A80605 [ALLEGRO]
High Power LED Driver with Pre-Emptive Boost for Ultra-High Dimming Ratio and Low Output Ripple;型号: | A80605 |
厂家: | ALLEGRO MICROSYSTEMS |
描述: | High Power LED Driver with Pre-Emptive Boost for Ultra-High Dimming Ratio and Low Output Ripple |
文件: | 总42页 (文件大小:4624K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
A80605 and A80605-1
High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
FEATURES AND BENEFITS
DESCRIPTION
The A80605 is a multi-output LED driver for automotive
applicationssuchasexteriorlighting,heads-updisplay,andmid-
size LCD backlighting. It implements a current-mode boost/
SEPICconverterwithgatedriverforexternalN-MOSFET.This
allows greater output power even at minimum supply voltage.
• Automotive AEC-Q100 qualified
• Enhanced fault handling for ASIL B system compliance
• Wide input voltage range of 4.5 to 40 V for start/stop,
cold crank, and load dump requirements
• Operate in Boost or SEPIC mode for flexible output
• Gate driver for external NMOS to deliver higher output power
• Six integrated LED current sinks, up to 140 mA each
• Boost switching frequency synced externally or
programmed from 200 kHz to 2.3 MHz
• Programmable boost frequency dithering to reduce EMI
• Advanced control allows minimum PWM on-time down
to 0.3 µs, and avoids MLCC audible noises
• LED contrast ratio: 15,000:1 at 200 Hz using PWM
dimming alone, 150,000:1 when combining PWM and
analog dimming
TheA80605 provides six integrated current sinks driving up to
140 mAper string. Multiple sinks can be paralleled together to
achieve higher LED currents up to 840 mA. The IC operates
from single power supply from 4.5 to 40 V; once started, it can
continue to operate down to 4 V. This allows it to withstand
stop/start, cold crank, and load dump conditions encountered
in automotive systems.
TheA80605cancontrolLEDbrightnessthroughexternalPWM
signal.ByusingthepatentedPre-EmptiveBoostcontrol,anLED
brightnesscontrastratioof15,000:1canbeachievedusingPWM
dimmingat200Hz.Ahigherratioof150,000:1ispossiblewhen
using a combination of PWM and analog dimming.
• Excellent input voltage transient response even at lowest
PWM duty cycle
• Gate driver for optional PMOS input disconnect switch
• Extensive fault protection features
Continued on next page...
PACKAGE:
APPLICATIONS
• Automotive infotainment backlighting
24-Pin 4 mm × 4 mm QFN
with Wettable Flank
• Automotive heads-up display
• Automotive interior and exterior lighting
Not to scale
VIN = 8-16 V
ꢀoptional
VOUT ≤ 40 V
L1
RSENSE
RADJ
D1
CIN2
Q1
D2
Cin
ROVP
RCS
CDRV
RGDRV
COUT
CS
GATE
VDRV GDRV
PGND
OVP
Vsense
VIN
V
c
CVDD
VDD
RPU
LED1
FAULT
A80605
Up to 11 WLEDs in series
Up to 140 mA/channel
Combine to drive up to 840 mA total
LED2
LED3
EN/PWM
ADIM
PWM tON ≥ 0.3 µs
LED6
iLED
COMP
PEB
100%
FSET
AGND
ISET
DITH
RZ
ADIM
CP
RM
PEB = Pre-Emptive Boost
(RD controls the delay time)
DITH = Dithering Control
RISET
RFSET
RD
CM
CZ
APWM 100 kHz 0-90%
(Modulation frequency and range)
Figure 1: A80605 in typical Boost configuration where VOUT is higher than VIN
A80605-DS, Rev. 2
MCO-0000765
June 15, 2020
A80605 and
A80605-1
High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
DESCRIPTION (continued)
Switchingfrequencycanbeexternallysynchronizedorprogrammed
between 200 kHz and 2.3 MHz. This allows operation either above
or below the AM band. A programmable dithering feature further
reduces EMI.
The A80605 provides protection against output short, overvoltage,
open- or shorted-LED pin, and overtemperature. A cycle-by-cycle
current limit protects the external boost switch against high current
overloads. An external P-MOSFET can optionally be used to
disconnect input supply in case of output to ground short fault. The
A80605-1 is similar toA80605 except it adopts ‘One-Out-All-Out’
fault handling (See Fault Table section for details).
SELECTION GUIDE [1]
Part Number
A80605KESJSR
A80605KESJSR-1
Fault Handling
One-Out-Continue
One-Out-All-Out
LED Driver
Package
Packing
24-pin 4 × 4 mm wettable flank QFN
with exposed thermal pad and sidewall plating
6 × 140 mA
6000 pieces per reel
[1] Contact Allegro for additional packing options.
ABSOLUTE MAXIMUM RATINGS [2]
Characteristic
Symbol
Notes
Rating
–0.3 to 40
–0.3 to 40
–0.3 to 40
Higher of –0.3
Unit
V
LEDx Pin
OVP pin
VIN
VLEDx
VOVP
VIN
x = 1..6
V
V
VSENSE
VGATE
,
VSENSE, GATE
and (VIN – 7.4) to
VIN +0.4
V
VDRV, GDRV
CS
VDRV, VGDRV
VCS
–1.0 to 7.5
–0.3 to 7
V
V
EN/PWM, FAULT, ADIM, COMP,
DITH, PEB, FSET, ISET, VDD
External input signals must not be higher than VIN + 0.4 V
–0.3 to 5.5
V
Maximum Junction Temperature
Storage Temperature
TJ(max)
Tstg
150
°C
°C
–55 to 150
[2] Stresses beyond those listed in this table may cause permanent damage to the device. The absolute maximum ratings are stress ratings only,
and functional operation of the device at these or any other conditions beyond those indicated in the Electrical Characteristics table is not implied.
Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
THERMAL CHARACTERISTICS: May require derating at maximum conditions; see application information
Characteristic
Symbol
Test Conditions [4]
Value
Unit
Package Thermal Resistance
RθJA
ES package measured on 4-layer PCB based on JEDEC standard
37
°C/W
[4] Additional thermal information available on the Allegro website.
2
Allegro MicroSystems
955 Perimeter Road
Manchester, NH 03103-3353 U.S.A.
www.allegromicro.com
A80605 and
A80605-1
High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
Table of Contents
PWM Dimming ............................................................... 18
Pre-Emptive Boost (PEB)................................................. 19
Analog Dimming ............................................................. 20
ADIM Mode ................................................................ 20
APWM Mode .............................................................. 21
Extending LED Dimming Ratio.......................................... 22
Analog Dimming with External Voltage............................... 23
VDD.............................................................................. 24
VDRV............................................................................ 24
Shutdown....................................................................... 24
Fault Detection and Protection............................................. 25
FAULT Status ................................................................. 25
LED String Partial-Short Detect ........................................ 27
Overvoltage Protection .................................................... 28
Boost Switch Overcurrent Protection ................................. 29
Input Overcurrent Protection and Disconnect Switch ........... 30
Setting the Input Current Sense Resistor ........................... 31
Input UVLO.................................................................... 31
Fault Protection During Operation ..................................... 31
Package Outline Drawing.................................................... 34
Appendix A: Design Example............................................... 35
Appendix B: External MOSFET Selection Guide .................... 40
Features and Benefits........................................................... 1
Description.......................................................................... 1
Applications......................................................................... 1
Package ............................................................................. 1
Selection Guide ................................................................... 2
Absolute Maximum Ratings................................................... 2
Thermal Characteristics ........................................................ 2
Typical Application – SEPIC .................................................. 3
Functional Block Diagram ..................................................... 4
Pinout Diagram and Terminal List........................................... 5
Electrical Characteristics....................................................... 6
Application Example........................................................... 10
Functional Description .........................................................11
Enabling the IC................................................................11
Powering Up: LED Detection Phase.................................. 12
Powering Up: Boost Output Undervoltage.......................... 14
Soft Start Function .......................................................... 14
Frequency Selection........................................................ 15
Synchronization.............................................................. 15
Loss of External Sync Signal............................................ 16
Switching Frequency Dithering ......................................... 17
LED Current Setting ........................................................ 18
ꢇꢍ
ꢇ1
ꢐreaꢑdown ꢒoltage oꢓ ꢔ1 and
ꢃ1 mꢕst ꢖeꢗ ꢁꢂN ꢘ ꢁꢀUꢅ
ꢁꢂN ꢎ ꢏ-1ꢈ ꢁ
ꢃ1
ꢁꢀUꢅ ≤ 40 V
ꢌꢌ
ꢌꢂN
ꢔ1
RꢀꢁP
ꢌꢀUꢅ1
ꢌꢀUꢅꢍ
ꢌꢃRꢁ
ꢄAꢅꢆ
ꢁsense
ꢁꢃRꢁ ꢄꢃRꢁ ꢌS
PꢄNꢃ
ꢀꢁP
ꢁꢌ
ꢁꢂN
ꢁꢃꢃ
ꢌꢁꢃꢃ
RPU
ꢇꢆꢃ1
ꢇꢆꢃꢍ
ꢇꢆꢃ3
A80605
ꢋAUꢇꢅ
Uꢙ to 11 ꢊꢇꢆꢃs in series
Uꢙ to 1ꢚ0 mAꢉch. ꢌomꢖine
to driꢒe ꢕꢙ to ꢏꢚ0 mA total
ꢆNꢉPꢊM
PꢊM t
≥ 0.3 ꢛs
on
ꢇꢆꢃꢈ
AꢃꢂMꢉ
APꢊM
iꢇꢆꢃ
ꢌꢀMP
Pꢆꢐ
100ꢞ
ꢋSꢆꢅ
AꢄNꢃ
ꢂSꢆꢅ
ꢃꢂꢅH
AꢃꢂM
Rꢜ
ꢌꢜ
ꢌP
RꢃꢂꢅH
ꢌꢃꢂꢅH
RꢂSꢆꢅ
RPꢆꢐ
RꢋSꢆꢅ
APꢊM 100ꢑHꢝ 0-90ꢞ
Figure 2: A80605 in typical SEPIC configuration where VOUT can be either higher or lower than VIN
3
Allegro MicroSystems
955 Perimeter Road
Manchester, NH 03103-3353 U.S.A.
www.allegromicro.com
A80605 and
A80605-1
High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
ꢍꢄUꢊ
ꢍSꢉNSꢉ
ꢍꢅRꢍ
Sꢖ
ꢉꢛternal
SꢙNꢇ
ꢇꢅꢎꢊH
RꢀSꢉꢊ
RꢅꢎꢊH
ꢈ1
ꢏAꢊꢉ
ꢇꢅRꢍ
ꢅꢎꢊH
ꢀSꢉꢊꢌSꢙNꢇ
ꢍꢎN
ꢄscillator
ꢏate ꢅriꢆer
ꢈꢅꢄ ꢑꢕ.5 ꢍꢓ
ꢀreꢟꢁency
dithering
ꢏꢅRꢍ
NMꢄS
ꢏate
ꢅriꢆe
ꢉnaꢚle
ꢔSꢖ
ꢂoost
ꢉnaꢚle
ꢇS
ꢇꢄMP
ꢇomꢋarator
RꢇS
PꢏNꢅ
ꢇꢄMP
PꢏNꢅ
ꢇꢁrrent
sense
Soꢔt Start
Ramꢋ
ꢑ1ꢕmsꢓ
ꢇꢇꢄMP
ꢍꢈꢉꢅ
reꢔ
1 MHꢜ
ꢠꢒ
ꢈꢉꢅ1
ꢒ MHꢜ
.
Mꢁlti-inꢋꢁt
ꢄꢇPꢐ
ꢊSꢅ
ꢉrror Amꢋ
.
System
oscillator
ꢈꢉꢅꢒ
ꢍꢄUꢊ
ꢀSꢉꢊ or ꢎSꢉꢊ
ꢋin ꢄꢋenꢌShort
ꢍꢅꢅ
ꢎnternal ꢍꢅꢅ
ꢑꢒ.ꢐ5 ꢍꢓ
ꢇꢍꢅꢅ
RꢄꢍP
ꢍꢎN
ꢄꢍP
sense
Regꢁlator
Uꢍꢈꢄ ꢂlocꢃ
1.ꢐ35 ꢍ
Rꢉꢀ
ꢄꢍP
ꢍreꢔ
ꢀaꢁlt ꢂlocꢃ
AꢏNꢅ
RSꢉNSꢉ
ꢉnaꢚle
ꢄꢋenꢌShort
ꢈꢉꢅ ꢅetect
ꢗ
ꢎnꢋꢁt cꢁrrent
sense amꢋ
ꢍ
SꢉNSꢉ
ꢇhoꢋꢋing
ꢔreꢟ ꢡ ꢒ MHꢜ
iAꢅꢘ
ꢈꢉꢅ1
ꢈꢉꢅꢐ
ꢈꢉꢅ
ꢅriꢆer
ꢂlocꢃ
ꢍꢎN
ꢄnꢌꢄꢔꢔ
ꢏAꢊꢉ
ꢄꢀꢀ
ꢂoost
ꢉnaꢚle
ꢏAꢊꢉ
ꢇꢁrrent
leꢆel
ꢈꢉꢅꢕ
AꢅꢎMꢌ
PMꢄS
ꢅriꢆer
AꢏNꢅ
ꢇlocꢃ
detector
ꢉnaꢚle
APꢖM
100 kΩ
ꢍreꢔ
ꢎnt ꢍꢅꢅ
ꢉNꢌPꢖM
ꢎSꢉꢊ
ꢞeeꢋ-Aliꢆe
ꢊimer
ꢎSꢉꢊ
ꢂlocꢃ
50 kΩ
1 MHꢜ
ꢉꢛternal PꢖM
100 Hꢜ ꢝ ꢐ0 ꢞHꢜ
RꢎSꢉꢊ
ꢍꢅꢅ
ꢉꢛternal
ꢈꢉꢅ ꢉnaꢚle
ꢀAUꢈꢊ
RPU
start
Pre-ꢉmꢋtiꢆe
ꢂoost
Pꢉꢂ
ꢀAUꢈꢊ
ꢎnternal ꢀAUꢈꢊ
delay
RPꢉꢂ
A80605
AꢏNꢅ
Figure 3: Functional Block Diagram
4
Allegro MicroSystems
955 Perimeter Road
Manchester, NH 03103-3353 U.S.A.
www.allegromicro.com
A80605 and
A80605-1
High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
PINOUT DIAGRAM AND TERMINAL LIST
FAULT
VDD
1
2
3
4
5
6
18 PGND
17 OVP
AGND
COMP
ISET
16 LED1
15 LED2
14 LED3
13 LED4
PAD
PEB
Package ES, 24-Pin QFN Pinouts
Terminal List Table
Number
Name
Function
This pin is an open drain type configuration that will be pulled low when a fault occurs. Connect a pull-up resistor between this pin and
desired logic level voltage.
1
FAULT
2
3
4
5
VDD
AGND
COMP
ISET
Output of internal LDO (bias regulator). Connect a 1 µF decoupling capacitor between this pin and AGND. VDD is regulated at ~4.25 V.
LED current Ground. Also serves as ‘quiet’ ground for analog signals.
Output of the error amplifier and compensation node. Connect a series RZ-CZ network from this pin to AGND for control loop compensation.
Connect RISET resistor between this pin and AGND to set the 100% LED current.
Pre-Emptive Boost control: Connect resistor from PEB pin to AGND to fine-tune the delay between boost switch and LED current sinks.
Leave pin open for minimum PEB delay of 1 µs.
6
7
PEB
Dithering control: connect a capacitor to AGND to set the dithering modulation frequency (1 to 22 kHz). Connect a resistor between DITH and
FSET pins to set the dithering range (such as ±5% of fSW).
DITH
Frequency/synchronization pin. A resistor RFSET from this pin to AGND sets the switching frequency fSW (with dithering superimposed)
between 200 kHz and 2.3 MHz. It can also be used to synchronize fSW to an external frequency between 260 kHz and 2.3 MHz (frequency
dithering is disabled in this case).
8
9
FSET
ADIM
Analog dimming. Apply a PWM clock (40 to 1000 kHz) to pin and the duty cycle of this clock determines the LED current. Alternatively, apply
DC level between 0.2 and 2 V to vary LED current between 10% and 100%. If unused, pull pin above 2 V for 100%.
Enables the IC when this pin is pulled high. It also controls the on/off state of LED current sinks to reduce the light intensity by using pulse
width modulation. Typical PWM dimming frequency is in the range of 200 Hz to 2 kHz. When this pin is pulled low, the IC remains in standby
mode for up to 16 ms, then shuts down completely.
10
EN/PWM
LED6..LED1
LED current sinks #6 to #1. Connect the cathode of each LED string to pin. Unused LED pin must be terminated to AGND through a resistor
(4.75 kΩ for LED1/3/4/6, 2.37 kΩ for LED2/5).
11-16
17
18
19
20
21
22
OVP
PGND
VDRV
CS
Overvoltage Protection. Connect external resistor from VOUT to this pin to adjust the over voltage protection threshold.
Power Ground for internal Gate Driver. Connect pin to external power GND with shortest path.
Gate driver supply voltage (~6.5 V). Connect a 2.2 µF MLCC to PGND for buffer.
Current Sense for peak current control of power switch. Connect to sense resistor at the Source terminal of external power MOSFET.
Gate driver for power switch. Connect to Gate of external power MOSFET. (External FET must be fully enhanced at VGS = 5 V).
Output gate driver pin for external P-channel MOSFET (input disconnect switch).
GDRV
GATE
Connect this pin to the negative sense side of the input current sense resistor Rsc. The threshold voltage is measured as VIN – VSENSE
There is also fixed iADJ current sink to allow for trip threshold adjustment.
.
23
24
–
VSENSE
VIN
Input power to the IC as well as the positive side of input current sense resistor.
Exposed pad of the package providing enhanced thermal dissipation. Must be connected to the ground plane(s) of the PCB with at least 8
vias, directly in the pad.
PAD
5
Allegro MicroSystems
955 Perimeter Road
Manchester, NH 03103-3353 U.S.A.
www.allegromicro.com
A80605 and
A80605-1
High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
ELECTRICAL CHARACTERISTICS [1]: Unless otherwise noted, specifications are valid at VIN = 12 V, TJ = 25°C, • indicates specifica-
tions guaranteed over the full operating temperature range with TJ = –40°C to 125°C, typical specifications are at TJ = 25°C
Characteristics
INPUT VOLTAGE SPECIFICATIONS
Operating Input Voltage Range [3]
VIN UVLO Start Threshold
VIN UVLO Stop Threshold
UVLO Hysteresis [2]
Symbol
Test Conditions
Min.
Typ.
Max.
Unit
VIN
●
●
●
4.5
−
−
–
40
V
V
VUVLO(rise)
VUVLO(fall)
VUVLO_HYS
VIN rising
VIN falling
4.45
4.05
500
−
–
V
300
400
mV
INPUT CURRENTS
EN and PWM = H, CGATE = 1 nF from GDRV to
PGND, fSW = 2 MHz
VIN Pin Operating Current
VIN Pin Sleep Current
IOP
●
●
−
−
22
1
32
5
mA
µA
ISLEEP
VIN = 16 V, VEN / VPWM = VSYNC = 0 V
INPUT LOGIC LEVELS (EN/PWM, ADIM)
Input Logic Level-Low
VIL
VIH
●
●
−
−
−
0.4
−
V
V
Input Logic Level-High
1.5
30
60
REN/PWM
RADIM
Input = 5 V
Input = 5 V
50
100
70
kΩ
kΩ
Input Pull-Down Resistor
140
ANALOG DIMMING (ADIM)
iADIM50
iADIM25
fAPWM
DC 1.0 V applied to ADIM pin
DC 0.5 V applied to ADIM pin
Clock signal applied to ADIM pin
Clock signal applied to ADIM pin
−
23
40
0
50
25
−
−
27
%
%
Analog Dimming Current Level
(shown as % of full-scale current)
APWM Frequency Range [2]
APWM Duty Cycle Range [2]
VDD REGULATOR
●
●
1000
90
kHz
%
DAPWM
−
Regulator Output Voltage
VDD UVLO Start Threshold
VDD UVLO Stop Threshold
ERROR AMPLIFIER
VDD
VIN > 6 V, iLOAD < 1 mA
4.05
−
4.25
3.2
4.45
−
V
V
V
VDDUVLOrise VDD rising, no external load
VDDUVLOfall VDD falling, no external load
−
2.65
−
Amplifier Gain [2]
gm
VCOMP = 1.5 V
−
−
−
−
−
900
–500
–700
+500
1.4
−
−
−
−
−
μA/V
μA
VCOMP = 1.5 V, A80605 (symm COMP)
VCOMP = 1.5 V, A80605-1 (asymm COMP)
VCOMP = 1.5 V
Source Current
IEA(SRC)
μA
Sink Current
IEA(SINK)
RCOMP
μA
COMP Pin Pull Down Resistance
FAULT = 0, VCOMP = 1.5 V
kΩ
Continued on the next page…
6
Allegro MicroSystems
955 Perimeter Road
Manchester, NH 03103-3353 U.S.A.
www.allegromicro.com
A80605 and
A80605-1
High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
ELECTRICAL CHARACTERISTICS [1] (continued): Unless otherwise noted, specifications are valid at VIN = 12 V, TJ = 25°C, • indi-
cates specifications guaranteed over the full operating temperature range with TJ = –40°C to 125°C, typical specifications are at TJ = 25°C
Characteristics
Symbol
Test Conditions
Min.
Typ.
Max.
Unit
OVERVOLTAGE PROTECTION
OVP Pin Voltage Threshold
VOVP(th)
iOVP(th)
OVP pin connected to VOUT
Current into OVP pin at 125°C
Measured over temperature
●
●
2.2
140
140
2.5
146.5
150
2.8
153
160
V
µA
µA
OVP Pin Sense Current Threshold
OVP Sense Current Temperature
Coefficient [2]
∆iOVP
Current into OVP pin
VOUT = 16 V, EN = L
−
−36
−
nA/°C
OVP Pin Leakage Current
IOVPLKG
●
●
−
−
0.1
−
1
4
µA
%
%
V
OVP Variation at Output
ΔOVP
Measured at VOUT when ROVP = 188 kΩ
−
−
7
Measured at VOUT when ROVP = 188 kΩ [2]
Measured at VOUT when ROVP = 0 Ω
2.4
0.13
2.55
0.20
2.7
0.25
Undervoltage Detection Threshold
VUVP(th)
V
BOOST SWITCH GATE DRIVER
Gate Driver Supply Voltage
Gate Driver Pull-Up and Pull-Down
Gate Pull-Down When Disabled
Peak Sink Current [2]
VDRV
Measured at VIN > 7.5 V
−
−
−
−
−
6.5
2.5
100
2
−
−
−
−
−
V
Ω
RGDRV
Measured at iGDRV = 100 mA
RGDRV_OFF EN = L, VIN = 0 V
kΩ
A
iSINK
Measured at VGDRV = VDRV
Peak Source Current [2]
iSOURCE
Measured at VGDRV = 0 V
2
A
Measured with CLOAD = 1.5 nF;
VGDRV between 10% and 90% of VDRV
Gate Rise / Fall Time [2]
tRISE, tFALL
−
7
−
ns
Minimum Gate Driver On-Time
Minimum Gate Driver Off-Time
BOOST SWITCH CURRENT SENSE
tSW(ON)
●
●
−
−
−
−
100
100
ns
ns
tSW(OFF)
Exceeding iCS(LIM1) causes gate driver to
truncate existing cycle, but does not shut down
Primary Current Sense Limit
iCS(LIM1)
iCS(LIM2)
tCSDELAY
●
175
−
210
300
32
245
−
mV
mV
ns
Exceeding iCS(LIM2) causes gate driver to shut
down and latch off
Secondary Current Sense Limit [2]
Secondary Current Sense Limit
Propagation Delay
Overdrive CS threshold by 10%, excluding
leading edge blanking
−
−
OSCILLATOR FREQUENCY
RFSET = 10 kΩ
RFSET = 110 kΩ
RFSET = 10 kΩ
●
1.95
−
2.15
200
2.35
−
MHz
kHz
V
Oscillator Frequency
fSW
FSET Pin Voltage
VFSET
−
1.00
−
SYNCHRONIZATION
VSYNCL
VSYNCH
FSET/SYNC pin logic Low
FSET/SYNC pin logic High
●
●
●
●
●
−
−
−
−
−
−
0.4
−
V
V
Sync Input Logic Level
1.5
260
150
150
Synchronized PWM Frequency
Synchronization Input Min Off-Time
Synchronization Input Min On-Time
fSWSYNC
2300
−
kHz
ns
ns
tPWSYNCOFF
tPWSYNCON
−
Continued on the next page…
7
Allegro MicroSystems
955 Perimeter Road
Manchester, NH 03103-3353 U.S.A.
www.allegromicro.com
A80605 and
A80605-1
High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
ELECTRICAL CHARACTERISTICS [1] (continued): Unless otherwise noted, specifications are valid at VIN = 12 V, TJ = 25°C, • indi-
cates specifications guaranteed over the full operating temperature range with TJ = –40°C to 125°C, typical specifications are at TJ = 25°C
Characteristics
LED CURRENT SINKS
LEDx Accuracy [4]
Symbol
Test Conditions
Min.
Typ.
Max.
Unit
ErrLED
iISET = 120 µA (RISET = 8.33 kΩ)
●
●
−
−
0.7
0.8
3
2
%
%
LEDx Matching
ΔLEDx
iISET = 120 µA
Measured individually with all
other LED pins tied to ≥1 V,
iISET = 120 µA, VADIM > 2.1 V
A80605
●
650
750
850
mV
LEDx Regulation Voltage
VLED
A80605-1
●
●
760
955
860
978
0.985
−
960
1000
1.015
144
mV
A/A
V
IISET to ILEDx Current Gain
ISET Pin Voltage
AISET
VISET
iISET
iISET = 120 µA
VADIM > 2.1 V
VADIM > 2.1 V
0.955
20
Allowable ISET Current
●
●
µA
Sensed from each LED pin to GND while its current
sink is in regulation; all other LED pins tied to 1 V
LED String Partial-Short Detect
VLEDSD
tLEDSTG
4.85
5.5
1.5
6.1
V
LED Pin Shorted-to-GND Test
Duration [2]
Wait time before proceeding with Soft-Start (if
no LED pin is shorted to GND)
−
−
ms
Maximum time duration before all LED
channels come into regulation, or OVP is
tripped, whichever comes first
Soft-Start Ramp-Up Time [2]
Enable Pin Shut Down Delay
tSSRU
12.4
16
20.5
ms
EN goes from High to Low; exceeding tEN(OFF)
results in IC shutdown
tEN(OFF)
tPWMH
●
●
10
16
22
ms
µs
Minimum PWM On-Time
INPUT DISCONNECT GATE PIN
Gate Pin Sink Current
First and subsequent PWM pulses
−
0.3
0.4
IGSINK
VGS = VIN, no input OCP fault
−
−
−113
−
−
µA
Gate Pin Source Current
IGSOURCE
VGS = VIN – 6 V, input OCP fault tripped
6
mA
Gate Shutdown Delay When Over-
Current Fault Is Tripped [2]
tGATEFAULT
VGS
VIN – VSENSE = 200 mV; monitored at FAULT pin
−
−
−
3
µs
V
PMOS Gate to source voltage measured when
gate is on
Gate Voltage
−6.7
−
VSENSE PIN
VSENSE Pin Sink Current
VSENSE Trip Point
PEB PIN
iADJ
●
●
16
88
20
98
24
µA
VSENSETRIP Measured between VIN and VSENSE, RADJ = 0 Ω
108
mV
iPEB = 60 µA
3.2
5.6
4.6
8.1
6.0
µs
µs
PEB Delay Time
tPEB
iPEB = 100 µA
10.5
FAULT PIN
FAULT Output Pull-Down Voltage
FAULT Pin Leakage Current
External FAULT Input Low
External FAULT Input High
VFAULT
IFAULT-LKG
VFIL
iFAULT = 1 mA
−
−
−
−
−
−
0.5
1
V
µA
V
VFAULT = 5 V
No internal faults; FAULT pin externally pulled down
No internal faults
●
●
−
0.8
−
VFIH
1.5
V
No internal faults; delay (in fSW cycles) from
FAULT pin externally pulled L to LED off;
ignored if FAULT returns to H before that
External FAULT Deglitch Timer
tFIL
−
8
−
cycles
Continued on the next page…
8
Allegro MicroSystems
955 Perimeter Road
Manchester, NH 03103-3353 U.S.A.
www.allegromicro.com
A80605 and
A80605-1
High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
ELECTRICAL CHARACTERISTICS [1] (continued): Unless otherwise noted, specifications are valid at VIN = 12 V, TJ = 25°C, • indi-
cates specifications guaranteed over the full operating temperature range with TJ = –40°C to 125°C, typical specifications are at TJ = 25°C
Characteristics
Symbol
Test Conditions
Min.
Typ.
Max.
Unit
THERMAL PROTECTION (TSD)
Thermal Shutdown Threshold [2]
Thermal Shutdown Hysteresis [2]
TSD
Temperature rising
155
170
20
−
−
°C
°C
TSDHYS
−
[1] For input and output current specifications, negative current is defined as coming out of the node or pin (sourcing);
positive current is defined as going into the node or pin (sinking).
[2] Ensured by design and characterization; not production tested.
[3] Minimum VIN = 4.5 V is only required at startup. After startup is completed, IC can continue to operate down to VIN = 4 V.
[4] LED current is trimmed to cancel variations in both Gain and ISET voltage.
9
Allegro MicroSystems
955 Perimeter Road
Manchester, NH 03103-3353 U.S.A.
www.allegromicro.com
A80605 and
A80605-1
High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
APPLICATION EXAMPLE
ꢁꢂN
ꢃ1
ꢁꢀUꢅ ≤ ꢌ0 ꢁ
ꢇ1
ꢖ1
ꢌ.ꢍ ꢎꢉ
ꢊꢀUꢅ
RꢀꢁP1
RꢀꢁPꢏ
ꢊꢁꢃRꢁ
ꢁꢂN
ꢄꢃRꢁ
ꢁꢃRꢁ
ꢄAꢅꢆ
PꢄNꢃ
ꢄꢃRꢁ
ꢁꢃRꢁ
ꢄAꢅꢆ
PꢄNꢃ
ꢊS
ꢊS
ꢁSꢆNSꢆ
ꢁꢂN
ꢁSꢆNSꢆ
ꢀꢁP
ꢀꢁP
ꢁꢊ
ꢊꢁꢃꢃ
ꢁꢂN
ꢊꢁꢃꢃ
ꢁꢃꢃ
ꢁꢃꢃ
10 ꢋΩ
ꢇꢆꢃ1
ꢇꢆꢃ1
A80605-1
ꢀꢁAꢂꢃERꢄ
A80605-1
ꢀꢂLAꢅEꢄ
ꢇꢆꢃꢏ
ꢇꢆꢃ3
ꢇꢆꢃꢏ
ꢇꢆꢃ3
ꢉAUꢇꢅ
ꢉAUꢇꢅ
ꢆNꢑ
ꢆNꢑ
PꢒM
PꢒM
ꢇꢆꢃꢈ
ꢇꢆꢃꢈ
Uꢔ to 1ꢌ0 mA ꢕ ꢈ
Uꢔ to 1ꢌ0 mA ꢕ ꢈ
AꢃꢂM
AꢃꢂM
ꢊꢀMP
Pꢆꢓ
ꢊꢀMP
Pꢆꢓ
ꢉSꢆꢅ
AꢄNꢃ
ꢉSꢆꢅ
ꢂSꢆꢅ
ꢃꢂꢅH
AꢄNꢃ
ꢂSꢆꢅ
ꢃꢂꢅH
Rꢐ
ꢊP
RM
ꢊM
RꢂSꢆꢅ
RꢉSꢆꢅ
RPꢆꢓꢏ
RPꢆꢓ1
RꢂSꢆꢅ
RꢉSꢆꢅ
ꢊꢐ
Figure 4: Two A80605-1 connected in Master/Slave Configuration to drive 140 mA × 12 LED strings
Remarks on Master-Slave configuration:
• Only one Slave to a Master.
• Master-Slave operation requires asymmetrical COMP (for example: source = –700 µA and
sink = 500 µA). This is available in A80605-1 only.
• Also requires bidirectional FAULT pin of A80605-1, so that the slave can halt the switching of master.
10
Allegro MicroSystems
955 Perimeter Road
Manchester, NH 03103-3353 U.S.A.
www.allegromicro.com
A80605 and
A80605-1
High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
FUNCTIONAL DESCRIPTION
The A80605 is a multi-string LED regulator with six preci-
sion current sinks and a gate driver for external boost MOSFET
switch. It incorporates a patented Pre-Emptive Boost (PEB)
control algorithm to achieve PWM dimming ratio over 15,000:1
at 200 Hz. PEB control also minimizes output ripple to avoid
audible noise from output ceramic capacitors.
Only if no faults were detected, then the IC can proceed to start
switching.
During operation, the EN/PWM pin can be toggled to control the
brightness of LEDs channels by using PWM dimming. If EN/
PWM is pulled Low for longer than 16ms, the IC shuts off.
The switching frequency can be either synchronized to an
external clock or generated internally. Spread-spectrum tech-
nique (with user-programmable dithering range and modulation
frequency) is provided to reduce EMI. A clock-out signal (CLK-
OUT) allows other converters to be synchronized to the switching
frequency of A80605.
Enabling the IC
The A80605 wakes up when EN/PWM pin is pulled above logic
high level, provided that VIN pin voltage is over the VIN_UVLO
threshold. The boost stage and LED channels are enabled sepa-
rately by PWM = H signal after the IC powers up.
The IC performs a series of safety checks at power up, to deter-
mine if there are possible fault conditions that might prevent the
system from functioning correctly. Power-up checks include:
Figure 5: Startup showing (from top to bottom) EN/PWM, VDD, VDRV,
and ISET.
• VOUT shorted to GND
• LED pin shorted to GND
• FSET pin open/shorted
• ISET pin open/shorted to GND, etc.
11
Allegro MicroSystems
955 Perimeter Road
Manchester, NH 03103-3353 U.S.A.
www.allegromicro.com
A80605 and
A80605-1
High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
Unused LED pins should be terminated with a resistor to GND.
Powering Up: LED Detection Phase
Value of this termination resistor is 4.75 kΩ for channel 1, 3, 4, 5;
or 2.37 kΩ for channel 2, 6. At the end of LED detection phase,
any channel with pull-down resistor is then disabled and will not
contribute to the boost regulation loop.
The VIN pin has an undervoltage lockout (UVLO) function that
prevents the A80605 from powering up until the UVLO threshold is
reached. Once the VIN pin goes above UVLO and a high signal is
present on the EN pin, the IC proceeds to power up. At this point, the
A80605 is going to enable the disconnect switch and will try to check
if any LED pins are shorted to GND and/or are not used. The LED
detection phase starts when the GATE voltage of the input disconnect
PMOS switch is pulled down to 3.3 V below VIN.
ꢅꢆUꢇ
ꢀꢁꢂ ꢋh1 to ꢈ
are enaꢍled
ꢀꢁꢂ1
ꢀꢁꢂꢎ
ꢀꢁꢂ3
ꢀꢁꢂꢈ
ꢀꢁꢂ5
ꢀꢁꢂꢃ
ꢄNꢂ
ꢀꢁꢂ ꢋh5 ꢌ ꢃ
are disaꢍled
ꢎ.3ꢉ ꢊΩ ꢈ.ꢉ5 ꢊΩ
Figure 7: How to signal an unused LED channel
during startup LED detection phase
Table 1: LED Detection phase voltage threshold levels
LED Pin
Interpretation
Outcome
Voltage Measured
Cannot proceed with
soft-start unless fault
is removed
Figure 6: Startup showing EN/PWM, GATE, LED1, and ISET. Note
that LED Detection Phase starts as soon as GATE pin is pulled
down to 3.3 V below VIN.
LED pin shorted to
GND fault
< 120 mV
LED channel is
removed from
operation
LED channel not in
use
Once the voltage threshold on VLED pins exceeds ~120 mV, a
delay of approximately 1.5 ms is used to determine the status of
the pins.
~230 mV
> 340 mV
LED channel in use
Proceed with soft-start
12
Allegro MicroSystems
955 Perimeter Road
Manchester, NH 03103-3353 U.S.A.
www.allegromicro.com
A80605 and
A80605-1
High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
If an LED pin is shorted to ground, the A80605 will not proceed
with soft start until the short is removed from the LED pin. This
prevents the A80605 from ramping up the output voltage and put-
ting an uncontrolled amount of current through the LEDs.
The FAULT pin is pulled low in case of LED pin shorted-to-GND
fault, but the IC continues to retry. Once the fault is removed, the
soft-start process will continue. The same applies in case of FSET
or ISET pin is shorted to GND.
Figure 8: Normal startup showing all channels passed LED Detec-
tion phase (only LED1 and LED2 pin voltages are shown). Output
Voltage = 26.5 V (8× LED). Total LED current = 100 mA × 6.
Figure 10: LED1 is shorted-to-GND initially, then released. After the
fault is removed, the IC auto-recovers and proceeds with soft-start.
FAULT is released at the end of LED detection phase.
Figure 9: Normal startup showing LED1 channel is disabled with
a 4.75 kΩ resistor to GND. Total LED current = 100 mA × 5.
13
Allegro MicroSystems
955 Perimeter Road
Manchester, NH 03103-3353 U.S.A.
www.allegromicro.com
A80605 and
A80605-1
High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
This is illustrated by the following startup timing diagram (not to
scale):
Power Up: Boost Output Undervoltage
During startup, after the input disconnect switch has been
enabled, the output voltage is checked through the OVP (over-
voltage protection) pin. If the sensed voltage does not rise above
VUVP(th), the output is assumed to be at fault and the IC will not
proceed with soft start. Output UVP level is linked to the OVP
level programmed according to the equation:
Eꢀ
Pꢁꢂ
ꢀꢁN
3.3 ꢀ
ꢂ.ꢃ ꢀ
ꢃAꢄE
0
VUVP = VOVP / 12
1 ꢀ
LEDꢆ
0
Undervoltage protection may be caused by one of the following
faults:
ꢆꢇꢈ detection
ꢉhase
ꢌ1
ꢌꢍ
ꢄꢀP
93ꢅ ꢄꢀP
1.5 ms
• Output capacitor shorted to GND
• Boost inductor or diode open
• OVP sense resistor open
ꢅOUꢄ
ꢀꢁN
0
After an UVP (undervoltage protection) fault, the A80605 is
immediately shutdown and latched off. To enable the IC again,
the latched fault must be cleared. This can be achieved by
powering-cycling the IC, which means either:
tSSRU
iLED
0
Soꢊt-Start
Regꢋlation
A
B
ꢇ
D
E
• VIN falls below falling UVLO threshold, or
• EN = L for >16 ms.
Figure 11: Complete startup process of A80605
Explanation of Events:
Alternatively, latched fault can be cleared by keeping EN = H but
pulling PWM = L for >16 ms. This method has the advantage that
it does not interrupt the CLKOUT signal.
A: EN = H wakes up the IC. VDD ramps up and CLKOUT
becomes available. IC starts to pull down GATE slowly.
Soft Start Function
B: When GATE is pulled down to 3.3 V below VIN, ISET becomes
enabled. IC is now waiting for PWM = H to startup.
During startup, the A80605 ramps up its boost output voltage
following a fixed slope, as determined by OVP set point and Soft-
Start Timer. This technique limits the input inrush current, and
ensures consistent startup time regardless of the PWM dimming
duty cycle.
C: Once PWM = H, the IC checks each LEDx pins to determine
if it is in use, disabled, or shorted to GND.
D: Soft-Start begins at the completion of LED pin short-detect
phase of ~1.5 ms. VOUT ramps up following a fixed slope set by
OVP and soft-start timer of ~16 ms.
The soft-start process is completed when any one of the follow-
ing conditions is met:
E: Soft-start terminates when all LED currents reached regula-
• All enabled LED channels have reached their regulation
current,
• Output voltage has reached 93% of its OVP threshold, or
• Soft-start ramp time (tSS) has expired.
tion, VOUT reached 93% OVP, or soft-start timer expired.
Note when PWM pulse is significant small (depending on the
operating conditions), A80605 is in open loop regulation and the
output voltage will be regulated to OVP level in the steady state
as shown in curve C1; otherwise A80605 will regulate the output
voltage to the expected LED load voltage in the closed loop regu-
lation (as shown in curve C2).
To summarize, the complete startup process of A80605 consists
of:
• Power-up error checking
• Enabling input disconnect switch
• LED pin open/short detection
• Soft-start ramp
14
Allegro MicroSystems
955 Perimeter Road
Manchester, NH 03103-3353 U.S.A.
www.allegromicro.com
A80605 and
A80605-1
High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
Frequency Selection
t PꢂSꢃNꢄꢅN
15ꢁ ns
The switching frequency of the boost regulator is programmed
by a resistor connected to FSET pin. The switching frequency
can be selected anywhere from 200 kHz to 2.3 MHz. The chart
below shows the typical switching frequency verses FSET resis-
tor value.
150 ns
150 ns
tPꢂSꢃNꢄꢅꢆꢆ
t ꢀ ꢁ5ꢁ ns
Figure 13: Pulse width requirements
for an External Sync clock at 2.2 MHz
Based on the above, any clock with a duty cycle between 33%
and 66% at 2.2 MHz can be used. The table below summarizes
the allowable duty cycle range at various synchronization fre-
quencies.
Table 2: Acceptable Duty Cycle range for External Sync
clock at various frequencies
Sync. Pulse Frequency
2.2 MHz
Duty Cycle Range
33% to 66%
2 MHz
30% to 70%
1 MHz
15% to 85%
600 kHz
9% to 91%
Figure 12: Switching Frequency
as a function of FSET Resistance
300 kHz
4.5% to 95.5%
Alternatively, the following empirical formula can be used:
If it is necessary to switch over between internal oscillator and
external sync during operation, ensure the transition takes place
at least 500 ns after the previous PWM = H rising edge. Alterna-
tively, execute the switchover during PWM = L only. This restric-
tion does not apply if PWM dimming is not being used.
Equation 1:
fSW = 21.5 / (RFSET + 0.2)
where fSW is in MHz and RFSET is in kΩ.
If a fault occurs during operation that will increase the switch-
ing frequency, the internal oscillator frequency is clamped to a
maximum of 3.5 MHz. If the FSET pin is shorted to GND, the
part will shut down. For more details, refer to the Fault Mode
Table section.
Pꢀꢁ
500 ns
Eꢂtꢃꢄꢅnꢆ
1 ꢀ
ꢇ ꢈꢄEꢉ
Synchronization
The A80605 can also be synchronized using an external clock.
At power up, if the FSET pin is held low, the IC will not start.
Only when the FSET pin is tristated to allow for the pin to rise to
about 1 V, or when a sync clock is detected, the A80605 will then
try to power up.
ꢊnternal
ꢋloꢆꢌ
ꢁnternal oscillator
ꢂꢃternal Sync
Figure 14: Avoid switching over between Internal
Oscillator and External Sync in highlighted region
The basic requirement of the external sync signal is 150 ns
minimum on-time and 150 ns minimum off time. The diagram
below shows the timing restrictions for a synchronization clock at
2.2 MHz.
15
Allegro MicroSystems
955 Perimeter Road
Manchester, NH 03103-3353 U.S.A.
www.allegromicro.com
A80605 and
A80605-1
High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
ꢁꢆternal
Loss of External Sync Signal
Sychroniꢇation
ꢋꢋ0ꢌꢀ
Signal
Suppose the A80605 started up with a valid external SYNC sig-
nal, but the SYNC signal is lost during normal operation. In that
case, one of the following happens:
ꢀSꢁꢂꢃSꢄNꢅ
RꢀSꢁꢂ
10kΩ
Schottꢈy
ꢉarrier
ꢊiode
• If the external SYNC signal is high impedance (open), the
IC continues normal operation after approximately 5 μs, at
the switching frequency set by RFSET. No FAULT flag is
generated.
Figure 15: Countermeasure for
External Sync Stuck-at-Low Fault
• If the external SYNC signal is stuck low (shorted to ground),
the IC will detect an FSET-shorted-to-GND fault. FAULT
pin is pulled low after approximately 10 μs, and switching is
disabled. Once the FSET pin is released or SYNC signal is
detected again, the IC will proceed to soft-start.
It is important to use a small capacitance for the AC-coupling
capacitor (220 pF in the above example). If the capacitance is too
large, the IC may incorrectly declare a FSET-shorted-to-GND
fault and restart.
To prevent generating a fault when the external SYNC signal
is stuck at low, the circuit shown below can be used. When the
external SYNC signal goes low, the IC will continue to operate
normally at the switching frequency set by the RFSET. No FAULT
flag is generated.
16
Allegro MicroSystems
955 Perimeter Road
Manchester, NH 03103-3353 U.S.A.
www.allegromicro.com
A80605 and
A80605-1
High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
Switching Frequency Dithering
ꢄDꢃꢂH
i
ꢀꢁEꢂ ꢉ 100 ꢋA
ꢊ5 ꢋA
ꢀꢁEꢂ
DꢃꢂH
1.ꢆ ꢍ
1.0 ꢍ
0.ꢌ ꢍ
iDꢃꢂH ꢉ ꢊꢆ0 ꢋA
ꢄꢇSꢈꢂ
To minimize the peak EMI spikes at switching frequency har-
monics, the A80605 offers the option of frequency dithering, or
spread-spectrum clocking. This feature simplifies the input filters
needed to meet the automotive CISPR 25 conducted and radiated
emission limits.
RꢀꢁꢂH
ꢃ0.1 ꢄΩ
RꢇSꢈꢂ
10 ꢄΩ
ꢅꢀꢁꢂH
ꢆꢆ nꢇ
iDꢃꢂH
ꢆ0 ꢋA
0
ꢀithering Range ꢉ
ꢊ5ꢗ
ꢎꢆ0 ꢋA
Modꢓlation
ꢔreꢕꢓency
ꢉ 1.1 ꢄHꢖ
Period ꢉ 0.ꢌ ꢏ ꢅ ꢐ i
For maximum flexibility, the A80605 allows both dithering range
and modulation frequency to be independently programmable
using two external components.
ꢑ0.ꢌꢌ ms when ꢅ ꢉ ꢆꢆ nꢇꢒ
fꢁꢅ ꢆꢇHꢈꢉ
ꢆ.ꢆ5
ꢆ.15
ꢆ.05
The Dithering Modulation Frequency is given by the approximate
equation:
ꢂime ꢑmsꢒ
0
0.ꢌꢌ
Equation 2:
fDM (kHz) = 25 / CDITH (nF)
Figure 16: How to Program Switching Frequency
Dithering Range and Modulation Frequency
where CDITH is the value of capacitor connected from DITH
pin to GND.
There are no hard limits on dithering range and modulation
frequency. As a general guideline, pick a dithering range between
±5% and 10%, with the modulation frequency between 1 kHz and
3 kHz. In practice, using a larger dithering range and/or higher
modulation frequency do not generate any noticeable benefits.
The dithering Range is given by the approximate equation:
Equation 3:
Range (±%) = 20 × RFSET / RDITH
where RFSET is the resistor from FSET pin to GND, RDITH is
the resistor between DITH and FSET pins.
If dithering function is not desired, it can be disabled by discon-
necting the RDITH between DITH and FSET pins. Connect DITH
pin to VDD if CDITH is not populated. Dithering is always dis-
abled when fSW is controlled by external sync. RDITH and CDITH
have no effects in this case even if they were populated.
As an example, by using RFSET = 10 kΩ, RDITH = 40.1 kΩ,
and CDITH = 22 nF, the resulted switching frequency is fSW
2.15 MHz ±5% modulated at 1.1 kHz. This is illustrated by the
following diagram.
=
17
Allegro MicroSystems
955 Perimeter Road
Manchester, NH 03103-3353 U.S.A.
www.allegromicro.com
A80605 and
A80605-1
High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
LED Current Setting
The maximum LED current can be up to 140 mA per channel,
and is set through the ISET pin. Connect a resistor RISET between
this pin and GND. The relation between ILED and RISET is given
below:
Equation 4:
ILED = ISET × AISET
ISET = VISET / RISET
Therefore RISET = (VISET × AISET ) / ILED
= 963 / ILED
where ILED current is in mA and RISET is in kΩ.
This sets the maximum current through the LEDs, referred to
as the ‘100% current’. The average LED current can be reduced
from the 100% current level by using either PWM dimming or
analog dimming.
Figure 17: PWM dimming operation at 20% 1 kHz. CH1 = PWM (5 V/
div), CH2 = SW (20 V/div), CH3 = VOUT, CH4 = iLED (200 mA/div).
By using the patented Pre-Emptive Boost (PEB) control algo-
rithm, the A80605 is able to achieve minimum PWM dimming
on-time down to 300 ns. This translates to PWM dimming ratio
up to 15,000:1 at the PWM dimming frequency of 200 Hz. Tech-
nical details on PEB will be explained in the next section.
Table 3: ISET resistor values vs. LED current. Resistances
are rounded to the nearest E-96 (1%) resistor value.
Standard Closest RISET
LED current per channel
Resistor Value
6.81 kΩ
9.53 kΩ
12 kΩ
140 mA
100 mA
80 mA
60 mA
40 mA
16 kΩ
24 kΩ
PWM Dimming
When the EN/PWM pin is pulled high, the A80605 turns on all
enabled LED current sinks. When it is pulled low, all LED cur-
rent sinks are turned off. By changing the duty cycle of PWM
signal, the average LED current (and hence brightness) can be
accurately controlled.
During PWM = L, the IC floats the compensation (COMP) pin
and waits for the next PWM rising edge. But if PWM stays Low
longer than tEN(OFF) duration (16 ms typical), the IC shuts off
completely.
Figure 18: Zoom in view for PWM on-time = 10 µs. Notice that the
LED current is shifted with respect to PWM signal. Ripple at VOUT
is ~0.2 V when using 2 × 4.7 µF MLCC as output capacitors.
18
Allegro MicroSystems
955 Perimeter Road
Manchester, NH 03103-3353 U.S.A.
www.allegromicro.com
A80605 and
A80605-1
High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
CH1 (Yellow) = PWM (5 V/div); CH2 (Red) = Inductor current
(500 mA/div); CH3 (Blue) = VOUT (1 V/div); CH4 (Green) =
LED current (200 mA/div); time scale = 2 µs/div.
Figure 19: Zoom-in view showing A80605 is able to regulate LED
current at PWM on-time down to 300 ns.
The typical PWM dimming frequencies fall between 200 Hz and
1 kHz. There is no hard limit on the highest PWM dimming fre-
quency that can be used. However at higher PWM frequency, the
maximum PWM dimming ratio will be reduced. This is shown in
the following table:
Figure 20: Traditional PWM Dimming operation where boost switch
and LED current are enabled at the same time. Note that VOUT
shows overall ripple of ~0.5 V
When PWM signal goes high, a conventional LED driver turns
on its boost switching at the time with LED current sinks. The
problem is that the inductor current takes several switching cycles
to ramp up to its steady-state value before it can deliver full
power to the output load. During the first few cycles, energy to
the LED load is mainly supplied by the output capacitor, which
results in noticeable dip in output voltage.
Table 4: Maximum PWM Dimming Ratio that can be achieved
when operating at different PWM Dimming Frequency
Maximum PWM
PWM Frequency
PWM Period
Dimming Ratio
15,000:1
3,000:1
200 Hz
1 kHz
5 ms
1 ms
3.3 kHz
20 kHz
300 µs
50 µs
1,000:1
150:1
Pre-Emptive Boost
The basic principle of pre-emptive boost (PEB) can be best
explained by the following two waveforms. The first one shows
how a conventional LED driver operates during PWM dimming
operation. The second one shows that of the A80605.
Common test conditions for both cases:
PWM = 1% at 1 kHz (on-time = 10 µs), fSW = 2.15 MHz,
L = 10 µH, VIN = 12 V, LED load = 8 series (VOUT = ~25 V)
at 100 mA × 4. COUT = 2 × 4.7 µF 50 V 1210 MLCC.
COMP: RZ = 280 Ω, CZ = 68 nF.
Figure 21: A80605 PWM dimming operation with PEB delay set to
3 µs. Note that VOUT ripple is reduced to ~0.2 V.
Common scope settings:
19
Allegro MicroSystems
955 Perimeter Road
Manchester, NH 03103-3353 U.S.A.
www.allegromicro.com
A80605 and
A80605-1
High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
In the A80605, the boost switch is also enabled when PWM goes
high. However, the LED current is not turned on until after a
short delay of tPEB. This allows the inductor current to build up
before it starts to deliver the full power to LED load. During the
pre-boost period, VOUT actually bumps up very slightly, while
the following dip is essentially eliminated. When PWM goes low,
both boost switching and LED remains active for the same delay
of tPEB. Therefore the PWM on-time is preserved in LED current.
can significantly reduce the output ripple voltage compared to a
conventional LED driver.
A80605
ꢃꢂN
ꢂPꢀꢁ
Pꢀꢁ
RPꢄ
PEB delay can be programmed using an external resistor, RPEB
,
from PEB pin to GND. Their relationship is shown in the follow-
ing chart:
RPꢁ
13.0
12.0
11.0
10.0
9.0
Figure 23: PEB delay setup circuit with connection to VIN
12.0
11.0
10.0
9.0
8.0
7.0
6.0
8.0
5.0
7.0
4.0
6.0
3.0
2.0
5.0
1.0
4.0
0.0
3.0
6
8
10
12
14
RPEB (kΩ)
16
18
20
22
24
VIN = 18 V
VIN = 12 V
VIN = 6 V
2.0
1.0
0.0
Figure 22: How PEB delay time varies with value of PEB pin resis-
tor to GND.
Ideally, tPEB is equal to the inductor current ramp up time.
But the latter is affected by many external parameters, such
as switching frequency, inductance, VIN and VOUT ratio, etc.
Therefore, some experimentation is required to optimize the
PEB delay time. A simple guideline is to set PEB delay at
nominal VIN equal to 3 switching cycles (longer at lower VIN).
In general for switching frequency at 500 kHz, tPEB = 6 to 12 µs
is a good starting point.
20
30
40
50
60
70
IPEB (µA)
80
90
100 110 120
Figure 24: PEB delay tPEB vs. PEB pin current
Analog Dimming
The peak (100%) level of LED current is set by the RISET resistor.
The actual peak LED current may also be adjusted continuously
from approximately 10% up to 100%, by using the ADIM pin.
There are two methods to do so:
Additionally, adding a resistor from PEB to VIN (as shown
below) can extend PEB delay when VIN becomes lower. Refer
to the PEB delay versus PEB pin current below; for example,
at switching frequency 400 kHz, set IPEB = 80 μA to obtain
~5.88 μs PEB delay at VIN = 12 V by choosing RPB = 8.45 kΩ
and RPT = 604 kΩ (PEB voltage is fixed). When VIN lowers to
6 V, PEB delay becomes longer at 6.8 μs with IPEB = 90 μA. If
VIN increases to 18 V, PEB delay will be 5.2 μs.
1. In ADIM mode: apply a DC voltage between 0.2 V and 2 V
at the pin.
2. In APWM mode: apply a clock signal with duty cycle be-
tween 90% and 0% at the pin.
ADIM MODE
An analog voltage is applied at the ADIM/APMW pin. This DC
The advantage of PEB is that even a non-optimized delay time
20
Allegro MicroSystems
955 Perimeter Road
Manchester, NH 03103-3353 U.S.A.
www.allegromicro.com
A80605 and
A80605-1
High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
voltage linearly controls the peak LED current, as illustrated by
the chart below:
Normalized LED Current vs. APWM Duty Cycle
100ꢀ
80ꢀ
60ꢀ
40ꢀ
20ꢀ
0ꢀ
Nꢊꢅꢎꢌꢋꢏꢐꢆꢑ ꢁEꢂ ꢃꢄꢅꢅꢆꢇt ꢒs. ꢈꢂIꢉ Vꢊꢋtꢌꢍꢆ
100ꢀ
ꢊꢆꢎsꢄꢅꢆꢏ
90ꢀ
80ꢀ
70ꢀ
60ꢀ
50ꢀ
ꢐꢑꢆꢒꢅꢆ�ꢌꢎꢍ
ꢈꢂIꢉ ꢂꢆꢓꢅꢆꢌsꢏꢇꢍ
40ꢀ
ꢈꢂIꢉ Iꢇꢓꢅꢆꢌsꢏꢇꢍ
30ꢀ
0ꢀ
20ꢀ
40ꢀ
60ꢀ
80ꢀ
100ꢀ
ꢈPꢉꢊ ꢂꢄtꢋ ꢃꢋꢌꢍꢆ
20ꢀ
10ꢀ
0ꢀ
Figure 26: Showing LED current is inversely proportional to the
APWM duty cycle. Test conditions: VIN = 12 V, VOUT = 25 V (8 ×
WLED), total LED current = 100 mA × 4, APWM frequency = 100 kHz
0
0.2 0.4 0.6 0.8
1
1.2 1.4 1.6 1.8
2
2.2
ꢈꢂIꢉ Vꢊꢋtꢌꢍꢆ (V)
As an example, a system that delivers a full LED current of
100 mA per channel would deliver 75 mA when an APWM signal
with a duty-cycle of 25% is applied (because analog dimming
level is 100% – 25% = 75%). This is demonstrated by the fol-
lowing waveforms (only LED channels 1 to 4 are enabled).
Figure 25: In analog dimming mode, the LED current is linearly pro-
portional to ADIM voltage between 0.2 V and 2 V approximately
There is an internal pull-down resistor (100 kΩ typical) from
ADIM pin to GND. When this pin is left floating, LED current
is actually being dimmed down to ~10%. Therefore, if analog
dimming is not required, the ADIM pin should be pulled to over
2 V (but below VDD) to ensure 100% LED current. One simple
technique is to pull up ADIM to VDD through a 30 kΩ resistor.
APWM MODE
When a clock signal is detected at ADIM pin, the A80605 goes
into APWM mode. The typical APWM signal frequency is
between 40 kHz and 1 MHz. The duty cycle of this signal is
inversely proportional to the percentage of current delivered to
the LED. The relationship is shown below:
Figure 27: PWM = H. Total LED current drops from 400 mA (4 ×
100 mA/ch) to 300 mA when APWM of 25% duty cycle is applied.
Note that LED current takes ~1 ms to settle after change in APWM.
21
Allegro MicroSystems
955 Perimeter Road
Manchester, NH 03103-3353 U.S.A.
www.allegromicro.com
A80605 and
A80605-1
High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
• With PWM dimming on-time fixed at 0.5 µs, reduce peak
LED current from 100% down to 10%. This can be achieved
by either:
□ Apply a clock signal at APWM pin, and vary its duty cycle
from 0% to 90%, or
□ Apply a DC voltage at APWM pin, and vary its level from
2 V down to 0.2 V.
The net result of using both PWM and APWM is 100,000:1 dim-
ming ratio, as shown in the chart below:
Average LED Current vs. PWM Dimming Duty Cycle
100
10
Figure 28: PWM = 10% at 1 kHz. Peak LED current drops from
400 mA (4 × 100 mA/ch) to 300 mA when APWM of 25% duty cycle
is applied
1
0.1
One popular application of analog dimming is for LED brightness
calibration, commonly known as ‘LED Binning’. LEDs from
the same manufacturer and series are often grouped into differ-
ent ‘bins’ according to their light efficacy (lumens per watt). It is
therefore necessary to calibrate the ‘100% current’ for each LED
bin, in order to achieve uniform luminosity.
Pꢏꢐ ꢊꢅꢂꢂꢅꢍꢑ
ꢔPꢏꢐ ꢕ Pꢏꢐ
Iꢈꢇꢃꢄ
0.01
0.001
To use ADIM pin as a trim function, the user should first set the
100% current based on efficacy of LED from the lowest bin.
When using LED with higher efficacy, the required current is then
trimmed down to the appropriate level using APWM duty cycle.
0.001
0.01
0.1
1
10
100
Pꢏꢐ ꢊꢅꢂꢂꢅꢍꢑ ꢊꢌtꢒ ꢋꢒꢓꢄꢇ (ꢎ)
As an example, assume that:
Figure 29: How to achieve 100,000:1 dimming ratio by using both
PWM and APWM. Test conditions: VIN = 12 V, VOUT = 25 V (8 ×
WLED), total LED current = 400 mA, PWM frequency = 200 Hz,
APWM frequency = 100 kHz.
• LED from lowest bin has an efficacy of 80 lm/W
• LED highest bin has an efficacy of 120 lm/W
Suppose the maximum LED current was set at 100 mA based
on LEDs from lowest bin. When using LEDs from highest bin,
the current should then be reduces to 67% (80/120). This can be
achieved by sending APWM clock with 33% duty cycle.
Note that the A80605 is capable of providing analog dimming
range greater than 10:1. By applying APWM with 96% duty
cycle, for example, an analog dimming range of 25:1 can be
achieved. However, this requires the external APWM signal
source to have very fine pulse-width resolution. At 200 kHz
APWM frequency, a resolution of 50 ns is required to adjust its
duty cycle by 1%.
Extending LED Dimming Ratio
The dynamic range of LED brightness can be further extended,
by using a combination of PWM duty cycle, APWM duty cycle,
and analog dimming method.
For example, the following approach can be used to achieve a
100,000:1 dimming ratio at 200 Hz:
• Vary PWM duty cycle from 100% down to 0.01% to give
10,000:1 dimming. This requires PWM dimming on-time be
reduced down to 0.5 µs.
22
Allegro MicroSystems
955 Perimeter Road
Manchester, NH 03103-3353 U.S.A.
www.allegromicro.com
A80605 and
A80605-1
High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
In the following application example, the thermistor used is NTC-
Analog Dimming with External Voltage
S0805E3684JXT (680 kΩ @ 25°C). R1 = 336 kΩ, R2 = 20 kΩ,
and R3 = 8.45 kΩ. The LED current per channel is reduced from
97 mA at 25°C to 34 mA at 125°C.
Besides using ADIM pin, the LED current can also be reduced
by using an external voltage source applied through a resistor
to the ISET pin. The dynamic range of this type of dimming is
dependent on the ISET pin current. The recommended iSET range
is from 20 µA to 144 µA for the A80605. Note that the IC will
continue to work at iSET below 20 µA, but the relative error in
LED current becomes larger at lower dimming level.
ꢀꢁꢁ
ꢂꢃ.ꢄ5 ꢀꢅ
Aꢉ0ꢊ05
Nꢀꢁ
Rꢄ
ꢆSꢇꢈ
ꢂ1.0 ꢀꢅ
Below is a typical application circuit using a DAC (digital-analog
converter) to control the LED current. The ISET current (which
R1
directly controls the LED current) is normally set as VISET/RISET
.
ꢋNꢁ
R3
The DAC voltage can be higher or lower than VISET, thus adjust-
ing the LED current to a lower or higher value.
Figure 31: Thermal foldback of
LED current using NTC thermistor
Aꢃ0ꢄ05
Rꢅ
ꢈꢇAꢉ
ꢀSꢁꢂ
RꢀSꢁꢂ
ꢆNꢇ
Figure 30: Adjusting LED current
with an external voltage source
Equation 5:
VISET
RISET
VDAC −V
R2
ISET
iISET
=
−
where VISET is the ISET pin voltage (typically 1.0 V), and
VDAC is the DAC output voltage.
Figure 32: LED current varies with temperature
when using thermistor NTCS0805E3684JXT
for thermal foldback
When VDAC is higher than 1.00 V, the LED current is reduced.
When VDAC is lower than 1.00 V, the LED current is increased.
Some common applications for the above scheme include:
• LED binning
• Thermal fold-back using external NTC (negative temperature
coefficient) thermistor
23
Allegro MicroSystems
955 Perimeter Road
Manchester, NH 03103-3353 U.S.A.
www.allegromicro.com
A80605 and
A80605-1
High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
VDD
Shutdown
The VDD pin provides regulated bias supply for internal circuits.
Connect a CVDD capacitor with a value of 1 μF or greater to this
pin. The internal LDO can deliver up to 2 mA of current with a
typical VDD voltage of about 4.25 V. This allows it to serve as
the pull up voltage for FAULT pin.
If the EN/PWM pin is pulled low for longer than tEN(OFF)
(~16 ms), the A80605 enters shutdown (sleep mode). The next
time the EN/PWM pin goes high, all internal fault registers are
cleared. The IC needs to go through a complete soft start process
after PWM goes high.
VDRV
The VDRV pin provides a regulated gate driver supply for
external boost power MOSFET. Connect a CVDRV capacitor with
a typical value of 2.2 μF to this pin. The gate driver can deliver
up to 2 A of peak sink and source current, with a typical VDRV
voltage of 6.5 V. However, its average output current is limited to
approximately 36 mA. Note that average gate driver current is:
Equation 6:
iVDRV = fSW × QG
where fSW is the switching frequency and QG is the total gate
charge of the power MOSFET for VGS = 0 to 6.5 V.
At higher switching frequency, it is important to select a power
MOSFET with low QG to limit the average gate driver current.
Refer to the appendix section for details on MOSFET selection.
Figure 33: After EN/PWM (Yellow) goes Low for ~16 ms, the IC
completely shuts down so both VDD (Blue) and COMP (Red) decay.
24
Allegro MicroSystems
955 Perimeter Road
Manchester, NH 03103-3353 U.S.A.
www.allegromicro.com
A80605 and
A80605-1
High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
FAULT DETECTION AND PROTECTION
FAULT Status
ꢃꢄ ꢅꢆꢆ
The FAULT pin is an open-drain output that will be pulled low
when a fault occurs. A pull-up resistor (typically around 10 kΩ) is
required between this pin and desired logic level voltage (typi-
cally 3.3 to 5 V). Multiple devices with open-drain FAULT pins
can be connected in parallel to form a wired-AND configuration.
This way, when any device reports a fault, the system FAULT
signal is pulled low.
ꢏNꢔPꢕMꢖH ꢗ
ꢉꢃNꢘUꢉꢐꢅ
Power ꢁꢇ
ꢈꢉꢊꢊ, ꢋꢌ readyꢍ ꢌAꢎꢏ
ꢇꢁlled ꢐꢍ ꢀaꢁlt checꢑingꢒ
ꢏNꢔPꢕMꢖꢐ
ꢀAUꢐꢎ State
ꢈꢀAUꢐꢎ ꢇꢁlled ꢐꢒ
Any ꢀaꢁlt
detectedꢂ
The A80605-1 (One-Out-All-Out option) has a bidirectional
FAULT pin. This means the same pin also serves as an input to
monitor the status of system FAULT signal. When the FAULT
pin is pulled low externally for >8 fSW cycles by another device,
the A80605-1 disables its own boost switch and all LED current
sinks in response. This feature is required in Master/Slave con-
figuration, for example.
ꢓes
No
ꢏNꢔPꢕMꢖꢐ
ꢃꢄ Ready
ꢈꢀAUꢐꢎ ꢇꢁlled ꢐꢒ
ꢏNꢔPꢕMꢖH
Pin shorted
to ꢌNꢊ ꢆaꢁlt
ꢀAUꢐꢎꢖꢐ
The following two simplified flow charts demonstrate the differ-
ence between A80605 (unidirectional FAULT pin) and A80605-1
(bidirectional FAULT pin).
ꢐꢏꢊ Pin ꢄhecꢑ
ꢈꢃn Use, ꢊisaꢙled, or
Shorted to ꢌNꢊꢒ
ꢎime-oꢁt withoꢁt ꢆaꢁlts
ꢀAUꢐꢎ released
Soꢆt Start
ꢈenaꢙle ꢙoost Sꢕ and
ꢐꢏꢊ cꢁrrent sinꢑsꢒ
Any ꢀaꢁlt
detectedꢂ
ꢓes
No
PꢕM ꢊimming
ꢐꢏꢊꢖon
ꢄlear 1ꢚms timer
ꢏNꢔPꢕM ꢖ ꢐ
ꢏNꢔPꢕM ꢖ H
ꢐꢏꢊꢖoꢆꢆ
Start 1ꢚ ms timer
ꢎimer eꢛꢇired
Figure 34: Simplified A80605 Startup Flowchart
25
Allegro MicroSystems
955 Perimeter Road
Manchester, NH 03103-3353 U.S.A.
www.allegromicro.com
A80605 and
A80605-1
High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
ꢀꢄ ꢅꢆꢆ
ꢒNꢓPꢔMꢕH ꢖ
ꢉꢀNꢗUꢉꢏꢅ
Power ꢂꢇ
ꢈꢉꢊꢊ, ꢋgreadyꢌ ꢁaꢂlt
checꢍingꢎ
ꢒNꢓPꢔMꢕꢏ
ꢁAUꢏꢐ State
ꢈꢁAUꢏꢐ ꢇꢂlled ꢏꢎ
Any ꢀnternal
ꢁaꢂlt detectedꢃ
ꢑes
No
ꢒNꢓPꢔMꢕꢏ
ꢀꢄ Ready
ꢈꢁAUꢏꢐ ꢇꢂlled ꢏꢎ
ꢒNꢓPꢔMꢕH
Pin shorted
ꢏꢒꢊ Pin ꢄhecꢍ
to ꢛNꢊ ꢆaꢂlt
ꢈꢀn Use, ꢊisaꢘled, or
ꢁAUꢏꢐꢕꢏ
Shorted to ꢛNꢊꢎ
ꢐime-oꢂt withoꢂt ꢆaꢂlts
ꢁAUꢏꢐ released
Any ꢒꢚternal
ꢁaꢂlt detectedꢃ
ꢀes
ꢈꢁAUꢏꢐ ꢇꢂlled ꢏ
eꢚternallyꢎ
No
ꢈꢁAUꢏꢐꢕHꢎ
Soꢆt Start
ꢈenaꢘle ꢘoost Sꢔ and
ꢏꢒꢊ cꢂrrent sinꢍsꢎ
Any ꢀnternal
ꢁaꢂlt detectedꢃ
ꢑes
No
Any ꢒꢚternal
ꢁaꢂlt detected ꢃ
ꢀes
ꢈꢁAUꢏꢐ ꢇꢂlled ꢏ
eꢚternallyꢎ
No
PꢔM ꢊimming
ꢏꢒꢊꢕon
ꢄlear 1ꢙ ms timer
ꢒNꢓPꢔM ꢕ ꢏ
ꢒNꢓPꢔM ꢕ H
ꢏꢒꢊꢕoꢆꢆ
Start 1ꢙ ms timer
ꢐimer eꢚꢇired
Figure 35: Simplified startup flow chart for A80605-1, showing responses to both Internal
and External FAULT signals
26
Allegro MicroSystems
955 Perimeter Road
Manchester, NH 03103-3353 U.S.A.
www.allegromicro.com
A80605 and
A80605-1
High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
For A80605, the FAULT pin is pulled low in case any LED
LED String Partial-Short Detect
string is directly or partially shorted. The suspect LED string is
disabled, while the rest of the LED strings continue to operate.
FAULT pin is latched at low until it is reset by either EN = L or
PWM = L for >16 ms
All LED current sink pins (LED1 to LED6) are designed to with-
stand the maximum output voltage, as specified in the Absolute
Maximum Ratings table. This prevents the IC from being dam-
aged if VOUT is directly applied to an LED pin due to an output
connector short.
For A80605-1, all LED strings are turned off in case any LED
string has detected a partial short. FAULT pin is latched at low
until the IC is reset.
In case of direct-short or partial-shorted fault in any LED string dur-
ing operation, the LED pin with voltage exceeding VLEDSD will be
removed from regulation. This prevents the IC from dissipating too
much power due to large voltage drop across the LED current sink.
Figure 38: A80605-1 startup sequence when LED string#2 has a
partial-short fault (6 × WLED instead of 8). As soon as LED2 pin rises
above VLEDSD (~5 V), the channel is disabled but FAULT remains High.
Figure 36: A80605 Normal startup sequence showing voltage at LED1 and
At least one LED pin must be at regulation voltage (below
~1.2 V) for the LED string partial-short detection to activate.
In case all of the LED pins are above regulation voltage (this
could happen when the input voltage rises too high for the LED
strings), they will continue to operate normally.
LED2 pins. VIN = 6 V, output = 8 × WLED in series, current = 6 × 100 mA
Figure 37: A80605 startup sequence when LED string#2 has a partial-
short fault (6 × WLED instead of 8). As soon as LED2 pin rises above
VLEDSC (~5 V), the channel is disabled and FAULT = Low.
27
Allegro MicroSystems
955 Perimeter Road
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www.allegromicro.com
A80605 and
A80605-1
High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
Overvoltage Protection
The A80605 offers a programmable output overvoltage protection
(OVP). The OVP pin has a threshold level of 2.5 V typical. Overvolt-
age protection is tripped when current into this pin exceeds ~150 µA.
A resistor can be used to set the OVP threshold up to 40 V approxi-
mately. This is sufficient for driving 11 white LEDs in series.
The formula for calculating the OVP resistor is shown below:
Equation 7:
ROVP = (VOVP – VOVP(th)) / iOVP(th)
where VOVP is the desired OVP threshold, VOVP(th) = 2.5 V
typical, iOVP(th) = 150 µA typical.
To determine the desired OVP threshold, take the maximum LED
string voltage at cold and add ~10% margin on top of it.
Figure 39: A80605 startup with LED2 string open. VOUT hits OVP at
~30 V and LED2 is removed from regulation. FAULT pin goes Low
but remaining LED strings continue to operate.
The OVP event is not a latched fault and, by itself, does not pull
the FAULT pin to low. If the OVP condition occurs during a load
dump, for example, the IC will stop switching but not shut down.
For A80605-1, all LED strings are disabled in case any string is
not in regulation when VOUT hits OVP. FAULT pin is pulled low
and switching is stopped. The IC remains in latched off state until
it is reset.
OVP condition is typically caused by an open LED fault, or dis-
connected output connector. It may be detected either at startup or
during normal operation. This is explained separately below.
CASE 1: OVP AT STARTUP
During soft start period, the A80605 tries to boost VOUT until it
becomes high enough for all LED string to come into regulation.
But if any LED string is open, VOUT will eventually hit OVP. At
this point, the A80605 will disable any LED string that is still not
in regulation. The FAULT pin is pulled low and boost switching
is stopped to allow VOUT to fall. Once VOUT decreases by approx-
imately VOVP(th), switching resumes to power the remaining LED
strings.
Figure 40: A80605-1 startup with LED2 string open. VOUT hits
OVP and all LED string are disabled. FAULT pin goes Low and IC
remains latched off until reset.
28
Allegro MicroSystems
955 Perimeter Road
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www.allegromicro.com
A80605 and
A80605-1
High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
CASE 2: OVP DURING NORMAL OPERATION
Boost Switch Overcurrent Protection
When one LED string becomes open during operation, current
through its LED driver drops to zero. The A80605 responds by
boosting the output voltage higher. When output reaches OVP
threshold, the LED string without current is removed from regu-
lation. The rest of LED strings continue to draw current and drain
The external boost switch is protected with a cycle-by-cycle
primary current limit. When the voltage sensed at CS pin exceeds
VCS(LIM1) (typically 210 mV), the existing switching cycle is
truncated. That means the peak switching current is limited to:
Equation 8:
iSW(LIM1) = VCS(LIM1) / RCS
down VOUT. Once VOUT decreases by approximately VOVP(th)
,
boost will resume switching to power the remaining LED strings.
where RCS is the sense resistor connected from source of boost
MOSFET to power ground.
As an example, if RCS = 39 mΩ, then iSW(LIM1) = 5.4 A approxi-
mately.
The waveform below shows normal switching at VIN = 6 V, VOUT
= ~26 V and total LED current 800 mA. Average input current is
around 4.5 A.
Figure 41: An open-LED string faults causes VOUT to ramp up
and trip OVP. The A80605 then disables the open LED string and
continues with remaining strings.
The A80605-1, in contrast, will disable all LED strings in case
any LED string becomes open. The IC remains in latched off
state until it is reset.
Figure 43: Normal 400 kHz switching waveform at VIN = 6 V. Red
trace is the SW node voltage at 10 V/div. Green trace is the induc-
tor current at 1 A/div.
When the input voltage is reduced further to 5.6 V, input current
increases and peak switch current reaches 5.4 A. Overcurrent
protection is tripped to limit the peak SW current.
Figure 42: An open-LED string faults causes VOUT to ramp up and
trip OVP. The A80605-1 then disables all LED string and remains in
latched off state until reset.
29
Allegro MicroSystems
955 Perimeter Road
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www.allegromicro.com
A80605 and
A80605-1
High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
If the input current level goes above the preset threshold, the part
will be shut down in less than 3 µs. The FAULT pin is pulled
Low and the IC remains in latched off state until it is reset. This
feature prevents catastrophic failure in the system when there is
a direct short from VOUT to GND (caused by a shorted output
connector or cable, for example).
The waveform below illustrates the input overcurrent fault condi-
tion during startup. As soon as input OCP limit is reached, the
part disables the gate of the disconnect switch Q1 and latches off.
Figure 44: When peak current through the inductor reaches ~5.4 A,
overcurrent protection kicks in to truncate the present switching cycle.
There is also a secondary current sense limit VCS(LIM2), set at
about 40% higher than the cycle-by-cycle current limit. It is to
protect the external MOSFET from destructive current spikes in
case the boost inductor or boost diode is shorted. Once this limit
is tripped, the A80605 will immediately shut down and latch off.
Input Overcurrent Protection and
Disconnect Switch
Figure 46: Startup into an output shorted-to-GND fault. Input OCP
is tripped when current (Green trace) exceeds ~6.5 A. PMOS Gate
(Red) is turned off immediately and IC latches off.
iSꢆNSꢆ
ꢇꢈN
ꢅo ꢌ1
RSꢆNSꢆ
During startup when Q1 first turns on, an inrush current flows
through Q1 into the output capacitance. If Q1 turns on too fast
(due to its low gate capacitance), the inrush current may trip
input OCP limit. In this case, an external gate capacitance CG is
added to slow down the turn-on transition. Typical value for CG is
around 4.7 to 22 nF. Do not make CG too large, since it also slows
down the turn-off transient during a real input OCP fault.
ꢀ1
ꢁPMꢂSꢃ
RAꢉꢊ
ꢋꢄ
iAꢉꢊ
ꢄAꢅꢆ
ꢇSꢆNSꢆ
ꢇꢈN
A80605
ꢇꢈN ꢍ ꢇSꢆNSꢆ ꢎ RSꢆNSꢆ ꢏ iSꢆNSꢆ ꢐ RAꢉꢊ ꢏ iAꢉꢊ
Figure 45: Optional input disconnect switch using a PMOSFET
The primary function of the input disconnect switch is to protect
the system and the device from excessive input currents during a
fault condition.
30
Allegro MicroSystems
955 Perimeter Road
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A80605 and
A80605-1
High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
Setting the Input Current Sense Resistor
Fault Protection During Operation
The input disconnect switch threshold is typically 98 mV, mea-
sured between VIN and VSENSE pins when RADJ is 0 Ω. This
threshold can be trimmed slightly using the RADJ resistor.
The A80605 constantly monitors the state of the system to deter-
mine if any fault conditions occur during normal operation. The
response to a triggered fault condition is summarized in the table
below. It is important to note that there are several points at which
the A80605 monitors for faults during operation. The locations are
input current, switch current, output voltage, switch voltage, and
LED pins. Some of the protection features might not be active dur-
ing startup to prevent false triggering of fault conditions.
To avoid false tripping, the input disconnect switch overcurrent
limit should be set higher than the boost switch cycle-by-cycle cur-
rent limit. For example, the boost switch OCP is set at 5.4 A, so the
input disconnect switch OCP may be set 25% higher at 6.75 A. The
input current sense resistor is then calculated as below.
The possible fault conditions that the part can detect include:
When RADJ is not used:
• Open LED Pin or open LED string
• Shorted or partially shorted LED string
• LED pin shorted to GND
• Open or shorted boost diode
• Open or shorted boost inductor
• VOUT short to GND
VIN – VSENSE = RSENSE × iSENSE = 98 mV
The desired sense resistor is RSENSE = 98 mV / 6.75 A =
14.5 mΩ. But this is not a standard E-24 resistor value. Pick the
closest lower value which is 13 mΩ.
When RADJ is used:
• SW shorted to GND
VIN – VSENSE = RSENSE × iSENSE + RADJ × iADJ
Therefore
• ISET shorted to GND
• FSET shorted to GND
• Input disconnect switch drain shorted to GND
RADJ = [(VIN – VSENSE) – (RSENSE × iSENSE)] / iADJ
= [98 mV – 88 mV] / 20 µA = 500 Ω
Pick the closest E-96 resistor value of 499 Ω.
Note that some of these faults will not be protected if the input
disconnect switch is not being used. An example of this is VOUT
short to GND fault.
Input UVLO
When VIN rises above VUVLOrise threshold, the A80605 is
enabled. The IC is disabled when VIN falls below VUVLOfall
threshold for more than 50 μs. This small delay is used to avoid
shutting down because of momentary glitches in the input power
supply.
31
Allegro MicroSystems
955 Perimeter Road
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A80605 and
A80605-1
High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
Table 5: A80605 Fault Mode Table
Fault Flag
Set
Disconnect
Switch
Fault Name
Type
Active
Description
Boost Switch
LED Sink drivers
This fault condition is triggered when the SW current exceeds the
cycle-by-cycle current limit, ISW(LIM).The present SW on-time is
truncated immediately to limit the current. Next switching cycle starts
normally.
Primary Switch Overcurrent
Protection (Cycle-By-Cycle Auto-restart
Current Limit)
Off for a single
cycle
Always
NO
ON
ON
When current through boost switch exceeds secondary SW current
limit (iSW(LIM2)) the device immediately shuts down the disconnect
switch, LED drivers and boost. The Fault flag is set. To reset the fault
the EN/PWM pin needs to be pulled low for ~16 ms.
Secondary Switch Current
Limit
Latched
Off
Always
YES
OFF
OFF
OFF
The device is immediately shut off if the voltage across the input
sense resistor is above the VSENSEtrip threshold. To reset the fault the
EN/PWM pin must be pulled low for ~16 ms.
Input Disconnect Current
Limit
Latched
Off
Always
Startup
YES
YES
OFF
OFF
OFF
ON
OFF
OFF
If any of the LED pins is determined to be shorted to GND when PWM
first goes high, soft-start process is halted. Only when the short is
removed, then soft-start is allowed to proceed.
LEDx Pin Shorted to GND
Auto-restart
Auto-restart
If an LED string is not getting enough current, the device will first
respond by increasing the output voltage until OVP is reached. Any
LED string that is still not in regulation will be disabled. The device will
then go back to normal operation by reducing the output voltage to
the appropriate voltage level.
LEDx Pin Open
(One-Out-Continue option)
Normal
operation
OFF for open pins.
ON for all others.
YES
YES
ON
ON
If an LED string is not getting enough current, the device will first
respond by increasing the output voltage until OVP is reached. If any
LED string is still not in regulation, all LED strings will be disabled and
the device latched off. To reset the fault the EN/PWM pin must be
pulled low for ~16 ms.
LEDx Pin Open
(One-Out-All-Out option)
Normal
operation
Latched
OFF
OFF
OFF
Fault occurs when the ISET current goes above 150% of max current.
The boost will stop switching and the IC will disable the LED sinks
until the fault is removed. When the fault is removed, the IC will try to
regulate to the preset LED current.
ISET Short Protection
Auto-restart
Auto-restart
Always
Always
YES
YES
OFF
OFF
ON
ON
OFF
OFF
Fault occurs when the FSET current goes above 150% of max
current. The boost will stop switching, Disconnect switch will turn off
and the IC will disable the LED sinks until the fault is removed. When
the fault is removed, the IC will try to restart with soft-start.
FSET/SYNC Short
Protection
Fault occurs when current into OVP pin exceeds iOVP(th) (typically
150 µA). The IC will immediately stop switching but keep the LED
drivers active, to drain down the output voltage. Once the output
voltage decreases by approximately VOVP(th), the IC will restart
switching to regulate the output current.
STOP during
OVP event.
Overvoltage Protection
Undervoltage Protection
Auto-restart
Auto-restart
Always
Always
NO
ON
ON
ON
Device immediately shuts off boost and current sinks if the voltage at
VOUT is below VUVP(th). This may happen if VOUT is shorted to GND,
or boost diode is open before startup. It will auto-restart once the fault
is removed.
YES
OFF
OFF
Fault occurs if an LED pin voltage exceeds VLEDSC with its current
sink in regulation, while at least one other LED pin is below ~1.2 V.
This may happen when two or more LEDs are shorted within a string.
The LED string exceeding the threshold will be disabled and removed
from operation. Device will re-enable the LED string when its pin
voltage falls below threshold, or at the next PWM = H.
LED String Partial Short
Detection (One-Out-
Continue option)
OFF for shorted
string, ON for all
others.
Auto-restart
Latched
Always
Always
YES
YES
ON
ON
LED String Partial Short
Detection (One-Out-All-Out
option)
If two or more LEDs are shorted within a string, all LED strings will be
disabled and the device latched off. To reset the fault, EN or PWM pin
must be pulled low for ~16 ms.
OFF
OFF
OFF
Fault occurs when the die temperature exceeds the over-temperature
threshold, typically 170°C. IC will restart after temperatures drops
lower by TSDHYS
Overtemperature Protection Auto-restart
Always
Always
YES
NO
OFF
OFF
OFF
OFF
OFF
OFF
Fault occurs when VIN drops below VUVLO(fall). This fault resets all
latched faults.
VIN UVLO
Auto-restart
Continued on next page...
32
Allegro MicroSystems
955 Perimeter Road
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www.allegromicro.com
A80605 and
A80605-1
High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
Table 5: A80605 Fault Mode Table (continued)
Fault Flag
Set
Disconnect
Switch
Fault Name
Type
Active
Description
Boost Switch
LED Sink drivers
FAULT pin pulled Low
Externally (One-Out-
Continue option)
Always
ignored
In One-Out-Continue mode (with unidirectional FAULT pin), external
status of FAULT pin does not affect the operation of the IC in any way.
Always ignored
No change
No change
No change
No change
No change
In One-Out-All-Out mode (with bidirectional FAULT pin), if FAULT pin
is externally pulled Low, the IC immediately shuts off its boost and
LED current sinks. IC can only restart when external fault status is
cleared AND there is no internal fault status pending. That means
local latching faults cannot be cleared by externally forcing FAULT
pin to High.
FAULT pin pulled Low
Externally (One-Out-All-Out Auto-restart
option)
Always
OFF
ON
OFF
LED ꢀtring Partial-ꢀhort Deteꢁtion in One-Out-ꢂontinue modeꢃA80605ꢄ
ꢄaꢅlt Remoꢆed
No ꢄaꢅlts
ꢀꢁꢂꢃ String Partial-Short
ꢄaꢅlt asserted
Pꢋꢌ
ꢀꢁꢂꢃ
ꢀꢁꢂ1
LED1ꢇ
LEDꢈ
ꢑꢀꢁꢂSꢂ
0
ꢃ00 mA
iꢍLED 100 mA
0
ꢅAULꢆ
D
H
A
E
ꢉ
B
ꢅ
ꢂ
Eꢊplanation of events ꢇ
Aꢇ PꢈM goes High and all ꢀꢁꢂ driꢆers oꢉerate normally. ꢊꢄor simꢉlicity, assꢅme only ꢀꢁꢂ 1
and ꢀꢁꢂꢃ are in ꢅse, each sinꢋing 100 mA.ꢌ
Bꢇ A ꢉartial-short ꢍaꢅlt is asserted to ꢀꢁꢂ ꢃ string. Nothing haꢉꢉens yet since PꢈM ꢎ ꢀ.
ꢂꢇ At the neꢏt PꢈM ꢎ H, ꢀꢁꢂꢃ ꢉin ꢆoltage stays aꢐoꢆe ꢑꢀꢁꢂSꢂ while ꢀꢁꢂ1 ꢉin is at regꢅlation
ꢆoltage.
Dꢇ Aꢍter ꢉartial-short detection time ꢊꢒꢃ ꢓsꢌ, ꢀꢁꢂꢃ string is disaꢐled and ꢄAUꢀꢔ ꢉin ꢉꢅlled
ꢀow. ꢀꢁꢂ1 string continꢅes to oꢉerate.
Eꢇ At sꢅꢐseꢕꢅent PꢈM ꢎ H, ꢖꢗ retries ꢀꢁꢂ1 ꢐꢅt shꢅts it oꢍꢍ again since the ꢍaꢅlt is still
ꢉresent. ꢄAUꢀꢔ ꢍlag remains ꢀow.
ꢅꢇ Partial Short ꢍaꢅlt is remoꢆed ꢍrom ꢀꢁꢂ ꢃ string. Nothing haꢉꢉens yet since PꢈM ꢎ ꢀ.
ꢉꢇ At the neꢏt PꢈM ꢎ H, ꢖꢗ retries ꢀꢁꢂ1 and it ꢉasses. ꢘꢅt ꢄAUꢀꢔ ꢍlag is not cleared
Hꢇ ꢄAUꢀꢔ ꢍlag is cleared at the second PꢈM ꢎ H aꢍter Partial Short ꢍaꢅlt was remoꢆed.
33
Allegro MicroSystems
955 Perimeter Road
Manchester, NH 03103-3353 U.S.A.
www.allegromicro.com
A80605 and
A80605-1
High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
PACKAGE OUTLINE DRAWING
For Reꢀerence ꢁnly ꢂ Not ꢀor Tooling ꢃse
Reference Allegro DWG-2871 (Rev. A) or ꢀEDEC MO-220WGGD.
Dimensions in millimeters – NOT TO SCALE.
Exact case and lead configuration at supplier discretion within limits shown.
0.50
0.30
4.00 ꢂ0.10
24
24
0.95
1
2
1
2
A
4.00 ꢂ0.10
4.10
2.80
DETAIL A
2.80
4.10
D
C
24ꢁ
0.75 ꢂ0.05
0.0-0.05
0.08
C
SEATING
PLANE
C PCB Layout Reference View
ꢄ0.05
–0.07
0.25
0.50 BSC
0.40 ꢂ0.10
0.14 REF
0.10 REF
0.20 REF
0.203 REF
0.05 REF
0.05 REF
0.40 ꢂ0.10
B
Detail A
ꢄ0.10
–0.15
2.70
2
1
A
B
Terminal ꢃ1 mark area
Exposed thermal pad (reference only, terminal #1 identifier appearance at supplier discretion)
24
C
Reference land pattern layout (reference IPC7351 QFN50P400X400X80-25W6M); 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/ꢀEDEC Standard ꢀESD51-5)
0.20 REF
ꢄ0.10
–0.15
2.70
0.10 REF
D
Coplanarity includes exposed thermal pad and terminals
Figure 47: Package ES, 24-Pin 4 mm × 4 mm QFN with Exposed Thermal Pad and Wettable Flank
34
Allegro MicroSystems
955 Perimeter Road
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A80605 and
A80605-1
High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
APPENDIX A: DESIGN EXAMPLE
This section provides step-by-step instructions to select compo-
nent values for an A80605 application.
Step 3: Determining the OVP resistor according to Equation 6:
ROVP = (VOVP – VOVP(th)) / iOVP(th)
For the purposes of this example, the following operating condi-
tions are assumed:
The nominal output voltage is:
VOUT_nom = n × Vf + VREG
• VIN = 12 V nominal (6 V min, 18 V max)
• Number of LED channels nc = 6
where VREG is the LED pin regulation voltage. Substitute n = 7,
Vf = 3.2 V and VREG = 0.85 V to get VOUT_nom = 23.25 V.
• Number of series LEDs per channel n = 7
• LED current per channel ILED = 100 mA
• LED forward drop Vf = 3.2 V max at cold
• Switching frequency fSW = 2.15 MHz
Set the OVP threshold voltage approximately 10% higher, to
account for error margin and component tolerances:
VOVP = VOUT_nom × 1.1 = 25.6 V
The OVP resistor is therefore:
• Dithering modulation frequency fDITH = 1 kHz
• Dithering frequency range ∆fSW = ±5%
• Max ambient temperature TA(max) = 65°C
• PWM dimming frequency fPWM = 200 Hz
Step 1: Program the Switching Frequency from Equation 1:
ROVP = (25.6 V – 2.5 V) / 150 µA
= 154 kΩ (pick 154 kΩ)
Step 3a: Check to ensure the maximum boost duty cycle is suf-
ficient to achieve the required conversion ratio.
DMAX(boost) = 1 – tSW(off) × fSW(max)
fSW = 21.5 / (RFSET + 0.2)
Therefore
where tSW(off) is the worst-case minimum SW on-time, and
fSW(max) is the maximum switching frequency with dithering.
RFSET – 0.2 = 21.5 / fSW
Substitute tSW(off) = 100 ns and fSW(max) = 2.26 MHz to get
DMAX(boost) = 0.774.
where fSW is in MHz and RFSET is in kΩ.
Substitute fSW = 2.15 MHz to get RFSET = 9.8 kΩ (pick 10 kΩ).
Theoretical maximum output voltage at the lowest input voltage is:
VOUT(max) = VIN(min) / (1 – DMAX(boost)) – VD
Step 1a: Program the Dithering Modulation Frequency from
Equation 2:
where VD is the forward drop of boost Schottky diode.
fDITH (kHz) = 25 / CDITH (nF)
Substitute fDITH = 1 kHz to get CDITH = 25 nF (pick 22 nF).
Step 1b: Select Dithering Range from Equation 3:
∆fSW Range (±%) = 20 × RFSET / RDITH
Substitute VIN(min) = 6 V, DMAX(boost) = 0.774, and VD = 0.4 V to
get VOUT(max) = 26.15 V.
Theoretical VOUT(max) has to be greater than VOVP. If this is not
the case, then switching frequency of the boost converter must be
reduced to meet the maximum duty cycle requirement.
Substitute Range = 5 and RFSET = 10 kΩ to get RDITH = 40 kΩ
(pick 40.2 kΩ). The switching frequency now linearly sweeps
between 2.04 and 2.26 MHz.
Step 4 – Inductor selection: The inductor must be chosen
based on ripple current requirement. In most applications due to
stringent EMI requirements, the system also needs to operate in
continuous conduction mode (CCM) throughout the whole input
voltage range. A simple guideline is to start with 30% peak-to-
peak ripple current at nominal input and output voltages.
Step 2: Determine the LED current set Resistor RISET from
Equation 4:
RISET = (VISET × AISET) / ILED
Step 4a: Determine the Boost Duty Cycle:
Substitute VISET = 0.985 V, AISET = 978, and iLED = 100 mA to
get RISET = 9.63 kΩ (pick 9.53 kΩ).
D = 1 – VIN / (VOUT + VD)
35
Allegro MicroSystems
955 Perimeter Road
Manchester, NH 03103-3353 U.S.A.
www.allegromicro.com
A80605 and
A80605-1
High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
For nominal operation, substitute VIN_nom = 12 V, VOUT_nom
23.25 V and VD = 0.4 V to get Dnom = 0.493.
=
Step 5: To verify that there is sufficient slope compensation for
the inductor chosen. The A80605 generates a variable internal
Slope Comp according to fSW and VIN.
Step 4b: Calculate the nominal Input Current based on esti-
mated efficiency:
• If VIN is between 9 V and 15 V:
SC = 3 × fSW × VIN / 12
iIN = VOUT × iOUT / (VIN × η)
• If VIN < 9 V:
where η = efficiency of the converter (typically in the 85% to
90% range).
SC = 3 × fSW × 9 / 12
• If VIN > 15 V:
For nominal operation, substitute VOUT = 23.25 V, iOUT = 0.6 A,
VIN = 12 V, and η = 0.9 to get iIN = 1.29 A.
SC = 3 × fSW × 15 / 12
where fSW is in MHz and SC is in A/µs.
Step 4c: Select Boost Inductance based on 30% Ripple Current.
For nominal operation, ∆iL = 0.3 × iIN = 0.39 A.
∆iL = tON × VIN / L = D × VIN / (fSW × L)
For example, at fSW = 2.15 MHz and VIN = 6 V, SC = 4.74 A/µs
The falling slope of inductor current is given as:
diL/dt = –∆iL / tOFF = –∆iL × fSW /(1 – D)
Therefore:
Based on equations from previous section, at VIN = 6 V and
VOUT(OVP) = 25.6 V, D = 0.769 and ∆iL = 0.316 A. Therefore
|diL/dt| = 2.94 A/µs, which is slower than the internal slope. That
means there is sufficient slope compensation.
L = D × VIN / (fSW × ∆iL)
Substitute Dnom = 0.493, VIN_nom = 12 V, and fSW = 2.15 MHz to
get L = 7.1 µH (pick 6.8 µH).
STEP 4d: Determine the maximum and minimum input current
to the system. The maximum current determines the inductor’s
saturation current rating. The minimum current determines its
critical inductance.
In case the negative slope of inductor current is faster than the
internal slope comp, a higher inductance value must be used.
Step 6: Select External Boost Switch MOSFET.
Refer to Appendix B for more details on how to select the exter-
nal boost MOSFET. For this example, the MOSFET picked is
NVD5867NL with the following key parameters:
Maximum input current occurs at minimum VIN and maximum
VOUT (OVP).
iIN_max = VOVP × iOUT / (VIN_min × η)
• Breakdown voltage V(BD)DSS = 60 V min
Substitute VOVP = 25.6 V, VIN_min = 6 V, and η = 0.85 to get
iIN_max = 3.01 A.
• On-resistance RDS(on) = 50 mΩ max at VGS = 4.5 V
• Total Gate Charge QG = 10 nC for VGS = 0 to 6.5 V
Step 7: Select boost switch current sense resistor.
Peak inductor current:
iL_peak = iIN_max + ∆iL / 2
From Equation 8:
At minimum VIN = 6 V, D = 0.769, ∆iL = 0.316 A, and so iL_peak
= 3.01 + 0.316 / 2 = 3.17 A. Therefore, the inductor should have a
saturation current of at least 3.8 A (20% higher than iL_peak).
RCS = VCS(LIM1) / iSW(LIM1)
From previous section, iL_peak = 3.17 A at min VIN and max
VOUT. Set the cycle-by-cycle SW current limit at least 20%
higher, which means ~3.8 A. Therefore:
Minimum input current occurs at maximum VIN and nominal
VOUT
.
RCS = 210 mV / 3.8 A = 55 mΩ
iIN_min = VOUT_nom × iOUT / (VIN_max × η)
Pick a standard E-12 resistor value of 47 mΩ. This gives cycle-
by-cycle current limit of iSW(LIM1) = 4.5 A.
Substitute VOUT_nom = 23.25 V, VIN_max = 18 V, and η = 0.9 to get
iIN_min = 0.865 A.
Step 8: Choosing the input disconnect switch components.
At maximum VIN = 18 V, D = 0.239, ∆iL = 0.294 A, and so
iL_valley = 0.865 – 0.294 / 2 = 0.718 A. Therefore the converter
operates in CCM throughout the input voltage range.
Set the input disconnect switch current limit at least 20% above
the SW cycle-by-cycle current limit:
36
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A80605 and
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iSENSE = 3.8 A × 1.2 = 4.56 A
RSC = VSENSETRIP / iSENSE = 21.5 mΩ
The biggest contributing factors for total output capacitance are
PWM off-time and leakage current (iLK). This current is mainly
due to the reverse current of switching diode, plus a small/negli-
gible leakage current into the OVP pin.
Pick the closest lower resistance value from E-24 series, which is
20 mΩ.
In this design example, the PWM dimming frequency is 200 Hz
with minimum duty cycle of 0.01%. So the maximum PWM
off-time is essentially tOFF = 5 ms. A typical goal is to keep the
output voltage variation at 250 mV or less, so that no audible
hum can be heard.
RADJ = [VSENSETRIP – (RSC × iSENSE)] / iADJ = 340 Ω
Select the input disconnect switch P-MOSFET based on its drain-
source breakdown voltage and on-resistance.
The SQJ459EP can be used in this case. It has VDS = –60 V and
∆VOUT = tOFF × iLK / COUT
RDS(ON) = 24 mΩ at VGS = –4.5 V.
Therefore:
Step 9: Select the switching diode.
COUT = tOFF × iLK / ∆VOUT
A Schottky barrier diode (SBD) is typically selected based on its
voltage and current ratings:
Substitute tOFF = 5 ms, iLK = 110 µA, and ∆VOUT = 0.25 V to get
COUT = 2.2 µF.
• The reverse voltage rating must be higher than the maximum
voltage stress, which is equal to the OVP threshold in this
case.
A major problem with multilayer ceramic capacitor (MLCC)
is that its actual capacitance drops with respect to DC bias. For
example, the capacitance of a 4.7 µF, 50 V, 0805 MLCC may
be derated by 80% when it is biased at 25 V. That means its real
capacity is less than 1 µF in actual application.
• The average forward current rating must be higher than the
total LED current. The peak current through diode is given as:
iD_peak = iL_peak = iIN_max + ∆iL / 2
MLCC with larger physical size and higher voltage rating typi-
cally suffers less derating problem. For example, a 4.7 µF, 50 V,
1210 MLCC may retain 3.3 µF of capacitance at 25 V. This is
shown in the table below:
From previous calculation at minimum VIN, iL_peak = 3.17 A.
However, during transient, this current could reach cycle-by-
cycle SW current limit, iSW(LIM)
.
Another critical parameter is the diode’s reverse leakage current
at hot. This is especially important when using PWM dimming.
During PWM off time, the boost converter is not switching, so
voltage at output capacitor decays due to leakage current. This
increases output ripple voltage, which may generate audible noise
from ceramic capacitors.
Rated
Capacitance
at 0 V (µF)
Actual
Capacitance
at 25 V (µF)
Derating at
25 V
Part Number
Package
GRM21BC71H475KE11
GRM31CR71H475MA12
GRM32ER71H475KA88
0805
1206
1210
4.7
4.7
4.7
–80%
–45%
–30%
0.94
2.59
3.29
Make sure to verify the diode’s reverse current at hot (such as
125°C) and at the nominal VOUT. As a general guideline, look
for a diode with leakage of 100 µA or less. If necessary, consider
using a diode with higher voltage rating (such as 100 V instead
of 50 V). Doing so can significantly reduce the leakage current at
Step 11: Selection of input capacitor.
A combination of MLCC and electrolytic capacitor is recom-
mended. The MLCC provides low ESR to reduce input switching
ripple. The electrolytic capacitor provide larger capacitance to
stabilize input voltage during PWM dimming operation.
nominal VOUT
.
A good rule of thumb is to set the input voltage ripple ΔVIN to be
1% of the minimum input voltage. The minimum input capacitor
requirements are as follows.
For this design example, a 100 V, 3 A Schottky diode SS3H10 is
selected. It has a very low iR = 50 µA at TJ = 125°C and VR = 30 V.
Step 10: Selection of output capacitors.
CIN = ∆iL / (8 × fSW × ΔVIN)
The use of multilayer ceramic capacitor (MLCC) is recom-
mended. MLCC has extremely low ESR, which is necessary to
reduce output switching ripple for boost converter. In addition,
the total output capacitance needs to be sufficient to reduce out-
put droop during PWM dimming operation.
Substitute ∆iL = 0.316 A at VIN = 6 V (from step 4d), ∆VIN
=
0.06 V, and fSW = 2.15 MHz to get CIN = 0.306 µF. Due to the
DC bias derating, the actual MLCC selected should be rated 1 µF
or higher.
37
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A80605 and
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High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
A much larger input capacitance is required to provide the inrush
current during PWM dimming operation. The exact requirement
depends on many external factors, such as length of power cables
and response time of the power supply. As a first-order estimate:
assuming the power supply takes 25 µs to response, and the input
capacitor must keep the VIN drip under 0.2 V while input current
ramps up from zero to full load. The following is needed:
CIN = iIN × tPS / (8 × ∆VIN)
Substitute iIN = 3.01 A at VIN = 6 V (from step 4d), ∆VIN = 0.2 V
and tPS = 25 µs to get CIN = 47 µF. Use an electrolytic capacitor
of 47 µF in parallel with the MLCC.
The following schematic diagrams shows calculated component
values from the design example:
ꢆꢑN ꢒ ꢊ ꢓ 1ꢋ ꢆ
ꢆꢏUꢔ ꢒ ꢕꢈ3 ꢆ
SS3H10
Sꢂꢃꢄ59ꢅP
ꢊ.ꢋ ꢌH
0.0ꢈ Ω
ꢇꢑNꢈ
Nꢆꢖ5ꢋꢊꢍNꢎ
ꢖꢈ
1N4148
ꢄꢍ ꢌꢁ
ꢅꢎꢇꢏ
ꢈ.ꢈ ꢌꢁ
Mꢎꢇꢇ
0.1 ꢌꢁ
0 Ω
ꢈ.ꢈ ꢌꢁ
3ꢄ0 Ω
15ꢄ ꢉΩ
ꢈ ꢐ ꢄ.ꢍ ꢌꢁ
50 ꢆ 1ꢈ10
0.0ꢄꢍ Ω
ꢗAꢔꢅ
ꢆꢖRꢆ ꢗꢖRꢆ ꢇS
PꢗNꢖ
ꢏꢆP
ꢆsense
ꢆꢇꢇ
ꢆin
1 ꢌꢁ
ꢆꢖꢖ
10 ꢉΩ
ꢎꢅꢖ1
ꢎꢅꢖꢈ
Aꢋ0ꢊ05
ꢁAUꢎꢔ
ꢅN
ꢊ ꢎꢅꢖ strings with
ꢍ ꢙꢎꢅꢖs in series
at 100 mAꢘch.
ꢎꢅꢖ3
ꢎꢅꢖꢊ
PꢙM
AꢖꢑMꢘAPꢙM
ꢇꢏMP
Pꢅꢛ
ꢇꢎꢚꢏUꢔ
AꢗNꢖ
ꢑSꢅꢔ
ꢁSꢅꢔ
ꢖꢑꢔH
100 ꢀꢁ
ꢈꢋ0 Ω
ꢄ0.ꢈ ꢉΩ
9.53 ꢉΩ
11.3 ꢉΩ
10 ꢉΩ
ꢊꢋ nꢁ
ꢈꢈ nꢁ
Figure 48: A80605 2.15 MHz Boost schematic for the design example
38
Allegro MicroSystems
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A80605 and
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High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
ꢂ1
Sꢂꢃꢄ59ꢅP
ꢍ
ꢆꢒN ꢓ ꢋ ꢔ 1ꢑ ꢆ
ꢆꢏUꢕ ꢓ ꢖꢈꢋ ꢆ
SS3H10
ꢈꢈ ꢊH
0.01ꢈ Ω
3ꢑ3 Ω
ꢎꢒNꢈ
0.1 ꢊꢁ
ꢈ.ꢄ9 Ω
ꢈ.ꢈ ꢊꢁ
ꢂꢈ
ꢜ
ꢄꢌ ꢊꢁ
ꢅꢍꢎꢏ
ꢄ.ꢌ ꢊꢁ
Mꢍꢎꢎ
ꢇꢈ
1N4148
RꢏꢆP
1ꢑꢈ ꢉΩ
ꢜ
RꢎS
ꢈꢈ ꢊꢁ
ꢅꢍꢎꢏ
ꢈ ꢐ ꢄ.ꢌ ꢊꢁ
50 ꢆ 1ꢈ10
0.039 Ω
ꢗAꢕꢅ
ꢆꢇRꢆ ꢗꢇRꢆ ꢎS
PꢗNꢇ
ꢏꢆP
ꢆsense
ꢆꢇꢇ
ꢆin
1 ꢊꢁ
ꢆꢇꢇ
10 ꢉΩ
ꢍꢅꢇ1
ꢍꢅꢇꢈ
Aꢑ0ꢋ05
ꢁAUꢍꢕ
ꢋ ꢍꢅꢇ strings with
ꢑ ꢙꢍꢅꢇs in series
at 100 mAꢘch.
ꢅN
ꢍꢅꢇ3
ꢍꢅꢇꢋ
PꢙM
AꢇꢒMꢘAPꢙM
ꢎꢏMP
Pꢅꢛ
ꢎꢍꢚꢏUꢕ
AꢗNꢇ
ꢒSꢅꢕ
ꢁSꢅꢕ
ꢇꢒꢕH
ꢆꢒN
Rꢝ
ꢎP
100 ꢀꢁ
5ꢋꢈ Ω
1ꢑꢌ ꢉΩ
5.9 ꢉΩ
ꢈꢈ0 ꢉΩ
ꢎꢝ
9.53 ꢉΩ
53.6 kΩ
ꢈꢈ nꢁ
0.ꢈꢈ ꢊꢁ
Figure 49: A80605 400 kHz Boost schematic for the design example
39
Allegro MicroSystems
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A80605 and
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High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
APPENDIX B: EXTERNAL MOSFET SELECTION GUIDE
The A80605 drives an external MOSFET for the boost stage. This
solution provides maximum flexibility in delivering a wide range
of output voltage and current for different LED panels, compared
to controllers with built-in boost switches. On the other hand,
care must be taken in selection of external MOSFET, to ensure
optimal tradeoff between component size, efficiency, and cost.
Primary Parameters to consider include the following.
ON-RESISTANCE
Device with lower RDSON can directly reduce the conduction loss
of the boost converter. This is especially important when the out-
put power is high and input supply voltage is low. Note that most
datasheets typically highlight this parameter at VGS = 10 V and
TJ = 25°C. It is important to examine how RDSON varies with gate
voltage and temperature, as shown in the following charts:
BREAKDOWN VOLTAGE
Pick the device with “Drain to Source Breakdown Voltage” at
least 20% higher than the maximum possible SW voltage.
• For boost configuration, VSW = VOUT + VF; where VF = boost
diode forward drop.
The A80605 has a maximum VOUT of 40 V. Therefore, the
MOSFET should be rated 50 V or higher.
• For SEPIC configuration, VSW = VIN + VOUT + VF.
Note that VIN can be as high as 40 V during load-dump
conditions. The breakdown voltage needs to be increased
accordingly.
GATE THRESHOLD VOLTAGE
The device must be fully enhanced by the time VGS = 5 V. Note
that this is not the same as “Gate to Source Threshold Voltage”
in most MOSFET datasheets, which is typically specified at very
small current such as 250 µA. A more reliable way is to consult
the “Gate Charge Characteristics” chart of the device, and make
sure that the ‘plateau’ occurs well before VGS reaches 5 V. See
example from datasheet of one potential candidate:
Figure 51: Chart showing On-Resistance varies with Darin
Current and Gate Voltage.
Figure 52: Nominalized On-Resistance vs. Junction Tem-
perature at VGS = 10 V. Note that resistance increases by
100% when temperature rises from 25°C to 150°C.
Figure 50: Gate Charge vs. Gate-Source Voltage for an ex-
ample MOSFET. Note plateau at VGS = 4.2 V approximately.
40
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A80605 and
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High Power LED Driver with Pre-Emptive Boost
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On the other hand, selecting a device with very low QG may
cause excessive voltage spikes at SW node due to high dV/dt. In
this case, a snubber circuit can be added to dampen the ringing.
The switching speed can be slowed down by adding a series gate
resistance (such as 1-5 ohm) between the driver and the device.
The downside of doing this is higher switching losses.
THERMAL RATING
The thermal resistance (RθJA) is primarily determined by the
device’s physical size. If the thermal resistance of the device is
too high, or if there is insufficient heat dissipation on the PCB,
the device may enter thermal run-away situation and burn itself
out. For most medium-power (10-30 W) applications, a DPAK
device is generally sufficient. For high-power (>50 W) applica-
tions, a D2PAK device may be required. Depending on power
loss, additional heat sink can be mounted to improve the heat
dissipation from the PCB.
GATE CHARGE
As mentioned earlier, lower RDSON is desired to reduce conduc-
tion loss. But devices with lower RDSON typically also have
higher gate charge (QG), which can lead to higher switching loss.
This is especially important when switching at high frequency
(such as 2 MHz) and with high output voltage. Higher gate
charge also results in higher gate driver current and hence higher
power loss for the controller IC.
The A80605 uses an LDO to supply the driver voltage (VDRV),
which has a current limit of 36 mA typical. Average gate driver
current is:
Figure 54: Gate Charge vs. Gate-Source Voltage chart for
a suitable MOSFET (NVD5867NL). Note that its plateau is
at ~3.5 V, and its total gate charge is about 10 nC as VGS
ramps up from 0 to 6.5 V.
iVDRV = fSW × QG
If the MOSFET selected has QG = 27 nC, for example, then the
highest switching frequency is limited to 1.33 MHz. See the fol-
lowing chart for relation between maximum switching frequency
and MOSFET gate charge:
ꢂꢆꢍ. ꢎꢁꢏtꢐꢉꢏꢌꢋ ꢑꢊꢇꢒꢓꢇꢌꢐꢔ ꢕs. ꢅꢆtꢇ ꢈꢉꢆꢊꢋꢇ
3.0
2.5
2.0
1.5
1.0
0.5
0.0
10
15
20
25
30
35
40
ꢅꢆtꢇ ꢈꢉꢆꢊꢋꢇ (ꢌꢈ)
Figure 53: Maximum Switching Frequency vs. Gate Charge
(to keep average VDRV current under 36 mA).
41
Allegro MicroSystems
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A80605 and
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High Power LED Driver with Pre-Emptive Boost
for Ultra-High Dimming Ratio and Low Output Ripple
Revision History
Number
Date
Description
–
1
2
January 23, 2020
Initial release
Updated Functional Block Diagram (page 4), Soft-Start Ramp-Up Time values (page 8), Soft Start
Function section (page 14), ADIM Mode section (page 21), Figure 48 (page 38), and Figure 49
(page 39)
May 28, 2020
June 15, 2020
Updated Soft-Start Ramp-Up Time minimum and maximum values (page 8)
Copyright 2020, Allegro MicroSystems.
Allegro MicroSystems 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 assumes no responsibility for its use; nor
for any infringement of patents or other rights of third parties which may result from its use.
Copies of this document are considered uncontrolled documents.
For the latest version of this document, visit our website:
www.allegromicro.com
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