0.8YM5 FM08 0.8A

MIC2014-1.2YM5 FM12 1.2A

5-Pin SOT-23

MIC2014-0.5YML 50M 0.5A

MIC2014-0.8YML 90M 0.8A

MIC2014-1.2YML 21M 1.2A

Yes

6-Pin 2mm x 2mm MLF®

Notes:

1. All MIC20XX Family parts are RoHS-compliant lead free.

2. Over/Under-bar symbol ( ¯ / _ ) may not be to scale. On the package the over/under symbol begins above/below the first character of the

marking.

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Ordering Information (Continued)

MIC2005

Part Number(1) Marking(2) Current Limit Enable Kickstart™ Package

MIC2005-0.5YM6 FF05 0.5A Active High

MIC2005-0.8YM6 FF08 0.8A Active High

MIC2005-1.2YM6 FF12 1.2A Active High

6-Pin SOT-23

MIC2005-0.5YML 50F 0.5A Active High

MIC2005-0.8YML 80F 0.8A Active High

MIC2005-1.2YML 21F 1.2A Active High

6-Pin 2mm x 2mm MLF®

MIC2005L

Part Number(1) Marking(2) Current Limit Enable Kickstart™ Package

MIC2005-0.5LYM5 5LFF 0.5A Active Low

MIC2005-0.8LYM5 8LFF 0.8A Active Low

MIC2005-1.2LYM5 4LFF 1.2A Active Low

No 5-Pin SOT-23

MIC2005A

Part Number(1) Marking(2) Current Limit Enable Kickstart™ Package

MIC2005A-1YM5 FA51 0.5A Active High

MIC2005A-2YM5 FA52 0.5A Active Low 5-Pin SOT-23

MIC2005A-1YM6 FA53 0.5A Active High

MIC2005A-2YM6 FA54 0.5A Active Low

6-Pin SOT-23

MIC2015

Part Number(1) Marking(2) Current Limit Enable Kickstart™ Package

MIC2015-0.5YM6 FN05 0.5A Active High

MIC2015-0.8YM6 FN08 0.8A Active High

MIC2015-1.2YM6 FN12 1.2A Active High

6-Pin SOT-23

MIC2015-0.5YML 50N 0.5A Active High

MIC2015-0.8YML 80N 0.8A Active High

MIC2015-1.2YML 21N 1.2A Active High

Yes

6-Pin 2mm x 2mm MLF®

Notes:

1. All MIC20XX Family parts are RoHS-compliant lead free.

2. Over/Under-bar symbol ( ¯ / _ ) may not be to scale. On the package the over/under symbol begins above/below the first character of the

marking.

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Ordering Information (Continued)

MIC2006/2016

Part Number(1) Marking(2) Current Limit Kickstart™ Package

MIC2006-0.5YM6 FG05 0.5A

MIC2006-0.8YM6 FG08 0.8A

MIC2006-1.2YM6 FG12 1.2A

6-Pin SOT-23

MIC2006-0.5YML 50G 0.5A

MIC2006-0.8YML 80G 0.8A

MIC2006-1.2YML 21G 1.2A

6-Pin 2mm x 2mm MLF®

MIC2016-0.5YM6 FP05 0.5A

MIC2016-0.8YM6 FP08 0.8A

MIC2016-1.2YM6 FP12 1.2A

6-Pin SOT-23

MIC2016-0.5YML 50P 0.5A

MIC2016-0.8YML 90P 0.8A

MIC2016-1.2YML 21P 1.2A

Yes

6-Pin 2mm x 2mm MLF®

MIC2007/2017

Part Number(1) Marking(2) Current Limit Kickstart™ Package

MIC2007YM6 FHAA 6-Pin SOT-23

MIC2007YML AHA No 6-Pin 2mm x 2mm MLF®

MIC2017YM6 FQAA 6-Pin SOT-23

MIC2017YML

0.2A – 2.0A

Yes 6-Pin 2mm x 2mm MLF®

AQA

MIC2008/2018

Part Number(1) Marking(2) Current Limit Kickstart™ Package

MIC2008YM6 FJAA 6-Pin SOT-23

MIC2008YML AJA No 6-Pin 2mm x 2mm MLF®

MIC2018YM6 FRAA 6-Pin SOT-23

MIC2018YML

0.2A – 2.0A

Yes 6-Pin 2mm x 2mm MLF®

ARA

MIC2009/2019

Part Number(1) Marking(2) Current Limit Kickstart™ Package

MIC2009YM6 FKAA 6-Pin SOT-23

MIC2009YML AKA No 6-Pin 2mm x 2mm MLF®

MIC2019YM6 FSAA 6-Pin SOT-23

MIC2019YML ASA

0.2A – 2.0A

Yes 6-Pin 2mm x 2mm MLF®

Notes:

1. All MIC20XX Family parts are RoHS-compliant lead free.

2. Over/Under-bar symbol ( ¯ / _ ) may not be to scale. On the package the over/under symbol begins above/below the first character of the

marking.

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Ordering Information (Continued)

MIC2009A/2019A

Part Number(1) Marking(2) Current Limit Kickstart™ Enable Package

MIC2009A-1YM6 FK1 Active High

MIC2009A-2YM6 FK2 No Active Low

MIC2019A-1YM6 FS1 Active High

MIC2019A-2YM6 FS2

0.1 A – 0.9 A

Yes Active Low

6-pin SOT-23

Notes:

1. All MIC20XX Family parts are RoHS-compliant lead free.

2. Over/Under-bar symbol ( ¯ / _ ) may not be to scale. On the package the over/under symbol begins above/below the first character of the

marking.

MIC20XX Family Member Functionality

Part Number Pin Function

Normal

Limiting Kickstart™(1) I

LIMIT I

LIMIT ENABLE

High ENABLE

Low CSLEW FAULT/ VUVLO(5) Load

Discharge

2003 2013 – – – – – – 

2004 2014       

2005 2015       

2005L  (1)       

2005A-1  (1)     (6)   

2005A-2  (1)     (6)   

2006 2016

Fixed (2)

      

2007 2017       

2008 2018       

2009 2019       

2009A-1 2019A-1       

2009A-2 2019A-2

Adj.(3)

      

Notes:

1. Kickstart™ provides an alternate start-up behavior; however, pin-outs are identical.

2. Kickstart™ not available.

3. Fixed = Factory-programmed current limit.

4. Adj. = User adjustable current limit.

5. VUVLO = Variable UVLO (Previously called DML).

6. CSLEW not available in 5-pin package.

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MIC20XX Family Member Pin Configuration Table, SOT Packages

Part Number Pin Number

Normal

Limiting Kickstart™ ILIMIT 1 2 3 4 5 6

2003 2013 VIN GND NC NC VOUT 

2004 2014 VIN GND EN NC VOUT 

2005 2015 VIN GND EN FAULT/ CSLEW VOUT

2005L  (1) VIN GND EN FAULT/ VOUT 

2005Axxx6  (1) VIN GND EN FAULT/ CSLEW VOUT

2005Axxx5  (1) VIN GND EN FAULT/ VOUT 

2006 2016

Fixed(2)

VIN GND EN VUVLO(4) CSLEW VOUT

2007 2017 VIN GND EN ILIMIT CSLEW VOUT

2008 2018 VIN GND EN ILIMIT CSLEW VOUT

2009 2019 VIN GND EN FAULT/ ILIMIT VOUT

2009A 2019A

Adj.(3)

VIN GND EN FAULT/ ILIMIT VOUT

Notes:

1. Kickstart™ not available.

2. Fixed = Factory-programmed current limit.

3. ILIMIT = User adjustable current limit.

4. VUVLO = Variable UVLO (Previously called DLM).

MIC20XX Family Member Pin Configuration Table, MLF® Packages (5)

Part Number Pin Number

Normal Limiting Kickstart™ I Limit 6 5 4 3 2 1

2003 2013 VIN GND NC

NC NC VOUT

2004 2014 VIN GND EN

NC NC VOUT

2005 2015 VIN GND EN FAULT/ CSLEW VOUT

2006 2016

Fixed(2)

VIN GND EN

VUVLO(4) CSLEW VOUT

2007 2017 VIN GND EN ILIMIT CSLEW VOUT

2008 2018 VIN GND EN ILIMIT CSLEW VOUT

2009 2019

Adj.(3)

VIN GND EN FAULT/ ILIMIT VOUT

Notes:

1. Kickstart™ not available.

2. Fixed = Factory-programmed current limit.

3. ILIMIT = User adjustable current limit.

4. VUVLO = Variable UVLO (Previously called DLM).

5. Connect EP to GND.

E L E A N E vw GND ENABLE vouT CSLEW - 2 FAULT] CSLEW - 2 EDD

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MIC20XX Family Member Pin Configuration Drawings

Fixed Current Limit

MIC20X3

VIN

GND

VOUT

5-Pin SOT-23 (M5) 6-Pin MLF® (ML)

(Top View)

MIC20X4

VIN

GND

ENABLE

VOUT

5-Pin SOT-23 (M5) 6-Pin MLF® (ML)

(Top View)

MIC20X5

VIN

GND

ENABLE

VOUT

FAULT/

VIN

GND

ENABLE

VOUT

FAULT/

CSLEW

5-Pin SOT-23 (M5)

MIC2005-X.XL 6-Pin SOT-23 (M6)

MIC20X5 6-Pin MLF® (ML)

(Top View)

MIC20X5

MIC20X6

VIN

GND

ENABLE

VOUT

VUVLO

CSLEW

6-Pin SOT-23 (M6) 6-Pin MLF® (ML)

(Top View)

1311:1131 IZIIZIIZI EH11: IZIIZHZI DEE! mm W CSLEW GND “.an ENABLE VOUT " VIN \LIMIT GND FAULT/ , ENABLE EIEIEI IZIIZIIZI DEE! [IUD

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MIC20XX Family Member Pin Configuration Drawings (Continued)

Adjustable Current Limit

MIC20X7/20X8

VIN

GND

ENABLE

VOUT

ILIMIT

CSLEW

6-Pin SOT-23 (M6) 6-Pin MLF® (ML)

(Top View)

MIC20X9

VIN

GND

ENABLE

VOUT

FAULT/

ILIMIT

6-Pin SOT-23 (M6) 6-Pin MLF® (ML)

(Top View)

MIC2005A

VIN

GND

ENABLE

VOUT

FAULT/

VIN

GND

ENABLE

VOUT

FAULT/

CSLEW

5-Pin SOT-23 (M5) 6-Pin SOT-23 (M6)

MIC2009A

VIN

GND

ENABLE

VOUT

FAULT/

ILIMIT

6-Pin SOT-23 (M6)

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Descriptions

These pin and signal descriptions aid in the

differentiation of a pin from electrical signals and

components connected to that pin. For example, VOUT

is the switch’s output pin, while VOUT is the electrical

signal output voltage present at the VOUT pin.

Pin Descriptions

Pin Name Type Description

VIN Input Supply input. This pin provides power to both the output switch and the switch’s internal control circuitry.

GND  Ground.

EN Input Switch Enable (Input):

FAULT/ Output

Fault status. A logic LOW on this pin indicates the switch is in current limiting, or has been shut down by

the thermal protection circuit. This is an open-drain output allowing logical OR’ing of multiple switches.

CSLEW Input

Slew rate control. Adding a small value capacitor between this pin and VIN slows turn-ON of the power

FET.

VOUT Output Switch output. The load being driven by the switch is connected to this pin.

VUVLO Input

Variable Under Voltage Lockout (VUVLO): Monitors the input voltage through a resistor divider between

VIN and GND. Shuts the switch off if voltage falls below the threshold set by the resistor divider.

Previously called VUVLO.

ILIMIT Input Set current limit threshold via a resistor connected from ILIMIT to GND.

EP Thermal On MLF packages connect EP to GND.

Signal Descriptions

Signal Name Type Description

VIN Input Electrical signal input voltage present at the VIN pin.

GND  Ground.

VEN Input Electrical signal input voltage present at the ENABLE pin.

VFAULT/ Output Electrical signal output voltage present at the FAULT/ pin.

CSLEW Component Capacitance value connected to the CSLEW pin.

VOUT Output Electrical signal output voltage present at the VOUT pin.

VVUVLO_TH Internal

VUVLO internal reference threshold voltage. This voltage is compared to the VUVLO pin input

voltage to determine if the switch should be disabled. Reference threshold voltage has a typical

value of 250mV.

CLOAD Component Capacitance value connected in parallel with the load. Load capacitance.

IOUT Output Electrical signal output current present at the VOUT pin.

ILIMIT Internal Switch’s current limit. Fixed at factory or user adjustable.

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Absolute Maximum Ratings(1)

VIN, VOUT.....................................................–0.3V to 6V

All other pins...........................................–0.3V to 5.5V

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

Continuous Output Current

All except MIC2005A / MIC20X9A................. 2.25A

MIC2005A / 20X9A.......................................... 1.0A

Maximum Junction Temperature (TJ) ................ 150°C

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

Lead Temperature (Soldering 10 sec)............... 260°C

Operating Ratings(2)

Supply Voltage.............................................. 2.5V to 5.5V

Continuous Output Current

All except MIC2005A / MIC20X9A ........... 0A to 2.1A

MIC2005A/20X9A...................................... 0A to 0.9A

Ambient Temperature Range (TA) ............–40°C to+85°C

Package Thermal Resistance(3)

SOT-23-5/6 (JA) .........................................230°C /W

2mm × 2mm MLF® (JA) ................................90°C /W

2mm × 2mm MLF® (JC) ................................45°C /W

Electrical Characteristics(4)

VIN = 5V, TA = 25°C unless otherwise specified. Bold indicates –40°C to +85°C limits; CIN = 1µF.

Symbol Parameter Condition Min. Typ. Max. Units

VIN Switch Input Voltage 2.5

5.5 V

ILEAK Output Leakage Current(5)

Switch = OFF, VOUT = 0V

Active Low Enable, VEN = 1.5V

Active High Enable, VEN = 0V

12 100 µA

MIC2005A, MIC2009A, MIC2019A

Switch = ON

Active Low Enable, VEN = 0V

Active High Enable, VEN = 1.5V

80 300

Switch = OFF

Active Low Enable, VEN = 1.5V 8 15

IIN Supply Current(5)

Switch = OFF

Active High Enable, VEN = 0V 1 5

µA

170 220

RDS(ON) Power Switch Resistance VIN = 5V, IOUT = 100mA 275 m

MIC2005A

ILIMIT Fixed Current Limit VOUT = 0.8 × VIN 0.5 0.7 0.9 A

MIC2009A, MIC2019A

IOUT = 0.9A, VOUT = 0.8 × VIN 172 211 263

IOUT = 0.5A, VOUT = 0.8 × VIN 152 206 263

IOUT = 0.2A, VOUT = 0.8 × VIN 138 200 263

CLF Variable Current Limit Factors

IOUT = 0.1A, VOUT = 0.8 × VIN 121 192 263

MIC2019A

ILIMIT_2nd Secondary Current Limit VIN = 2.5V, VOUT = 0V 1 2 3 A

Notes:

1. Exceeding the absolute maximum rating may damage the device.

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

3. Requires proper thermal mounting to achieve this performance

4. Specifications for packaged product only.

5. Check the Ordering Information section to determine which parts are Active High or Active Low.

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Electrical Characteristics(4) (Continued)

VIN = 5V, TA = 25°C unless otherwise specified. Bold indicates –40°C to +85°C limits; CIN = 1µF.

Symbol Parameter Condition Min. Typ. Max. Units

MIC2003-MIC2009, MIC2013-MIC2019, MIC2005-X.XL

Switch = ON

Active Low Enable, VEN = 0V

Active High Enable, VEN = 1.5V

80 330

Switch = OFF

Active Low Enable, VEN = 1.5V 8 15

IIN Supply Current(5)

Switch = OFF

Active High Enable, VEN = 0V 1 5

µA

70 100

RDS(ON) Power Switch Resistance VIN = 5V, IOUT = 100mA 125 m

MIC2003-X.X, MIC2004-X.X, MIC2005-X.X, MIC2006-X.X, MIC2013-X.X, MIC2014-X.X, MIC2015-X.X MIC2016-X.X, MIC2005-X.XL

−0.5, VOUT = 0.8 × VIN 0.5 0.7 0.9

−0.8, VOUT = 0.8 × VIN 0.8 1.1 1.5

ILIMIT Fixed Current Limit

−1.2, VOUT = 0.8 × VIN 1.2 1.6 2.1

MIC2005-0.5

ILIMIT Fixed Current Limit VOUT = 0.8 × VIN 0.5 0.7 0.9 A

MIC2007, MIC2008, MIC2009, MIC2017, MIC2018, MIC2019

IOUT = 2.0A, VOUT = 0.8 × VIN 210 250 286

IOUT = 1.0A, VOUT = 0.8 × VIN 190 243 293

IOUT = 0.5A, VOUT = 0.8 × VIN 168 235 298

CLF Variable Current Limit

Factors

IOUT = 0.2A, VOUT = 0.8 × VIN 144 225 299

MIC2013, MIC2014, MIC2015, MIC2016, MIC2017, MIC2018, MIC2019

ILIMIT_2nd Secondary Current Limit VIN = 2.5V, VOUT = 0V 2.2 4 6 A

MIC2006, MIC2016

VUVLO_TH Variable UVLO Threshold 225 250 275 mV

MIC20x4, MIC20x7

RDSCHG Load Discharge Resistance VIN = 5V, ISINK = 5mA 70 126 200 

MIC20X5, MIC20X6, MIC20X7, MIC20X8

ICSLEW C

SLEW Input Current 0V ≤ VOUT ≤ 0.8VIN 0.175 µA

Vw TA 25" 40" +85" Cw

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Electrical Characteristics(4) (Continued)

VIN = 5V, TA = 25°C unless otherwise specified. Bold indicates –40°C to +85°C limits; CIN = 1µF.

Symbol Parameter Condition Min. Typ. Max. Units

All Parts

VIL (MAX) 0.5

VEN ENABLE Input Voltage(6) VIH (MIN) 1.5 V

IEN ENABLE Input Current

0V ≤ VEN ≤ 5V 1 5 µA

VIN Rising 2 2.25 2.5

UVLOTHRESHOLD Undervoltage Lock-Out

Threshold VIN Falling 1.9 2.15 2.4 V

UVLOHYSTERESIS Undervoltage Lock-Out

Hysteresis 0.1 V

VFAULT Fault Status Output Voltage IOL = 10mA 0.25 0.4 V

TJ Increasing 145

OTTHRESHOLD Over-Temperature

Threshold TJ Decreasing 135 °C

Note:

6. VIL(MAX) = Maximum positive voltage applied to the input which will be accepted by the device as a logic low.

VIH(MAX) = Maximum positive voltage applied to the input which will be accepted by the device as a logic high.

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AC Electrical Characteristics

Symbol Parameter Condition Min. Typ. Max. Units

tRISE Output Turn-on rise time

RL = 10, CLOAD = 1µF,

VOUT = 10% to 90%

CSLEW(7) = Open

500 1000 1500 µs

Delay before asserting or releasing

FAULT/

MIC2003 – MIC2009

MIC2009A, MIC2005A

Time from current limiting to FAULT/ state

change 20 32 49

tD_FAULT Delay before asserting or releasing

FAULT/

MIC2013 – MIC2019

MIC2019A

Time from IOUT continuously exceeding

primary current limit condition to FAULT/

state change

77 128 192

tD_LIMIT

Delay before current limiting

MIC2013 – MIC2019

MIC2019A

128 192 ms

tRESET

Delay before resetting Kickstart™

current limit delay, tD_LIMIT

MIC2013 – MIC2019

MIC2019A

Out of current limit following a current limit

event. 77 128 192 ms

tON_DLY Output Turn-on Delay

RL = 43, CL = 120µF,

VEN = 50% to VOUT = 10%

*CSLEW = Open

1000 1500 µs

tOFF_DLY Output Turn-off Delay

RL = 43, CL = 120µF,

VEN = 50% to VOUT = 90%

*CSLEW = Open

700 µs

ESD(8)

Symbol Parameter Condition Min. Typ. Max. Units

VOUT and GND ±4

VESD_HB Electro Static Discharge Voltage:

Human Body Model All other pins ±2

VESD_MCHN Electro Static Discharge Voltage;

Machine Model

All pins

Machine Model ±200 V

Notes:

7. Whenever CSLEW is present.

8. Devices are ESD sensitive. Handling precautions recommended. Human body model, 1.5k in series with 100pF.

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Timing Diagrams

90%

10%

90%

10%

tFALL

tRISE

Rise and Fall Times

ENABLE

VOUT

50%

90%

10%

tON_DLY tOFF_DLY

50%

Switching Delay Times

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Typical Characteristics

100

2.5 3.0 3.5 4.0 4.5 5.0 5.5

SUPPLY CURRENT (µA)

VIN (V)

Supply Current Output Enabled

MIC20XX

-40°C

85°C

25°C

0.01

0.02

0.03

0.04

0.05

0.06

0.07

0.08

0.09

0.10

2.5 3.0 3.5 4.0 4.5 5.0 5.5

SUPPLY CURRENT (µA)

VIN (V)

Supply Current Output

Disabled (MIC20XX)

-40°C

85°C

25°C

0.01

0.02

0.03

0.04

0.05

0.06

0.07

0.08

0.09

0.10

-40 -15 10 35 60 85

LEAKAGE CURRENT (µA)

TEMPERATURE (°C)

Switch Leakage Current

(MIC20XX)

0.1

0.2

0.3

0.4

0.5

0.6

0.7

0.8

0.9

1.0

-40 -15 10 35 60 85

ILIMIT (A)

TEMPERATURE (°C)

ILIMIT vs. Temperature

(MIC20XX - 0.5)

0.5

0.6

0.7

0.8

0.9

1.0

1.1

1.2

1.3

1.4

1.5

-40 -15 10 35 60 85

ILIMIT (A)

TEMPERATURE (°C)

ILIMIT vs. Temperature

(MIC20XX - 0.8)

1.00

1.10

1.20

1.30

1.40

1.50

1.60

1.70

1.80

1.90

2.00

-40 -15 10 35 60 85

ILIMIT (A)

TEMPERATURE (°C)

ILIMIT vs. Temperature

(MIC20XX - 1.2)

100

120

140

160

180

200

22.533.544.555.5

RDS(ON) (mOhm)

VIN (V)

RDS(ON) vs. VIN

(MIC20XX)

-40°C

25°C 85°C

100

120

140

160

180

200

-40 -15 10 35 60 85

RDS(ON) (mOhm)

TEMPERATURE (°C)

RDS(ON) vs. Temperature

(MIC20XX)

2.5V 3.3V

5.0V

200

400

600

800

1000

1200

-40 -15 10 35 60 85

CURRENT-LIMIT THRESHOLD (mA)

TEMPERATURE (°C)

ILIMIT vs. Temperature

(MIC20X9 - 0.9A)

RSET = 267Ohms

100

120

140

160

0 0.2 0.4 0.6 0.8 1 1.2

VIN – VOUT (mV)

IOUT (A)

VDROP vs. Temperature

(MIC20XX-1.2)

-40°C

25°C

85°C

VIN = 5.0V

100

120

140

160

00.20.40.60.811.2

VIN – VOUT (mV)

IOUT (A)

VDROP vs. Temperature

(MIC20XX-1.2)

-40°C

25°C

85°C

VIN = 3.3V

200

400

600

800

1000

1200

0 0.2 0.4 0.6 0.8 1 1.2 1.4

RSET (Ohms)

ILIMIT (A)

RSET vs. ILIMIT

(MIC20X9)

RSET = 242.62

ILIMIT

0.9538

Micrel, Inc. MIC20xx Family

August 2011

16 M9999-080211-D

Typical Characteristics (Continued)

100

2.533.544.555.5

SUPPLY CURRENT (µA)

VIN (V)

Supply Current Output Enabled

(MIC20XXA)

-40°C

25°C 85°C

0.01

0.02

0.03

0.04

0.05

0.06

0.07

0.08

0.09

0.10

2.533.544.555.5

SUPPLY CURRENT (µA)

VIN (V)

Supply Current Output

Disabled (MIC20XXA)

-40°C 25°C 85°C

0.01

0.02

0.03

0.04

0.05

0.06

0.07

0.08

0.09

0.10

-40 -15 10 35 60 85

LEAKAGE CURRENT (µA)

TEMPERATURE (°C)

Switch Leakage Current

(MIC20XXA)

0.1

0.2

0.3

0.4

0.5

0.6

0.7

0.8

0.9

1.0

-40 -15 10 35 60 85

ILIMIT (A)

TEMPERATURE (°C)

ILIMIT vs. Temperature

(MIC20X5A)

100

200

300

400

500

600

700

800

900

1000

-40 -15 10 35 60 85

ILIMIT (A)

TEMPERATURE (°C)

ILIMIT vs. Temperature

(MIC20X9A (0.8A))

RSET = 267Ohms

500

1000

1500

2000

2500

00.20.40.60.81

RSET (Ohms)

ILIMIT (A)

RSET vs. ILIMIT

(MIC20X9A)

RSET = 212.23

ILIMIT

0.9587

100

150

200

250

2.533.544.555.5

RDS(ON) (mOhms)

VIN (V)

RDS(ON) vs. VIN

(MIC20XXA)

-40°C

25°C 85°C

100

150

200

250

-40 -15 10 35 60 85

RDS(ON) (mOhms)

TEMPERATURE (°C)

RDS(ON) vs. Temperature

(MIC20XXA)

5.0V

2.5V 3.3V

-40 -15 10 35 60 85

FLAG DELAY (ms)

TEMPERATURE (°C)

Flag Delay

vs. Temperature

2.5V

3.3V

5.0V

100

120

140

160

0 0.1 0.2 0.3 0.4 0.5 0.6

VIN - VOUT (mV)

IOUT (A)

VDROP vs. Temperature

(MIC20XXA)

-40°C

25°C 85°C

VIN = 5.0V

100

120

140

160

0 0.1 0.2 0.3 0.4 0.5 0.6

VIN - VOUT (mV)

IOUT (A)

VDROP vs. Temperature

(MIC20XXA)

-40°C

25°C 85°C

VIN = 3.3V

2.05

2.1

2.15

2.2

2.25

2.3

-50 0 50 100 150

THRESHOLD (V)

TEMPERATURE (°C)

UVLO Threshold

vs. Temperature

V RISING

V FALLING

Vm Soft Turn-On Turn-Off Vm vm (Maw! VFAum (7V V7 Vow tzvmm (mam VrAum (2V/mv Vow (7V/dm) lour (smuwmv) law lsOOmA/aw) TImeHms/dlvl Tlme(1ms/dw‘y Enable Tum-On Delay and Rise Time Enable Tum-Off Delay and Fall Time v ﬁ ﬁ 0UP 2m Vm lax/MW) Vm lax/MW) Vour (2mm) Vour (2Wdlv) l__—_—l Truelwous/dw} ﬁmevznus/dwl Enable Turn-Oanum-Off UVLO 1 vw : 5V a a DUF 2m , + Vaur (ml/5M r...“— 225v 215V Vour (soomA/aw} (swam) VIN {IV/m) .._...~ mm Iw Tlmelmms/dw} Tlmel’lDUms/dw}

Micrel, Inc. MIC20xx Family

August 2011

17 M9999-080211-D

Functional Characteristics

vEN (swam mm (swam vour lour (SuUmA/am (swam 45mm) 3 > iour (mam Vsmm (zwaw) Imm ﬁvrawi Vuur isvmw) iour (iNdM Enabled into Short v0w Snoned m Ground r _________J Time (1 ems/aw) Current Limit Response, Stepped Short Time MDms/dlv) Output Recovery from Short Circuit 5 1% mm » ik sums a! 'ﬁmeMﬂms/dwi Vouv 12mm VW (swam mum lour (SnomA/am m u) Power Up into Short Circuit chr Shoned to Ground Themiai Shmduwn 31mm Time (1 ems/aw) Current Limit Response Time, Stepped Short Vour (swam W > W VFAum i5V/dl4) iour (2mm 'ﬁmeHDus/GM Output Recovery from Thermal Shutdown Vsnanr (zvlmv) mum (Swan/i Vour (swam “I“? Thermai Shuldawn lour imam / ﬂﬂﬂﬂﬂﬂﬂﬂ wwmv Time (ﬁlms/div}

Micrel, Inc. MIC20xx Family

August 2011

18 M9999-080211-D

Functional Characteristics (Continued)

Vour (swam VquLr‘ {swam km (AUOMAIdw) Vour (SVIdw) VFAum swam mur (IA/mu) Vour (SVIdw) VFAum swam um (um, Current Limit Threshold Current Inrush Current Response ﬂ + EN (swam + 0L: wear- q = avuuF . 3 cL =220yF . 92 ‘ Mm=1 27A ' (c. :ZZUUF (c. : “our CL = WﬂuF 13 ' S Twme (Zums/dw} Twmeﬂms/dw“ Kickstarl Response Kickstarl Response 77ms/2.2A Load Step 150msl2.2A Load Step ii ii ¥ A Limo-us »‘ W L 77msv—‘ p 130m; —.\ «2 2A +2 2A + k g . f: a ‘1 Twme Mums/ow} Twme Mums/ow} Kickstarl Response Kickstarl Response Time Recgvery from Thermal Shutdown 5A Over Load a Wei F 130m 4-1 ._._ Leon... VFAum swam . * 1? F—mrmnum ﬁg ——l TwmeMﬂms/dw} Twmemms/dw“

Micrel, Inc. MIC20xx Family

August 2011

19 M9999-080211-D

Functional Characteristics (Continued)

UNDER VUVLO VUVLO — VOLTAGE ,_ "”020“ DETECTOR CURRENT I :i‘ MIRROR FET POWER FET _‘ T ENABLE — CONTROL LOGIC MIC20X4 - MICZOXQ AND FAULT/ DELAv TIMER .— GATE CONTROL MICZOXS & MICZOX9 THERMAL : SENSOR I | l ___ VIN VDUT LOAD DISCHARGE M|020X4 & MICQOX7 CSLEW SLEW RATE MICZOXB - MICZOXB CONTROL LUKNENL anm I CONTROL LOOF : GND I IUW FACTOR ADJUSTED : M‘CZOXS - M|C2OX6 ILIMIT USER ADJUSTABLE M|C20X7 r MICZOXQ, MICZOXSA

Micrel, Inc. MIC20xx Family

August 2011

20 M9999-080211-D

Functional Diagram

Figure 2. MIC20XX Family Functional Diagram

("m avmw mm W NW D 2.. vow 5vmw wow Wm

Micrel, Inc. MIC20xx Family

August 2011

21 M9999-080211-D

Functional Description

VIN and VOUT

VIN is both the power supply connection for the internal

circuitry driving the switch and the input (Source

connection) of the power MOSFET switch. VOUT is the

Drain connection of the power MOSFET and supplies

power to the load. In a typical circuit, current flows from

VIN to VOUT toward the load. Since the switch is bi-

directional when enabled, if VOUT is greater than VIN,

current will flow from VOUT to VIN.

When the switch is disabled, current will not flow to the

load, except for a small unavoidable leakage current of

a few microamps. However, should VOUT exceed VIN by

more than a diode drop (~0.6 V), while the switch is

disabled, current will flow from output to input via the

power MOSFET’s body diode.

If discharging CLOAD is required by your application,

consider using MIC20X4 or MIC20X7; these MIC20XX

family members are equipped with a discharge FET to

insure complete discharge of CLOAD.

Current Sensing and Limiting

MIC20XX protects the system power supply and load

from damage by continuously monitoring current

through the on-chip power MOSFET. Load current is

monitored by means of a current mirror in parallel with

the power MOSFET switch. Current limiting is invoked

when the load exceeds the set over-current threshold.

When current limiting is activated the output current is

constrained to the limit value, and remains at this level

until either the load/fault is removed, the load’s current

requirement drops below the limiting value, or the

switch goes into thermal shutdown.

Kickstart™

2003 2004 2005X 2006 2007 2008 2009X

2013 2014 2015 2016 2017 2018 2019X

Only parts in bold have Kickstart™.

(Not available in 5-pin SOT-23 packages)

The MIC201X is designed to allow momentary current

surges (Kickstart™) before the onset of current limiting,

which permits dynamic loads, such as small disk drives

or portable printers to draw the energy needed to

overcome inertial loads without sacrificing system

safety. In this respect, the Kickstart™ parts (MIC201X)

differs markedly from the non-Kickstart™ parts

(MIC200X) which immediately limit load current,

potentially starving the motor and causing the appliance

to stall or stutter.

During this delay period, typically 128ms, a secondary

current limit is in effect. If the load demands a current in

excess the secondary limit, MIC201X acts immediately

to restrict output current to the secondary limit for the

duration of the Kickstart™ period. After this time the

MIC201X reverts to its normal current limit. An example

of Kickstart™ operation is shown in Figure 3.

Figure 3. Kickstart™ Operation

Figure 3 Label Key:

A. MIC201X is enabled into an excessive load (slew

rate limiting not visible at this time scale) The initial

current surge is limited by either the overall circuit

resistance and power supply compliance, or the

secondary current limit, whichever is less.

B. RON of the power FET increases due to internal

heating (effect exaggerated for emphasis).

C. Kickstart™ period.

D. Current limiting initiated. FAULT/ goes LOW.

E. VOUT is non-zero (load is heavy, but not a dead short

where VOUT = 0V. Limiting response will be the same

for dead shorts).

F. Thermal shutdown followed by thermal cycling.

G. Excessive load released, normal load remains.

MIC201X drops out of current limiting.

H. FAULT/ delay period followed by FAULT/ going

HIGH.

Undervoltage Lock-Out

Undervoltage lock-out insures no anomalous operation

occurs before the device’s minimum input voltage of

UVLOTHRESHOLD which is 2V minimum, 2.25V typical,

and 2.5V maximum had been achieved. Prior to

reaching this voltage, the output switch (power

MOSFET) is OFF and no circuit functions, such as

FAULT/ or ENABLE, are considered to be valid or

operative.

Micrel, Inc. MIC20xx Family

August 2011

22 M9999-080211-D

Variable Undervoltage Lock Out (VUVLO)

2003 2004 2005X

2006 2007 2008 2009X

2013 2014 2015 2016 2017 2018 2019X

Only parts in bold have VUVLO.

VUVLO functions as an input voltage monitor when the

switch in enabled. The VIN pin is monitored for a drop in

voltage, indicating excessive loading of the VIN supply.

When VIN is less than the VULVO threshold voltage

(VVUVLO_TH) for 32ms or more, the MIC20XX disables

the switch to protect the supply and allow VIN to

recover. After 128ms has elapsed, the MIC20X6

enables switch. This disable and enable cycling will

continue as long as VIN deceases below the VUVLO

threshold voltage (VVUVLO_TH) which has a typical value

of 250mV. The VUVLO voltage is commonly established

by a voltage divider from VIN-to-GND.

ENABLE

2003 2004 2005X 2006 2007 2008 2009X

2013 2014 2015 2016 2017 2018 2019X

Only parts in bold have ENABLE pin.

ENABLE pin is a logic compatible input which activates

the main MOSFET switch thereby providing power to

the VOUT pin. ENABLE is either an active HIGH or active

LOW control signal. The MIC20XX can operate with

logic running from supply voltages as low as 1.5 V.

ENABLE may be driven higher than VIN, but no higher

than 5.5V and not less than –0.3V.

FAULT/

2003 2004

2005X 2006 2007 2008

2009X

2013 2014 2015 2016 2017 2018

2019X

Only parts in bold have FAULT/ pin.

FAULT/ is an N-channel open-drain output, which is

asserted (LOW true) when switch either begins current

limiting or enters thermal shutdown.

FAULT/ asserts after a brief delay when events occur

that may be considered possible faults. This delay

insures that FAULT/ is asserted only upon valid,

enduring, over-current conditions and that transitory

event error reports are filtered out.

In MIC200X FAULT/ asserts after a brief delay period,

of 32ms typical. After a fault clears, FAULT/ remains

asserted for the delay period of 32ms

MIC201X’s FAULT/ asserts at the end of the Kickstart™

period which is 128ms typical. This masks initial current

surges, such as would be seen by a motor load starting

up. If the load current remains above the current limit

threshold after the Kickstart™ has timed out, then the

FAULT/ will be asserted. After a fault clears, FAULT/

remains asserted for the delay of 128ms.

Because FAULT/ is an open-drain it must be pulled

HIGH with an external resistor and it may be wire-OR’d

with other similar outputs, sharing a single pull-up

resistor. FAULT/ may be tied to a pull-up voltage source

which is higher than VIN, but no greater than 5.5V.

Soft-Start Control

Large capacitive loads can create significant inrush

current surges when charged through the switch. For

this reason, the MIC20XX family of switches provides a

built-in soft-start control to limit the initial inrush

currents.

Soft-start is accomplished by controlling the power

MOSFET when the ENABLE pin enables the switch.

CSLEW

2003 2004

2005X 2006 2007 2008

2009X

2013 2014 2015 2016 2017 2018

2019X

Only parts in bold have CSLEW pin.

(Not available in 5-pin SOT-23 packages)

The CSLEW pin is provided to increase control of the

output voltage ramp at turn-on. This input allows

designers the option of decreasing the output’s slew

rate (slowing the voltage rise) by adding an external

capacitance between the CSLEW and VIN pins.

Thermal Shutdown

Thermal shutdown is employed to protect the MIC20XX

family of switches from damage should the die

temperature exceed safe operating levels. Thermal

shutdown shuts off the output MOSFET and asserts the

FAULT/ output if the die temperature reaches 145°C.

The switch will automatically resume operation when the

die temperature cools down to 135°C. If resumed

operation results in reheating of the die, another

shutdown cycle will occur and the switch will continue

cycling between ON and OFF states until the overcurrent

condition has been resolved.

Depending on PCB layout, package type, ambient

temperature, etc., hundreds of milliseconds may elapse

from the incidence of a fault to the output MOSFET

being shut off. This delay is due to thermal time

constants within the system itself. In no event will the

device be damaged due to thermal overload because die

temperature is monitored continuously by on-chip

circuitry.

Micrel, Inc. MIC20xx Family

August 2011

23 M9999-080211-D

Application Information

Setting ILIMIT

The MIC2009/2019’s current limit is user programmable

and controlled by a resistor connected between the

ILIMIT pin and GND. The value of this resistor is

determined by the following equation:

SET

LIMIT R

LF)itFactor(CCurrentLim

(A)I

LF)itFactor(CCurrentLim

LIMIT

SET =

For example: Set ILIMIT = 1.25A

Looking in the Electrical specifications we will find CLF

at ILIMIT = 1A.

Min Typ Max Units

190 243 293 V

Table 1. CLF at ILIMIT = 1A

For the sake of this example, we will say the typical

value of CLF at an IOUT of 1A is 243V. Applying the

equation above:

Ω==Ω 4.194

1.25A

243V

)(RSET

RSET = 196

(the closest standard 1% value)

Designers should be aware that variations in the

measured ILIMIT for a given RSET resistor, will occur

because of small differences between individual ICs

(inherent in silicon processing) resulting in a spread of

ILIMIT values. In the example above we used the typical

value of CLF to calculate RSET. We can determine

ILIMIT’s spread by using the minimum and maximum

values of CLF and the calculated value of RSET.

A97.0

196

190V

ILIMIT_MIN =

1.5A

196

293V

ILIMIT_MAX ==

Giving us a maximum ILIMIT variation over temperature

of:

ILIMIT_MIN ILIMIT_TYP ILIMIT_MAX

0.97A (-22%) 1.25A 1.5A (+20%)

IOUT R

SET I

LIMIT_MIN I

LIMIT_MAX

0.1A 1928 0.063A 0.136A

0.2A 993 0.137A 0.265A

0.3A 673 0.216A 0.391A

0.4A 511 0.296A 0.515A

0.5A 413 0.379A 0.637A

0.6A 346 0.463A 0.759A

0.7A 299 0.548A 0.880A

0.8A 263 0.634A 1.001A

0.9A 235 0.722A 1.121A

Table 2. MIC20x9A RSET Table

IOUT R

SET I

LIMIT_MIN I

LIMIT_MAX

0.2A 1125 0.127A 0.267A

0.3A 765 0.202A 0.390A

0.4A 582 0.281A 0.510A

0.5A 470 0.361A 0.629A

0.6A 395 0.443A 0.746A

0.7A 341 0.526A 0.861A

0.8A 300 0.610A 0.976A

0.9A 268 0.695A 1.089A

1A 243 0.781A 1.202A

1.1A 222 0.868A 1.314A

1.2A 204 0.956A 1.426A

1.3A 189 1.044A 1.537A

1.4A 176 1.133A 1.647A

1.5A 165 1.222A 1.757A

Table 3. MIC20x9 RSET Table

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Micrel, Inc. MIC20xx Family

August 2011

24 M9999-080211-D

ILIMIT vs. IOUT Measured

The MIC20XX’s current-limiting circuitry, during current

limiting, is designed to act as a constant current source

to the load. As the load tries to pull more than the

allotted current, VOUT drops and the input to output

voltage differential increases. When VIN - VOUT exceeds

1V, IOUT drops below ILIMIT to reduce the drain of fault

current on the system’s power supply and to limit

internal heating of the switch.

When measuring IOUT it is important to bear this voltage

dependence in mind, otherwise the measurement data

may appear to indicate a problem when none really

exists. This voltage dependence is illustrated in Figures

4 and 5.

In Figure 4, output current is measured as VOUT is

pulled below VIN, with the test terminating when VOUT is

1V below VIN. Observe that once ILIMIT is reached IOUT

remains constant throughout the remainder of the test.

In Figure 5 this test is repeated but with VIN - VOUT

exceeding 1V.

When VIN - VOUT > 1V, switch’s current limiting circuitry

responds by decreasing IOUT, as can be seen in Figure

5. In this demonstration, VOUT is being controlled and

IOUT is the measured quantity. In real life applications

VOUT is determined in accordance with ’s law by the

load and the limiting current.

Figure 4. IOUT in Current Limiting for VIN - VOUT < 1V

Figure 5. IOUT in Current Limiting for VIN - VOUT > 1V

This folding back of ILIMIT can be generalized by plotting

ILIMIT as a function of VOUT, as shown below in Figures 6

and 7. The slope of VOUT between IOUT = 0V and IOUT =

ILIMIT (where ILIMIT = 1A) is determined by RON of the

switch and ILIMIT.

0.2

0.4

0.6

0.8

1.0

1.2

0123456

NORMALIZED OUTPUT CURRENT (A)

OUTPUT VOLTAGE (V)

Normalized Output Current

vs. Output Voltage (5V)

Figure 6. Normalized Output Current vs. Output Voltage

Micrel, Inc. MIC20xx Family

August 2011

25 M9999-080211-D

0.2

0.4

0.6

0.8

1.0

1.2

0 0.5 1.0 1.5 2.0 2.5 3.0

NORMALIZED OUTPUT CURRENT (A)

OUTPUT VOLTAGE (V)

Normalized Output Current

vs. Output Voltage (2.5V)

Figure 7. Normalized Output Current vs. Output Voltage

CSLEW

2003 2004

2005X 2006 2007 2008

2009X

2013 2014 2015 2016 2017 2018

2019X

Only parts in bold have CSLEW pin.

(Not available in 5-pin SOT-23 packages).

The CSLEW pin is provided to increase control of the

output voltage ramp at turn-on. This input allows

designers the option of decreasing the output’s slew

rate (slowing the voltage rise) by adding an external

capacitance between the CSLEW and VIN pins. This

capacitance slows the rate at which the pass FET gate

voltage increases and thus, slows both the response to

an Enable command as well as VOUT’s ascent to its final

value.

Figure 8 illustrates effect of CSLEW on turn-on delay and

output rise time.

0.002

0.004

0.006

0.008

0.01

0.012

0.014

0000000000

TIME (mS)

CSLEW (nF)

Typical Turn-on Times

vs. External CSLEW Capacitance

000.5 11.5 22.5 33.5 44.5

TRISE

TDELAY

TON

Figure 8. CSLEW vs. Turn-On, Delay and Rise Times

CSLEW’s Effect on ILIMIT

An unavoidable consequence of adding CSLEW

capacitance is a reduction in the MIC20X5 – 20X8’s

ability to quickly limit current transients or surges. A

sufficiently large capacitance can prevent both the

primary and secondary current limits from acting in time

to prevent damage to the MIC20X5 – 20X8 or the

system from a short circuit fault. For this reason, the

upper limit on the value of CSLEW is 4nF.

Variable Undervoltage Lock Out (VUVLO)

2003 2004 2005X

2006 2007 2008 2009X

2013 2014 2015 2016 2017 2018 2019X

Only parts in bold have VUVLO pin and functionality.

Power-conscious systems, such as those implementing

ACPI, will remain active even in their low-power states

and may require the support of external devices

through both phases of operation. Under these

conditions, the current allowed these external devices

may vary according to the system’s operating state and

as such require dual current limits on their peripheral

ports. The MIC20X6 is designed for systems

demanding two primary current limiting levels but

without the use of a control signal to select between

current limits.

To better understand how the MIC20X6 provides this,

imagine a system whose main power supply supports

heavy loads during normal operation, but in sleep mode

is reduced to only few hundred milliamps of output

current. In addition, this system has several USB ports

which must remain active during sleep. During normal

operation, each port can support a 500mA peripheral,

but in sleep mode their combined output current is

limited to what the power supply can deliver minus

whatever the system itself is drawing.

If a peripheral device is plugged in which demands

more current than is available, the system power supply

will sag, or crash. The MIC20X6 prevents this by

monitoring both the load current and VIN. During normal

operation, when the power supply can source plenty of

current, the MIC20X6 will support any load up to its

factory programmed current limit. When the weaker,

standby supply is in operation, the MIC20X6 monitors

VIN and will shut off its output should VIN dip below a

predetermined value. This predetermined voltage is

user programmable and set by the selection of the

resistor divider driving the VUVLO pin.

va mum (EmuV/dw) “W |_I

Micrel, Inc. MIC20xx Family

August 2011

26 M9999-080211-D

To prevent false triggering of the VUVLO feature, the

MIC20X6 includes a delay timer to blank out

momentary excursions below the VUVLO trip point. If

VIN stays below the VUVLO trip point for longer than

32ms (typical), then the load is disengaged and the

MIC20X6 will wait 128ms before reapplying power to

the load. If VIN remains below the VUVLO trip point,

then the load will be powered for the 32ms blanking

period and then again disengaged. This is illustrated in

the scope plot below. If VIN remains above the VUVLO

trip point MIC20X6 resumes normal operation.

Figure 9. VUVLO Operation

VUVLO and Kickstart™ operate independently in the

MIC2016. If the high-current surge allowed by

Kickstart™ causes VIN to dip below the VUVLO trip

point for more than 32ms, VUVLO will disengage the

load, even though the Kickstart™ timer has not timed

out.

VIN

MIC20X6

VOUT

VUVLO

Input

Supply

IIN_LOAD

Figure 10. VUVLO Application Circuit

Calculating VUVLO Resistor Divider Values

The VUVLO feature is designed to keep the internal

switch off until the voltage on the VUVLO pin is greater

than 0.25V. A resistor divider network connected to the

VUVLO and VIN pins is used to set the input trip

voltage VTRIP (see Figure 10). The value of R2 is

chosen to minimize the load on the input supply IDIV and

the value of R1 sets the trip voltage VTRIP.

The value of R2 is calculated using:

DIV

VUVLO

2R =

The vale of R1 is calculated using:

⎟

⎠

⎞

⎜

⎝

⎛−×= 1

R2R1

VUVLO

TRIP

Where for both equations:

VVUVLO = 0.25V

When working with large value resistors, a small

amount of leakage current from the VUVLO terminal

can cause voltage offsets that degrade system

accuracy. Therefore, the maximum recommended

resistor value for R2 is 100k.

Using the divider loading current IDIV of 100µA, the

value of R2 can be estimated by:

Ω== k5.2

µA100

V25.0

Now the value of R1 can be calculated by:

k451

V25.0

V75.4

k5.21R =

⎟

⎠

⎞

⎜

⎝

⎛−×Ω=

where:

VTRIP = 4.75V (for a 5V supply)

VVUVLO = 0.25V

mm mm

Micrel, Inc. MIC20xx Family

August 2011

27 M9999-080211-D

The VUVLO comparator uses no hysteresis. This is

because the VUVLO blanking timer prevents any

chattering that might otherwise occur if VIN varies about

the trigger point. The timer is reset by upward crossings

of the trip point such that VIN must remain below the trip

point for the full 32ms period for load disengagement to

occur.

In selecting a VTRIP voltage, the designer is cautioned to

not make this value less than 2.5V. A minimum of 2.5V

is required for the MIC20X6’s internal circuitry to

operate properly. VUVLO trip points below 2.5V will

result in erratic or unpredictable operation.

Kickstart™

2003 2004 2005X 2006 2007 2008 2009X

2013 2014 2015 2016 2017 2018 2019X

Only parts in bold have Kickstart™.

(Not available in 5-pin SOT-23 packages).

Kickstart™ allows brief current surges to pass to the

load before the onset of normal current limiting, which

permits dynamic loads to draw bursts of energy without

sacrificing system safety.

Functionally, Kickstart™ is a forced override of the

normal current limiting function provided by the switch.

The Kickstart™ period is governed by an internal timer

which allows current to pass up to the secondary

current limit (ILIMIT_2nd) to the load for 128ms and then

normal (primary) current limiting goes into action.

During Kickstart™, a secondary current-limiting circuit

is monitoring output current to prevent damage to the

switch, as a hard short combined with a robust power

supply can result in currents of many tens of amperes.

This secondary current limit is nominally set at 4A and

reacts immediately and independently of the Kickstart™

period. Once the Kickstart™ timer has finished its count

the primary current limiting circuit takes over and holds

IOUT to its programmed limit for as long as the excessive

load persists.

Once the switch drops out of current limiting the

Kickstart™ timer initiates a lock-out period of 128ms

such that no further bursts of current above the primary

current limit, will be allowed until the lock-out period has

expired.

Kickstart™ may be over-ridden by the thermal

protection circuit and if sufficient internal heating

occurs, Kickstart™ will be terminated and IOUT Æ 0A.

Upon cooling, if the load is still present IOUT Æ ILIMIT, not

ILIMIT_2nd.

Figure 11. Kickstart™

Automatic Load Discharge

2003 2004 2005X 2006 2007 2008 2009X

2013 2014 2015 2016 2017 2018 2019X

Only parts in bold have automatic load discharge.

Automatic discharge is a valuable feature when it is

desirable to quickly remove charge from the VOUT pin.

This allows for a quicker power-down of the load. This

also prevents any charge from being presented to a

device being connected to the VOUT pin, for example,

USB, 1394, PCMCIA, and CableCARD™.

Automatic discharge is performed by a shunt MOSFET

from VOUT pin to GND. When the switch is disabled, a

break before make action is performed turning off the

main power MOSFET and then enabling the shunt

MOSFET. The total resistance of the MOSFET and

internal resistances is typically 126.

Supply Filtering

A minimum 1F bypass capacitor positioned close to

the VIN and GND pins of the switch is both good design

practice and required for proper operation of the switch.

This will control supply transients and ringing. Without a

bypass capacitor, large current surges or a short may

cause sufficient ringing on VIN (from supply lead

inductance) to cause erratic operation of the switch’s

control circuitry. For best-performance good quality,

low-ESR capacitors are recommended, preferably

ceramic.

When bypassing with capacitors of 10F and up, it is

good practice to place a smaller value capacitor in

parallel with the larger to handle the high frequency

components of any line transients. Values in the range

of 0.01F to 0.1F are recommended. Again, good

quality, low-ESR capacitors should be chosen.

EL mag/Emma? ma

Micrel, Inc. MIC20xx Family

August 2011

28 M9999-080211-D

In Figure 12, die temperature is plotted against IOUT

assuming a constant case temperature of 85°C. The

plots also assume a worst case RON of 140m at a die

temperature of 135°C. Under these conditions it is clear

that an SOT-23 packaged device will be on the verge of

thermal shutdown, typically 140°C die temperature,

when operating at a load current of 1.25A. For this

reason we recommend using MLF® packaged switches

for any design intending to supply continuous currents

of 1A or more.

Power Dissipation

Power dissipation depends on several factors such as

the load, PCB layout, ambient temperature, and supply

voltage. Calculation of power dissipation can be

accomplished by the following equation:

)I(RP OUT)ON(DSD ×

To relate this to junction temperature, the following

equation can be used:

100

120

140

160

0.2

OUTPUT CURRENT (A)

Die Temperature vs.

Output Current (T CASE=85°C)

SOT-23

0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0

MLF

)AJ(

DJ TRPT +×= −

where:

TJ = junction temperature

TA = ambient temperature

Rθ(J-A) is the thermal resistance of the package

In normal operation the switch’s RON is low enough that

no significant I2R heating occurs. Device heating is

most often caused by a short circuit, or very-heavy

load, when a significant portion of the input supply

voltage appears across the switch’s power MOSFET.

Under these conditions the heat generated will exceed

the package and PCB’s ability to cool the device and

thermal limiting will be invoked.

Figure 12. Die Temperature vs. IOUT

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Micrel, Inc. MIC20xx Family

August 2011

29 M9999-080211-D

Package Information

5-Pin SOT-23 (M5)

6-Pin SOT-23 (M6)

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Micrel, Inc. MIC20xx Family

August 2011

30 M9999-080211-D

Package Information (Continued)

6 Pin 2mm x 2mm MLF® (ML)

Section 1.01 MICREL, INC. 2180 FORTUNE DRIVE SAN JOSE, CA 95131 USA

TEL +1 (408) 944-0800 FAX +1 (408) 474-1000 WEB http://www.micrel.com

Micrel makes no representations or warranties with respect to the accuracy or completeness of the information furnished in this data sheet. This

information is not intended as a warranty and Micrel does not assume responsibility for its use. Micrel reserves the right to change circuitry,

specifications and descriptions at any time without notice. No license, whether express, implied, arising by estoppel or otherwise, to any intellectual

property rights is granted by this document. Except as provided in Micrel’s terms and conditions of sale for such products, Micrel assumes no liability

whatsoever, and Micrel disclaims any express or implied warranty relating to the sale and/or use of Micrel products including liability or warranties

relating to fitness for a particular purpose, merchantability, or infringement of any patent, copyright or other intellectual property right.

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

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

into the body or (b) support or sustain life, and whose failure to perform can be reasonably expected to result in a significant injury to the user. A

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

indemnify Micrel for any damages resulting from such use or sale.

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