JANTX1N963BUR-1/TR - MICROSEMI - Datasheet.Directory

DESCRIPTION

The A6214 is a single-IC switching regulator that provides

constant-current output to drive high-power LEDs. It integrates

a high-side N-channel DMOS switch for DC-to-DC step- down

(buck) conversion. A true average current is output using a

cycle-by-cycle, controlled on-time method.

Output current is user-selectable by an external current sense

resistor. Output voltage is automatically adjusted to drive

various numbers of LEDs in a single string. This ensures the

optimal system efficiency.

LED dimming is accomplished by a direct logic input

pulse-width-modulation (PWM) signal at the Enable pin.

Alternatively, an Analog Dimming input can be used to calibrate

the LED current, or implement thermal foldback in conjunction

with external NTC thermistor.

The A6216 has the added capability to generate its own PWM

dimming frequency and duty cycle in stand-alone mode.

The A6214 is provided in a compact 10-pin narrow SOIC

package (suffix LK). The A6216 is in 16-pin TSSOP (suffix

LP), both with exposed pad for enhanced thermal dissipation.

It is lead (Pb) free, with 100% matte-tin leadframe plating.

A6214-16-DS, Rev. 4

FEATURES AND BENEFITS

• AEC-Q100 qualified

• Supply voltage 4.5 to 55 V

• 2 A maximum output over operating temperature range

• Integrated MOSFET switch

• Able to use either Schottky or silicon low-side diode

• True average output current control

• Internal control loop compensation

• Integrated 5 V, 10 mA regulator for driving external load

• PWM dimming via direct logic input down to 0.1% at 200 Hz

• Standalone internal PWM dimming (A6216)

• Analog dimming for brightness calibration and thermal

foldback

• Low-power shutdown (1 µA typical)

• Fault flag output (A6216)

• LED string open and short protection

• Cycle-by-cycle current limit

• Undervoltage lockout (UVLO) and thermal shutdown (TSD)

• Robust protection against:

□Adjacent pin-to-pin short

□Pin-to-GND short

□Component open/short faults

Automotive-Grade, Constant-Current 2 A

PWM Dimmable Buck Regulator LED Driver

PACKAGES:

Not to scale

A6214 and A6216

Figure 1: A6214 (LK Package) Typical Application Circuit

APPLICATIONS:

Automotive lighting

• Daytime running lights

• Front and rear fog lights

• Turn/stop lights

• Map light

• Dimmable interior lights

January 21, 2013

A6214: 10-Pin SOICN (suffix LK)

A6216: 16-Pin eTSSOP (suffix LP)

Not to scale

LED+

GND

(4.5 to 55 V)

EN/PWM

BOOT

SENSE

GND

BOOT

GND

CSH

CSL

VIN

TON

ADIM

VCC

A6214

ADIM

External PWM

dimming signal

External analog

dimming signal

LED

November 1, 2016

Automotive-Grade, Constant-Current 2 A

PWM Dimmable Buck Regulator LED Driver

A6214 and

A6216

Allegro MicroSystems, LLC

115 Northeast Cutoff

Worcester, Massachusetts 01615-0036 U.S.A.

1.508.853.5000; www.allegromicro.com

SELECTION GUIDE

Part Number Internal PWM and

FAULT Flag Package Packing

A6214KLKTR-T No 10-pin SOICN with exposed thermal pad 3000 pieces per 13-in reel

A6216KLPTR-T Yes 16-pin TSSOP with exposed thermal pad 4000 pieces per 13-in reel

Table of Contents

Features and Benefits 1

Description 1

Applications 1

Packages 1

Typical Application Circuit (A6214) 1

Typical Application Circuit (A6216) 2

Selection Guide 2

Specifications 3

Absolute Maximum Ratings 3

Thermal Characteristics 3

Pinout Diagrams and Terminal List Tables 4

Functional Block Diagrams 5

Electrical Characteristics 7

Characteristic Performance 9

Functional Description 11

Application Circuit Diagrams 18

System Failure Detection and Protection 21

Package Outline Drawings 23

Figure 2: A6216 (LP Package) Typical Application Circuit

LED+

GND

(4.5 to 55 V)

EN/PWM

GND

ADIM

R1*

* R1, R2, R3 used in stand-alone

mode for internal PWM dimming

VCC

FAULT

External PWM

dimming signal

External analog

dimming signal

RANGE

BOOT

GND

CSH

CSL

FULL

TON

EN/PWM

ADIM

VCC

A6216

GND FPWM

FAULT

VIN

FULL

FULL = “HIGH” = 100% Duty Cycle

FULL = “LOW” = DR controls Duty Cycle

RANGE

RANGE = “HIGH” = 0 to 100% Duty Cycle

RANGE = “LOW” = 0 to 30% Duty Cycle

BIAS

R2* R3*

BOOT

LED

SENSE

Automotive-Grade, Constant-Current 2 A

PWM Dimmable Buck Regulator LED Driver

A6214 and

A6216

Allegro MicroSystems, LLC

115 Northeast Cutoff

Worcester, Massachusetts 01615-0036 U.S.A.

1.508.853.5000; www.allegromicro.com

ABSOLUTE MAXIMUM RATINGS

Characteristic Symbol Notes Rating Unit

Supply Voltage VIN –0.3 to 60 V

Bootstrap Drive Voltage VBOOT –0.3 to VIN + 8 V

Switching Voltage VSW

Continuous –1.5 to VIN + 0.3 V

Pulsed, t < 20 ns –0.3 to VIN + 3 V

Enable and TON Voltage VEN , VTON –0.3 to VIN + 0.3 V

Linear Regulator Terminal VCC –0.3 to 7 V

ADIM Pin Voltage VADIM –0.3 to 7 V

Current Sense Voltages VCSH, VCSL –0.3 to VIN + 0.3 V

FAULT, FULL, RANGE, and

FPWM Voltages

VFAULT, VFULL,

VRANGE, VFPWM

A6216 only –0.3 to 7 V

DR Pin Voltage VDR

A6216 only; DR pin voltage must not be higher

than VCC even when device is off (VCC = 0 V) –0.3 to VCC + 0.3 V

Operating Ambient Temperature TAK temperature range for automotive –40 to 125 °C

Maximum Junction Temperature TJ(max) 150 °C

Storage Temperature Tstg –55 to 150 °C

THERMAL CHARACTERISTICS*: May require derating at maximum conditions; see application section for optimization

Characteristic Symbol Test Conditions* Value Unit

Package Thermal Resistance

(Junction to Ambient) RθJA

A6214 Package LK On 4-layer PCB based on JEDEC standard 35 °C/W

A6216 Package LP

On 4-layer PCB based on JEDEC standard 34 °C/W

On 2-layer PCB with 3.8 in.2 of copper area each side 43 °C/W

Package Thermal Resistance

(Junction to Pad) RθJP 2 °C/W

*Additional thermal information available on the Allegro™ website.

SPECIFICATIONS

Automotive-Grade, Constant-Current 2 A

PWM Dimmable Buck Regulator LED Driver

A6214 and

A6216

Allegro MicroSystems, LLC

115 Northeast Cutoff

Worcester, Massachusetts 01615-0036 U.S.A.

1.508.853.5000; www.allegromicro.com

Pinout Diagram for A6214

(LK Package)

Terminal List Table for A6214 (LK Package)

Number Name Function

1 VIN Supply voltage input voltage for IC and buck regulator

2TON Regulator on-time setting resistor terminal. Connect a resistor

between VIN and TON to set the switching frequency.

3 EN/PWM Logic input for Enable and PWM dimming

4 ADIM Analog dimming control voltage input

5 VCC Internal IC bias regulator output. Connect 1uF MLCC to GND.

Can be used to supply up to 10mA for external load.

6 GND Ground terminal

7 CSL Current Sense (Lower end) feedback input for LED current

8 CSH Current Sense (Higher end) feedback input for LED current

9 BOOT DMOS gate driver bootstrap terminal

10 SW Switched output terminal

-PAD Exposed pad for enhanced thermal dissipation; connect to GND

Pinout Diagram for A6216

(LP Package)

VIN

TON

ADIM

VCC

BOOT

CSH

CSL

GND

PAD

VIN

TON

EN/PWM

ADIM

VCC

GND

FULL

BOOT

CSH

CSL

GND

FAULT

FPWM

RANGE

PAD

Terminal List Table for A6216 (LP Package)

Number Name Function

1 VIN Supply voltage input voltage for IC and buck regulator

2TON Regulator on-time setting resistor terminal. Connect a resistor

between VIN and TON to set the switching frequency

3 EN/PWM Logic input for Enable and PWM dimming

4 ADIM Analog dimming control voltage input

5 VCC Internal IC bias regulator output. Connect 1uF MLCC to GND.

Can be used to supply up to 10mA for external load

6 DR Dimming Ratio control. In stand-alone mode: connect to resistor

divider network from VCC to set the dimming PWM duty cycle

7 GND Ground terminal

8 FULL Selects 100% dimming duty cycle or DR control of duty cycle

9 RANGE Selects DR control range, high range gives DR control from 5%

to 100%, low range gives DR control from 5% to 33%.

10 FPWM Dimming PWM frequency control. In stand-alone mode, connect

a resistor to GND to set the dimming PWM frequency

11 FAULT Open-drain output which is pulled low in case of fault. Connect

through an external pull-up resistor to the desired logic level.

12 GND Ground terminal

13 CSL Current Sense (Lower end) feedback input for LED current

14 CSH Current Sense (Higher end) feedback input for LED current

15 BOOT DMOS gate driver bootstrap terminal

16 SW Switched output terminal

-PAD Exposed pad for enhanced thermal dissipation; connect to GND

Automotive-Grade, Constant-Current 2 A

PWM Dimmable Buck Regulator LED Driver

A6214 and

A6216

Allegro MicroSystems, LLC

115 Northeast Cutoff

Worcester, Massachusetts 01615-0036 U.S.A.

1.508.853.5000; www.allegromicro.com

FUNCTIONAL BLOCK DIAGRAMS

Figure 3: Simplied Functional Block Diagram for A6214

LED+

GND

BOOT

GND

CSH

CSL

VCC

On-Time

Select

Duty

Cycle

Control

LDO

Enable

Internal 5 V

LED

Reference

ADIM

adj

is optional. It can be used to fine-adjust the LED current

in case the desired value of R

SENSE

is not available.

A6214

(4.5 to 55 V)

adj C

LED

RSENSE

EN/PWM

VOUT VCC

VIN

TON

EN/PWM

VIN

On-Time

CBIAS

VREF

BOOT

VOUT

Automotive-Grade, Constant-Current 2 A

PWM Dimmable Buck Regulator LED Driver

A6214 and

A6216

Allegro MicroSystems, LLC

115 Northeast Cutoff

Worcester, Massachusetts 01615-0036 U.S.A.

1.508.853.5000; www.allegromicro.com

Figure 4: Simplied Functional Block Diagram for A6216

LED+

GND

BOOT

GND

CSH

CSL

TON

VCC

VIN

LDO

ADIM

FAULT

Mode

FAULT

OSC

FPWM

Enable

FPWM

Up to 10 mA

external load

RANGE

FULL

A6216

VCC

(4.5 to 55 V)

On-Time

Select

VOUT

CBIAS

Internal

5 V bias

VIN

EN/PWM

VCC

Internal PWM

Duty Cycle

Generator

(200 Hz to 1 kHz)

VREF

(0 to 200 mV)

LED

Reference

Buck

Converter

Duty Cycle

Control

On-Time

LED

Current

Differential

Amp

Gate

Driver

BOOT

VCC

RSENSE

adj

LED

VOUT

Automotive-Grade, Constant-Current 2 A

PWM Dimmable Buck Regulator LED Driver

A6214 and

A6216

Allegro MicroSystems, LLC

115 Northeast Cutoff

Worcester, Massachusetts 01615-0036 U.S.A.

1.508.853.5000; www.allegromicro.com

ELECTRICAL CHARACTERISTICS: Valid at VIN = 12 V, VOUT = 6 V, TA = –40°C to 125°C, typical values at TA = 25°C, unless

otherwise noted

Characteristics Symbol Test Conditions Min. Typ. Max. Unit

Input Supply Voltage VIN 4.5 – 55 V

VIN Undervoltage Lockout Threshold VUVLO VIN increasing – – 4.3 V

VIN Undervoltage Lockout Hysteresis VUVLO

HYS VIN decreasing – 150 300 mV

VIN Pin Supply Current IIN VCSH – VCSL = 0.5 V, EN = VIH, RON = 402 kΩ – 5 – mA

VIN Pin Shutdown Current IINSD EN = VIL – 1 10 µA

Buck Switch Current Limit Threshold ISWLIM 2.5 3.25 4 A

Buck Switch On-Resistance RDS(on) VBOOT = VIN + 4.3 V, TA = 25°C, ISW = 0.5 A – 0.25 0.4 Ω

BOOT Undervoltage Lockout

Threshold VBOOTUV VBOOT to VSW increasing 3.1 3.4 3.7 V

BOOT Undervoltage Lockout

Hysteresis VBOTUVHYS VBOOT to VSW decreasing – 750 – mV

Switching Minimum Off-Time tOFFmin VCSH – VCSL = 0 V – 75 100 ns

Switching Minimum On-Time tONmin VCSH – VCSL = 0.3 V – 75 100 ns

Selected On-Time tON RON = 402 kΩ 800 1000 1200 ns

REGULATION COMPARATOR AND ERROR AMPLIFIER

Load Current Sense Regulation

Threshold at 100%

1VCSREG

VCSH – VCSL decreasing, SW turns on, ADIM

tied to VCC 194 200 206 mV

Output Current Sense Common

Mode Voltage (measured at CSL pin) VOUT VIN = 55 V, fSW = 500 kHz, iLED = 0.5 A 2.65 – 50 V

CSH Input Sense Current ICSH VCSH – VCSL = 0.2 V – –190 – µA

CSL Input Sense Current ICSL VCSH – VCSL = 0.2 V 50 75 100 µA

INTERNAL LINEAR REGULATOR

VCC Regulated Output VCC 0 mA < ICC < 5 mA, VIN > 6 V 4.85 5 5.15 V

VCC Current Limit

2iVCCLIM VCC ≥ 4.75 V 10 20 – mA

VCC Dropout Voltage VLDO Measure VIN – VCC. VIN = 5 V, iVCC = 9 mA – 0.15 0.35 V

ENABLE/PWM INPUT

Logic High Voltage VIH VEN increasing 1.8 – – V

Logic Low Voltage VIL VEN decreasing – – 0.4 V

EN Pin Pull-down Resistance RENPD VEN = 5 V – 100 – kΩ

Maximum PWM Dimming Off-Time tPWML

Measured while EN = low, during dimming

control, and internal references are powered-on

(exceeding tPWML results in shutdown)

10 17 – ms

INTERNAL PWM DIMMING (A6216 ONLY)

Internal PWM Dimming Frequency fPWM External RFPWM = 30 kΩ from FPWM pin to GND 180 200 220 Hz

FULL, RANGE Pins Input Low Voltage VIL – – 0.8 V

FULL, RANGE Pins Input High Voltage VIH 2 – – V

Internal PWM Duty Cycle

DPWM5(L)

VDR driven by resistor divider from VCC,

VCC / VDR = 9.72, fPWM = 200 Hz, RANGE = low 4.75 5 5.25 %

DPWM5(H)

VDR driven by resistor divider from VCC,

VCC / VDR = 29.2, fPWM = 200 Hz, RANGE = high 4.5 5 5.5 %

DPWM90(H)

VDR driven by resistor divider from VCC,

VCC / VDR = 1.62, fPWM = 200 Hz, RANGE = high 87 90 93 %

Continued on the next page…

Automotive-Grade, Constant-Current 2 A

PWM Dimmable Buck Regulator LED Driver

A6214 and

A6216

Allegro MicroSystems, LLC

115 Northeast Cutoff

Worcester, Massachusetts 01615-0036 U.S.A.

1.508.853.5000; www.allegromicro.com

Characteristics Symbol Test Conditions Min. Typ. Max. Unit

ANALOG DIMMING INPUT

Input Voltage for 100% LED Current VADIMH VCSH – VCSL = VCSREG 2.1 – – V

Regulation Threshold at 50% Analog

Dimming VCSREG50 VADIM = 1 V – 100 – mV

Regulaton Threshold at 20% Analog

Dimming VCSREG20 VADIM = 0.4 V 38.4 40 41.4 mV

FAULT PIN (A6216 ONLY)

FAULT Pull-Down Voltage VFAULT(PD) Fault condition asserted, pull-up current = 1 mA – – 0.4 V

FAULT Pin Leakage Current VFAULT(LKG) Fault condition cleared, pull-up to 5 V – – 1 µA

TIMERS

Cool Down Timer for Fault Retry tRETRY – 1 – ms

Delay Timer for Reporting LED Open

Fault tOPEN – 50 – µs

THERMAL SHUTDOWN

Thermal Shutdown Threshold

3TSD 150 165 180 °C

Thermal Shutdown Hysteresis TSDHYS – 25 – °C

1 In test mode, a ramp signal is applied across CSH and CSL pins to determine the CS regulation threshold voltage. In actual application, the average

CS voltage is regulated at VCSREG regardless of ripple voltage.

2 The internal linear regulator is capable of supplying up to 10 mA to external devices.

3 Determined by design and characterization. Not production tested.

ELECTRICAL CHARACTERISTICS (continued): Valid at VIN = 12 V, VOUT = 6 V, TA = –40°C to 125°C, typical values at

TA = 25°C, unless otherwise noted

Automotive-Grade, Constant-Current 2 A

PWM Dimmable Buck Regulator LED Driver

A6214 and

A6216

Allegro MicroSystems, LLC

115 Northeast Cutoff

Worcester, Massachusetts 01615-0036 U.S.A.

1.508.853.5000; www.allegromicro.com

CHARACTERISTIC PERFORMANCE

100

0 0.4 0.8 1.2 1.6 2 2.4 2.8 3.2 3.6 4

Duty Cycle (%)

VDR (V)

Internal PWM Duty Cycle vs DR Pin Voltage

(VIN = 12 V, VOUT = 6 V, RTON = 300 kΩ, fPWM = 300 Hz, TA = 25ºC)

Measured for RANGE=H

Target for RANGE=H

Measured for RANGE=L

Target for RANGE=L

20%

40%

60%

80%

100%

0 0.4 0.8 1.2 1.6 2 2.4

Normalized LED Current (%)

ADIM Voltage (V)

Normalized LED Current vs ADIM Voltage

(VIN = 12 V, VOUT = 6 V, iLED = 1 A, TA = 25°C)

Measured Current

Target

Figure 5: Analog Dimming Performance –

LED current can be reduced linearly down to 10%

using the ADIM pin voltage.

Figure 6: PWM Dimming Performance –

Duty cycle down to ~0.1% (1000:1) can be achieved

with higher VIN or lower inductance.

Figure 7: Internal PWM Dimming Operation (A6216 only) –

Duty cycle is controlled by the voltage at DR pin.

Figure 8: Internal PWM Dimming Frequency

(A6216 only) as a function of FPWM Resistance

0.001

0.01

0.1

0.1 1 10 100

Normalize LED Current

PWM Duty Cycle (%)

Average LED Current vs. PWM Duty Cycle

(RTON = 442 kΩ, load = 2× LED at 1.5 A, fPWM = 200 Hz)

VIN = 24 V, L = 47 µH

VIN = 12 V, L = 22 µH

VIN = 12 V, L = 47 µH

Ideal

200

400

600

800

1000

1200

1400

1600

0 10 20 30

fPWM (Hz)

RFPWM (kΩ)

Frequency of Internal PWM vs. FPWM Resistance

(VIN = 12 V, VOUT = 6 V, VDR = 1.7 V, TA= 25°C)

Calculated

Measured

Automotive-Grade, Constant-Current 2 A

PWM Dimmable Buck Regulator LED Driver

A6214 and

A6216

Allegro MicroSystems, LLC

115 Northeast Cutoff

Worcester, Massachusetts 01615-0036 U.S.A.

1.508.853.5000; www.allegromicro.com

CHARACTERISTIC PERFORMANCE (continued)

Figure 9: Startup for PWM Dimming operation –

RTON = 442 kΩ, L = 22 µH, VIN = 12 V, Output = 2× LED at

1.5 A, PWM = 1 kHz 50%. Note that there is a ~150 µs delay

for the rst PWM = H pulse, but none for subsequent pulses.

Figure 10: PWM Dimming with on-time of just 10 µs –

RTON = 442 kΩ, L = 22 µH, VIN = 12 V, Output = 2× LED at

1 A. Note that the LED current takes ~5µs to ramp up to

its steady-state value.

CH1 = VPWM (5 V/div)

CH2 = VSW (5 V/div)

CH3 = VOUT (5 V/div)

CH4 = iLED (500 mA/div)

Time Scale= 500 µs/div

CH1 = VPWM (5 V/div)

CH2 = VSW (5 V/div)

CH3 = VOUT (5 V/div)

CH4 = iLED (500 mA/div)

Time Scale= 5 µs/div

Automotive-Grade, Constant-Current 2 A

PWM Dimmable Buck Regulator LED Driver

A6214 and

A6216

Allegro MicroSystems, LLC

115 Northeast Cutoff

Worcester, Massachusetts 01615-0036 U.S.A.

1.508.853.5000; www.allegromicro.com

The A6214 is a buck regulator designed for driving a high-current

LED string. It utilizes average current mode control to maintain

constant LED current and consistent brightness. The LED current

level is easily programmable by selection of an external sense

resistor, with a value determined as follows:

RSENSE = VCSREG / iLED

where VCSREG = VCSH – VCSL = 0.2 V typical.

If necessary, a resistor can be inserted in series with the CSL pin

to fine-tune the LED current, as shown below:

CSH

CSL Radj RSENSE

VCSREG

VSENSE

–

iLED

iCSH

iCSL

– +

iCSL × Radj

VCSREG = iLED × RSENSE + iCSL × Radj

Therefore

iLED = (VCSREG – iCSL × Radj) / RSENSE

Figure 11: How To Fine-Tune LED Current Using Radj

For example, with a desired LED current of 1.4 A, the required

RSENSE = 0.2 V / 1.4 A = 0.143 Ω. But the closest power resistor

available is 0.13 Ω. Therefore, the difference is

Radj × iCSL = 0.2 V – 1.4 A × 0.13 Ω = 0.018 V

where iCSL = 75 µA typical

Radj = 0.018 V / 75 µA = 240 Ω

The LED current is further modulated by the ADIM (Analog

Dimming) pin voltage. This feature can be used for LED bright-

ness calibration, or for thermal foldback protection. See Analog

Dimming section for details.

Switching Frequency

The A6214 operates in fixed on-time mode during switching. The

on-time (and hence switching frequency) is programmed using

an external resistor connected between the VIN and TON pins, as

given by the following equation:

tON = k × (RTON + RINT ) × ( VOUT / VIN )

fSW = 1 / [ k × (RTON + RINT )]

where k = 0.00434, with fSW in MHz, tON in µs, and RON and

RINT (internal resistance, 20 kΩ) in kΩ.

200

400

600

800

1000

1200

1400

1600

1800

2000

2200

0 100 200 300 400 500 600 700 800 900 1000

fSW (kHz)

RTON (kΩ)

Figure 12: Switching Frequency vs. TON resistance

ENABLE AND DIMMING

The IC is activated when a logic high signal is applied to the EN

(enable) pin. The buck converter ramps up the LED current to a

target level set by RSENSE.

When the EN pin is forced from high to low, the buck converter

is turned off, but the IC remains in standby mode for up to 10 ms.

If EN goes high again within this period, the LED current is

turned on immediately. Active dimming of the LED is achieved

by sending a PWM (pulse-width modulation) signal to the EN

pin. The resulting LED brightness is proportional to the duty cycle

(tON

/ Period) of the PWM signal. A practical range for PWM dim-

ming frequency is between 100 Hz (Period = 10 ms) and 2 kHz.

If EN is low for more than 17 ms, the IC enters shutdown mode

to reduce power consumption. The next high signal on EN will

initialize a full startup sequence, which includes a startup delay

of approximately 150 µs. This startup delay is not present during

PWM operation.

The EN pin is high-voltage tolerant and can be directly connected

to a power supply. However, if EN is higher than the VIN voltage

at any time, a series resistor (1-10 kΩ) is required to limit the cur-

rent flowing into the EN pin. This series resistor is not necessary

if EN is driven from a logic input.

FUNCTIONAL DESCRIPTION

Automotive-Grade, Constant-Current 2 A

PWM Dimmable Buck Regulator LED Driver

A6214 and

A6216

Allegro MicroSystems, LLC

115 Northeast Cutoff

Worcester, Massachusetts 01615-0036 U.S.A.

1.508.853.5000; www.allegromicro.com

PWM DIMMING RATIO

The brightness of the LED string can be reduced by adjusting the

PWM duty cycle at the EN pin as follows:

Dimming ratio = PWM on-time / PWM period

For example, by selecting a PWM period of 5 ms (200 Hz PWM

frequency) and a PWM on-time of 5 µs, a dimming ratio of 0.1%

can be achieved. This is sometimes referred to as “1000:1 dim-

ming.”

In an actual application, the minimum dimming ratio is deter-

mined by various system parameters, including: VIN

, VOUT

inductance, LED current, switching frequency, and PWM

frequency. As a general guideline, the minimum PWM on-time

should be kept at 5 µs or longer. A shorter PWM on-time is

acceptable under more favorable operating conditions, such as

higher VIN and lower inductance.

INTERNAL PWM DIMMING (A6216 ONLY)

In addition to external PWM dimming through EN pin, the

A6216 is able to generate an internal PWM dimming signal in

stand-alone mode. Frequency of the internal PWM signal can be

set by connecting a resistor between FPWM pin and GND, as

given by the following equation:

fPWM = c / (RFPWM + RINT)

where c = 6400, with fPWM in Hz, and RFPWM and RINT (internal

resistance, 0.5 kΩ) in kΩ.

This frequency can be between 200 Hz and 1 kHz when RANGE

is High, or 200 Hz and 500 Hz when RANGE is Low. Duty cycle

of PWM signal is linearly proportion to the voltage at DR (Dim-

ming Ratio) pin. This is illustrated by the following chart:

DR pin

voltage (V)

3.43

90%

Internal PWM

Duty Cycle

0.17

100%

3.080 V

30%

RANGE = High

RANGE = Low

0.514 5~4

33%

Figure 13: Variation of PWM Duty Cycle

with respect to DR Pin Voltage

It should be noted that the internal PWM duty cycle depends on

the ratio between VCC and VDR. The voltages shown in the chart

are with VCC = 5 V. For better accuracy, derive the DR pin volt-

age using a resistor divider connected between VCC and GND.

A practical range of internal PWM duty cycle when RANGE =

High is between 5% (VDR = 0.17 V) and 90% (VDR = 3.08 V).

To improve accuracy at low duty cycles between 5% and 30%,

set RANGE to Low. If DR pin is above 3.4 V, duty cycle stays at

around 99% if RANGE = High, 33% if Low.

To disable internal PWM generation, tie DR pin to VCC pin. (Do

NOT leave DR pin floating or connected to GND.) The FPWM

pin can be either left open, or tied to VCC. Note that at any time

during stand-alone PWM dimming mode, if EN pin goes low, the

LED is turned off immediately. This is illustrated in figure below.

Internal PWM

External PWM

(EN pin)

LED Current

Figure 14: LED Current when Both Internal and Exter-

nal PWM Dimming Signals are Applied

ANALOG DIMMING

In addition to PWM dimming, the A6214/16 also provides an

analog dimming feature. When V

ADIM is over 2 V, the LED cur-

rent is at 100% level (as defined by the SENSE resistor). When

ADIM is below 2 V, the LED current decreases linearly down to

20% at V

ADIM = 0.4 V. This is shown in the following figure:

ADIM pin

voltage

2 V

200 mV

±6 mV

(100%)

0.4 V

40 mV

100 mV

1 V

VCSREG

Figure 15: ADIM Pin Voltage Controls SENSE Reference

Voltage (hence LED current)

It is possible to pull ADIM pin below 0.4 V to achieve lower

than 20% analog dimming. However, the linearity may suffer if

the LED ripple current become too large compared to the aver-

age current. For example, if the LED ripple current is ±100 mA,

then the average current can only be dimmed down to 100 mA

linearly.

Automotive-Grade, Constant-Current 2 A

PWM Dimmable Buck Regulator LED Driver

A6214 and

A6216

Allegro MicroSystems, LLC

115 Northeast Cutoff

Worcester, Massachusetts 01615-0036 U.S.A.

1.508.853.5000; www.allegromicro.com

ADIM pin can be used in conjunction with PWM dimming to

provide wider LED dimming range over 1000:1. In addition, the

IC can provide thermal foldback protection by using an external

NTC (negative temperature coefficient) thermistor, as shown

below:

NTC

VCC

ADIM

Figure 16: Using an External NTC Thermistor

to Implement Thermal Foldback

If analog dimming is not required, the ADIM pin must be con-

nected to VCC pin. (Do NOT leave ADIM pin floating or con-

nected to GND.)

OUTPUT VOLTAGE AND DUTY CYCLE

The figure below provides simplified equations for approximat-

ing output voltage. The output voltage of a buck converter is

approximately given as:

VOUT = VIN × D – VD × (1 – D ) ≈ VIN × D, if VD << V IN

D = tON / (tON + tOFF )

where D is the duty cycle, and VD is the forward drop of the

diode D1 (typically under 0.5 V for Schottky diode).

During SW on-time:

iRIPPLE = (VIN – VOUT) / L × tON = (VIN – VOUT) / L × t × D

where D = tON / t.

During SW off-time:

iRIPPLE = (VOUT + VD) / L × tOFF = (VOUT + VD) / L × t × (1 – D)

Simplified equation for output voltage:

VOUT = VIN × D – VD × (1 – D)

If VD << VIN, then VOUT = VIN × D approximately.

More precisely:

VOUT = (VIN – iAVG × RDS(on)) × D – VD × (1 – D) – iAVG × (DCR + RSC)

where DCR is ther internal resistance of inductor and RSC is the

sense resistance.

VIN

VOUT

GND

MOS

CIN

iLRSC

VSW

VIN

tON

Period, t

–VD

tOFF

iRIPPLE

Figure 17: Simplied Waveforms for a Buck Converter

Automotive-Grade, Constant-Current 2 A

PWM Dimmable Buck Regulator LED Driver

A6214 and

A6216

Allegro MicroSystems, LLC

115 Northeast Cutoff

Worcester, Massachusetts 01615-0036 U.S.A.

1.508.853.5000; www.allegromicro.com

MINIMUM AND MAXIMUM OUTPUT VOLTAGES

For a given input voltage, the maximum output voltage depends

on the switching frequency and minimum tOFF . For example, if

tOFF(min) = 150 ns and fSW = 2 MHz, then the maximum duty

cycle is 80%. So for a 12.5 V input, the maximum output is

approximately 10 V (based on the simplified equation of VOUT

= VIN × D). This means up to 3 LEDs can be operated in series,

assuming Vf = 3.2 V or less for each LED.

The minimum output voltage depends on minimum tON and

switching frequency. For example, if the minimum tON = 100 ns

and fSW = 1 MHz, then the minimum duty cycle is 10%. That

means with VIN = 24 V, the theoretical minimum VOUT is just

2.4 V. However, the internal current sense amplifier is designed

to operate down to VOUT = 2.65 V. Therefore the output voltage

should not go lower than 2.65 V, or else the current accuracy will

suffer.

To a lesser degree, the output voltage is also affected by other

factors such as LED current, on-resistance of the high-side

switch, DCR of the inductor, and forward drop of the low-side

diode.

As a general rule, switching at lower frequencies allows a wider

range of VOUT , and hence more flexible LED configurations.

0 0.2 0.4 0.6 0.8 1 1.2 1.4 1.6 1.8 2

VOUT (V)

Frequency (MHz)

VOUT(max) (V)

VOUT(min) (V)

Figure 18: Minimum and Maximum Output Voltage vs.

Switching Freqency

(VIN = 24 V, minimum tON and tOFF of 100 ns)

If the required output voltage is lower than that permitted by the

minimum tON , the controller will automatically extend the tOFF ,

in order to maintain the correct duty cycle. This means that the

switching frequency will drop lower when necessary, in order to

keep the LED current in regulation.

If the LED string is completely shorted (VOUT = 0 V), LED

current regulation will become impossible. The output current

will increase until it trips SW overcurrent protection. The IC

then shuts down and retries after approximately 1 ms cooldown

period.

THERMAL BUDGETING

The A6214 is capable of supplying a 2 A current through its

high-side switch. However, depending on the duty cycle, the

conduction loss in the high-side switch may cause the package to

overheat. Therefore care must be taken to ensure the total power

loss of package is within budget. For example, if the maximum

temperature rise allowed is ∆T = 50°C at the device case surface,

then the maximum power dissipation of the IC is 1.4 W. Assum-

ing the maximum RDS(on) = 0.4 Ω and a duty cycle of 85%, then

the maximum LED current is limited to 2 A approximately. At a

lower duty cycle, the LED current can be higher.

FAULT HANDLING

The A6214 is designed to handle the following faults:

• Pin-to-ground short

• Pin-to-neighboring pin short

• Pin open

• External component open or short

• Output short to GND

The waveform in the figure below illustrates how the A6214

responds in the case in which the current sense resistor or the

CSH and CSL pins are shorted together. Note that the SW pin

overcurrent protection is tripped at around 3.5 A, and the part

shuts down immediately. The part then goes through startup retry

after approximately 1 ms of cooldown period.

Figure 19: In case of sense resistor short fault –

Output current rises until it trips SW OCP at ~3.5 A. The

IC shuts off and retries after ~1 ms cooldown period.

CH1 = VPWM (5 V/div)

CH2 = VSW (5 V/div)

CH3 = VOUT (5 V/div)

CH4 = iLED (1 A/div)

Time Scale = 200 µs/div

Automotive-Grade, Constant-Current 2 A

PWM Dimmable Buck Regulator LED Driver

A6214 and

A6216

Allegro MicroSystems, LLC

115 Northeast Cutoff

Worcester, Massachusetts 01615-0036 U.S.A.

1.508.853.5000; www.allegromicro.com

As another example, the waveform in figure below shows the

fault case where external diode D1 is missing or open. As LED

current builds up, a larger-than-normal negative voltage is

developed at the SW node during off-time. This voltage trips the

missing detection function of the IC. The IC then shuts down

immediately, and waits for a cooldown period before retry.

Figure 20: In case of missing low-side diode –

SW voltage fall below –2 V and trips Missing-Diode

fault. FAULT pin (A6216 only) is pulled Low immediate-

ly. The IC shuts off and retries after cooldown period.

COMPONENT SELECTIONS

The inductor is often the most critical component in a buck con-

verter. Follow the procedure below to derive the correct param-

eters for the inductor:

1. Determine the saturation current of the inductor. This can be

done by simply adding 20% to the average LED current:

iSAT ≥ iLED × 1.2.

2. Determine the ripple current amplitude (peak-to-peak value). As

a general rule, ripple current should be kept between 10% and

30% of the average LED current:

0.1 < iRIPPLE(pk-pk) / iLED < 0.3.

3. Calculate the inductance based on the following equations:

L = (VIN – VOUT

) × D × t / iRIPPLE , and

D = (VOUT + VD

) / ( VIN + VD ) ,

where

D is the duty cycle,

t is the period 1/ fSW , and

VD is the forward voltage drop of the Schottky diode D1.

OUTPUT FILTER CAPACITOR

The A6214 is designed to operate in current regulation mode.

Therefore it does not require a large output capacitor to stabilize

the output voltage. This results in lower cost and smaller PCB

area. In fact, having a large output capacitor is not recommended.

In most applications, however, it is beneficial to add a small filter

capacitor (around 0.1 μF) across the LED string. This cap serves

as a filter to eliminate switching spikes seen by the LED string.

This is very important in reducing EMI noises, and may also help

in ESD testing.

ADDITIONAL NOTES ON RIPPLE CURRENT

• For consistent switching frequency, it is recommended to

choose the inductor and switching frequency to ensure the induc-

tor ripple current percentage is at least 10% over normal operat-

ing voltage range (ripple current is lowest at lowest VIN).

If ripple current is less than 10%, the switching frequency may

jitter due to insufficient ripple voltage across CSH and CSL pins.

However, the average LED current is still regulated.

• For best accuracy in LED current regulation, a low current

ripple of less than 20% is required.

• There is no hard limit on the highest ripple current percentage

allowed. A 40% ripple current is still acceptable, as long as both

the inductor and LEDs can handle the peak current (average cur-

rent × 1.2 in this case). However, higher ripple current % affects

the accuracy of LED current, and limits the minimum current that

can be regulated when using ADIM.

• In general, allowing a higher ripple current percentage enables

lower-inductance inductors to be used, which results in smaller

size and lower cost.

• If lower ripple current is required for the LED string, one solu-

tion is to add a small capacitor (such as 1 to 2.2 μF) across the

LED string from LED+ to GND. In this case, the inductor ripple

current remains high while the LED ripple current is greatly

reduced.

• The effectiveness of this filter capacitor depends on many fac-

tors, such as: switching frequency, inductors used, PCB layout,

LED voltage and current, and so forth.

• The addition of this capacitor introduces a longer delay in LED

current during PWM dimming operation. Therefore the accuracy

of average LED current is reduced at short PWM on-time.

CH1 = VFAULT (5 V/div)

CH2 = VSW (5 V/div)

CH3 = VOUT (5 V/div)

CH4 = iLED (1 A/div)

Time Scale = 1 µs/div

Automotive-Grade, Constant-Current 2 A

PWM Dimmable Buck Regulator LED Driver

A6214 and

A6216

Allegro MicroSystems, LLC

115 Northeast Cutoff

Worcester, Massachusetts 01615-0036 U.S.A.

1.508.853.5000; www.allegromicro.com

INDUCTOR SELECTION CHART

The chart in figure below summarizes the relationship between

LED current, switching frequency, and inductor value. Based on

this chart: assuming LED current = 1 A and L = 22 μH, then mini-

mum fSW = 0.7 MHz in order to keep the ripple current at 20% or

lower. (Note: VOUT = VIN / 2 is the worst case for ripple current).

If the switching frequency is lower, then a larger inductance must

be used to meet the same ripple current requirement.

0.0

0.2

0.4

0.6

0.8

1.0

1.2

1.4

1.6

1.8

2.0

0 0.5 1 1.5 2

Switching Frequency (MHz)

LED Current (A)

L = 10

µH

L = 15

µH

L = 22

µH

L = 33

µH

L = 47

µH

Figure 21: Relation between minimum switching frequen-

cy and LED current, given different inductance used

(VIN = 12 V, VOUT = 6 V, ripple current = 20%)

Automotive-Grade, Constant-Current 2 A

PWM Dimmable Buck Regulator LED Driver

A6214 and

A6216

Allegro MicroSystems, LLC

115 Northeast Cutoff

Worcester, Massachusetts 01615-0036 U.S.A.

1.508.853.5000; www.allegromicro.com

VIN

GND

RSENSE

LED+

iRIPPLE

VIN

GND

RSENSE

LED+

iRIPPLE

Without output capacitor:

The same inductor ripple current flows through

sense resistor and LED string.

With a small capacitor across LED string:

Ripple current through LED string is reducted, while

ripple voltage across RSENSE remains high.

Figure 22: Using an Output Filter Capacitor to Reduce

Ripple Current in LED String

Effects of Output Capacitor on LED Ripple Current

Automotive-Grade, Constant-Current 2 A

PWM Dimmable Buck Regulator LED Driver

A6214 and

A6216

Allegro MicroSystems, LLC

115 Northeast Cutoff

Worcester, Massachusetts 01615-0036 U.S.A.

1.508.853.5000; www.allegromicro.com

APPLICATION CIRCUIT DIAGRAMS

Figure 23: Application Circuit Example for A6214

(for driving 15 V LED at 1.3 A, fSW = 500 kHz)

LED+

GND

(20 to 55 V)

EN/PWM

0.1 µF

442 kΩ

47 µH 2 A

1 µF

RSENSE

0.15 Ω

GND

60 V

2 A

BOOT

GND

CSH

CSL

VIN

TON

ADIM

VCC

A6214

adj

71.5 Ω

0.1 µF

100 V

4.7 µF

100 V

33 µF

63 V

LED

String

(~15 V)

LED

= (V

CSREG

– i

CSL

× R

adj

) / R

SENSE

= (0.2 – 0.000007 × 71.5) / 0.15 = 1.3 A

Suggested Components

Symbol Part Number Manufacturer

C1 HHXA630ARA330MHA0G United Chemi-Con

C2 C3225X7S2A475M200AB TDK

C3 CGA4J2X7R2A104M125AA TDK

L1 CDRH105RNP-470NC Sumida

D1 10MQ060NTRPBF Vishay

RSENSE RL1632R-R150-F Susumu

Figure 24: Application Circuit Example for A6216

(with External PWM and Thermal Foldback)

LED+

GND

(4.5 to 55 V)

EN/PWM

GND

VCC

FAULT

External PWM

dimming signal 3

RANGE

BOOT

GND

CSH

CSL

FULL

TON

EN/PWM

ADIM

VCC

A6216

GND FPWM

FAULT

VIN

442 kΩ

BIAS

1 µF

BOOT

0.1 µF

LED

0.1 µF

SENSE

0.2 Ω

10 kΩ

47 µH 2 A

60 V

2 A

LED

= 1 A

before foldback

VCC

NTC

Thermal Foldback using NTC

Automotive-Grade, Constant-Current 2 A

PWM Dimmable Buck Regulator LED Driver

A6214 and

A6216

Allegro MicroSystems, LLC

115 Northeast Cutoff

Worcester, Massachusetts 01615-0036 U.S.A.

1.508.853.5000; www.allegromicro.com

APPLICATION CIRCUIT DIAGRAMS (continued)

Figure 25: Using two (or more) A6214/16 in parallel to drive the same LED string. Total

LED current is the sum of currents from each driver.

LED–

L1 RCS1

GND

CSH

CSL

CLED

VIN

LED+ L2

RCS2

GND

CSH

CSL

CLED

VIN

iLED1 iLED2

A6214/6 A6214/6

Automotive-Grade, Constant-Current 2 A

PWM Dimmable Buck Regulator LED Driver

A6214 and

A6216

Allegro MicroSystems, LLC

115 Northeast Cutoff

Worcester, Massachusetts 01615-0036 U.S.A.

1.508.853.5000; www.allegromicro.com

APPLICATION CIRCUIT DIAGRAMS (continued)

PROTECTION FROM OUTPUT LC-RESONANCE

During normal operation, if the LED load becomes disconnected

(due to a bad connector, for example), the output capacitor CLED

will be charged up to VOUT = VIN. Later, when the LED load is

reconnected, higher voltage stored in CLED will create a huge

current spike through the load. Normally this does not create

any problems, since the current spike will decay within a few

microseconds. However, if the LED load is connected through

long cables, the parasitic inductance LK in the cable will form an

LC-resonant circuit with CLED. If the resonant circuit is under-

damped, VOUT may oscillate and becomes negative. This could

subject CSH and CSL pins to negative spike voltage exceeding

their Absolute Maximum Ratings. Therefore the following pre-

cautions are recommended to avoid output oscillation:

• Use shortest possible LED cables to reduce LK.

• Use lower capacitance for CLED to reduce stored energy

(EC = 0.5 × CLED × VIN2).

• Critically damp the output LC-resonant circuit, as shown

in Figure 26. The drawback is additional power loss during

PWM dimming operation (since C1 is charged and discharged

through R1 during each PWM cycle).

In case the output LC resonance cannot be eliminated (due to

long LED cables, for example), consider adding a Schottky bar-

rier diode (SBD) in parallel with CLED, as shown in Figure 28.

The SBD clamps the negative spike of the LC resonance, so CSH

and CSL pins are protected. This is the most effective protection

with minimal side effects.

In underdamped circuit,

VOUT goes negative

In critically-damped circuit,

VOUT stays positive

LED

initially charged to

VOUT = 50 V when load is open

Time/µs

Figure 26: Countermeasure to Prevent VOUT Oscillation

During Output Intermittent Open/Short Fault

Figure 27: Simulation Results Showing Difference in VOUT

Between Underdamped and Critically-Damped Circuits

Figure 28: Using Schottky Diode to Clamp the Negative

spike from Output LC-Resonance

GND

SENSE

CSL

LED

Add D2 to clamp the

negative voltage of

LC-resonant circuit

S1 LK

LED

CSH

(60 V 1 A)

Total parasitic

inductance of cable

VOUT

LED

GND

SENSE

LED

0.1 µF

ic = 50 V

OUT

1 Ω

CSH

CSL

Total resistance

of output path

0.4 µH

ic = 0 A

0.22 µF

1 Ω

ESR

10 mΩ

OUT

Add R1 and C1 to

critically damp the

LC-resonant circuit

Large current spike

when S1 is closed

Total parasitic

inductance of cable

Automotive-Grade, Constant-Current 2 A

PWM Dimmable Buck Regulator LED Driver

A6214 and

A6216

Allegro MicroSystems, LLC

115 Northeast Cutoff

Worcester, Massachusetts 01615-0036 U.S.A.

1.508.853.5000; www.allegromicro.com

SYSTEM FAILURE DETECTION AND PROTECTION

LED+

GND

EN/PWM

L1 = open

or short

SENSE

open or short

GND 1

BOOT

GND

CSH

CSL

VIN

TON

ADIM

VCC

A6214

D1 = open

or short

C4 open

or short

C1, C2 = open or short

R1 = open

or short

C5 = open

or short C3 open

or short

LED string open

or short to GND

Figure 29: Showing Various Possible Fault Cases in an

Application Circuit

IC-LEVEL FAILURE MODES

Protected against:

• Any pin open

• Any pin shorted to GND

• Adjacent pin-to-pin short

SYSTEM-LEVEL FAILURE MODES

Protected against open/short fault for all external

components, including:

• LED string

• Sense resistor

• Inductor

• Diode

• Input/output caps, etc.

Failure Mode Symptom Observed

FAULT flag

(A6216)

asserted?

A6214/16 Response

Inductor shorted Dim light from LED Yes Current spike trips SW secondary OCP and turns off switching. Retries after 1 ms.

Sense resistor open No light from LED Yes High differential sense voltage causes IC to shut off switching. Retries after 1 ms.

Sense resistor shorted Dim light from LED Yes Increases SW current, which eventually trips SW secondary OCP fault. Retries

after 1 ms.

Diode open Dim light from LED Yes Detects missing diode fault and shuts off switching. Retries after 1 ms.

Diode shorted No light from LED Yes Trips SW secondary OCP and turns off switching. Retries after 1 ms.

LED string open No light from LED Yes* Continue to switch at maximum tON (Since this fault cannot be distinguished from

VIN too low for LED forward drop)

LED string shorted to GND,

or Output cap shorted No light from LED Yes* IC unable to regulate LED current at VOUT = 0 V. SW current increases and trips

OCP. IC shuts down and retries after 1 ms.

LED string partially shorted Some LEDs are not on NO Normal operation (since IC has no way to know how many LED is supposed to

be in series).

Continued on the next page…

System Failure Mode Table (partial)

Automotive-Grade, Constant-Current 2 A

PWM Dimmable Buck Regulator LED Driver

A6214 and

A6216

Allegro MicroSystems, LLC

115 Northeast Cutoff

Worcester, Massachusetts 01615-0036 U.S.A.

1.508.853.5000; www.allegromicro.com

Failure Mode Symptom Observed

FAULT flag

(A6216)

asserted?

A6214/16 Response

Output cap open Normal light from LED NO Normal operation (since IC only monitors inductor current).

Boot cap open Dim light from LED Yes* IC attempts to switch but can’t fully turn on SW. Short current spikes through

LED string.

Boot cap shorted No light from LED Yes* IC detects undervoltage fault across Boot cap and will not start switching.

TON resistor open Dim light from LED Yes SW turns on and hits secondary current limit, then shuts down. Retries after 1 ms.

TON resistor shorted Dim light from LED NO Operates at maximum switching frequency (minimum tON and tOFF). May hit

thermal limit.

Note (*)

• In case of LED current not in regulation, FAULT ag is asserted after approximately 50 µs timeout delay.

• For PWM dimming operation with on-time < 50 µs, FAULT ag is asserted if LED current fails to reach regulation after 16 PWM = H pulses.

• For PWM dimming operation with on-time > 50 µs, FAULT ag is only asserted when PWM = H. However, if the fault persists for 16 consecutive

PWM cycles, FAULT ag will be pulled Low and then it stays Low until the fault is cleared.

System Failure Mode Table (partial) (continued)

Figure 30: VIN too low for LED regulation. PWM = 500 Hz

2% (40 µs). FAULT = L after 16 PWM pulses.

Figure 31: VIN too low for LED regulation. PWM = 500 Hz

20% (400 µs). FAULT toggles each time PWM = H, but

stays Low after 16 PWM pulses.

CH1 = VPWM (5 V/div)

CH2 = VFAULT (5 V/div)

CH3 = VOUT (5 V/div)

CH4 = iLED (500 mA/div)

Time Scale = 5 ms/div

CH1 = VPWM (5 V/div)

CH2 = VFAULT (5 V/div)

CH3 = VOUT (5 V/div)

CH4 = iLED (500 mA/div)

Time Scale = 5 ms/div

Automotive-Grade, Constant-Current 2 A

PWM Dimmable Buck Regulator LED Driver

A6214 and

A6216

Allegro MicroSystems, LLC

115 Northeast Cutoff

Worcester, Massachusetts 01615-0036 U.S.A.

1.508.853.5000; www.allegromicro.com

Package LK, 10-Pin SOICN with Exposed Thermal Pad

PACKAGE OUTLINE DRAWINGS

For Reference Only–Not for Tooling Use

NOT TO SCALE

Dimensions in millimeters

Dimensions exclusive of mold ﬂash, gate burrs, and dambar protrusions

Exact case and lead conﬁguration at supplier discretion within limits shown

0.40

0.30

0.25

0.19

8º

0º

0.685 ±0.20

SEATING

PLANE

SEATING PLANE

C0.10

10X

1.00 BSC

0.25 BSC

4.90+0.08

–0.10

3.91+0.08

–0.10

2.41 ±0.25 6.00 ±0.20

1.55 ±0.10

0.10 ±0.05

GAUGE PLANE

Exposed thermal pad (bottom surface)

5.60

1.000.55

1.75

2.41

3.30

Branded Face

3.30 ±0.25

PCB Layout Reference View

Terminal #1 mark area

Reference land pattern layout; all pads a minimum of 0.20 mm from all adjacent pads;

adjust as necessary to meet application process requirements and PCB layout tolerances;

when mounting on a multilayer PCB, thermal vias at the exposed thermal pad land can

improve thermal dissipation (reference EIA/JEDEC Standard JESD51-5)

Automotive-Grade, Constant-Current 2 A

PWM Dimmable Buck Regulator LED Driver

A6214 and

A6216

Allegro MicroSystems, LLC

115 Northeast Cutoff

Worcester, Massachusetts 01615-0036 U.S.A.

1.508.853.5000; www.allegromicro.com

Package LP, 16-Pin TSSOP with Exposed Thermal Pad

1.20 MAX

0.15

0.00

0.30

0.19

0.20

0.09

8º

0º

0.60 ±0.15

1.00 REF

SEATING

PLANE

C0.10

16X

0.65 BSC

0.25 BSC

5.00 ±0.10

4.40 ±0.10 6.40 ±0.20

GAUGE PLANE

SEATING PLANE

Exposed thermal pad (bottom surface); dimensions may vary with device

6.10

0.65

0.45

1.70

3.00

Branded Face

3 NOM

For Reference Only – Not for Tooling Use

(Reference MO-153 ABT)

Dimensions in millimeters. NOT TO SCALE

Dimensions exclusive of mold ﬂash, gate burrs, and dambar protrusions

Exact case and lead conﬁguration at supplier discretion within limits shown

PCB Layout Reference View

Terminal #1 mark area

Reference land pattern layout (reference IPC7351 SOP65P640X110-17M);

All pads a minimum of 0.20 mm from all adjacent pads; adjust as necessary

to meet application process requirements and PCB layout tolerances; when

mounting on a multilayer PCB, thermal vias at the exposed thermal pad land

can improve thermal dissipation (reference EIA/JEDEC Standard JESD51-5)

Branding scale and appearance at supplier discretion

Standard Branding Reference View

YYWW

NNNNNNN

LLLL

= Device part number

= Supplier emblem

= Last two digits of year of manufacture

= Week of manufacture

= Characters 5-8 of lot number

Automotive-Grade, Constant-Current 2 A

PWM Dimmable Buck Regulator LED Driver

A6214 and

A6216

Allegro MicroSystems, LLC

115 Northeast Cutoff

Worcester, Massachusetts 01615-0036 U.S.A.

1.508.853.5000; www.allegromicro.com

For the latest version of this document, visit our website:

www.allegromicro.com

Revision History

Number Date Description

– September 23, 2015 Initial release

1 March 17, 2016 Added Load Current Sense Regulation Threshold footnote (page 7-8); updated Additional Notes on

Ripple Current (page 15).

2 April 6, 2016 Added Parallel Operation figure (page 19) and SBD Protection figure (page 20); updated Protection

from Output LC-Resonance (page 19); corrected LK package drawing dimension (page 23).

3 June 17, 2016 Updated k value (page 11).

4 November 1, 2016 Updated Functional Description (page 11); added Table of Contents.

Allegro MicroSystems, LLC reserves the right to make, from time to time, such departures from the detail specifications as may be required to

permit improvements in the performance, reliability, or manufacturability of its products. Before placing an order, the user is cautioned to verify that

the information being relied upon is current.

Allegro’s products are not to be used in any devices or systems, including but not limited to life support devices or systems, in which a failure of

Allegro’s product can reasonably be expected to cause bodily harm.

The information included herein is believed to be accurate and reliable. However, Allegro MicroSystems, LLC assumes no responsibility for its

use; nor for any infringement of patents or other rights of third parties which may result from its use.