Maxim MAX31840 Mr16 led driver with integrated control mosfet and deep dimming Datasheet

EVALUATION KIT AVAILABLE
MAX31840
MR16 LED Driver with Integrated Control
MOSFET and Deep Dimming
General Description
The MAX31840 is an LED driver IC for dimmable 12V
MR16, as well as AR111 and other 12V lighting applications.
This next-generation MR16 LED driver minimizes BOM
count, cost, and board space by integrating a number of
value-added functions: deep dimming, bleeder control,
constant brightness control, and a boost FET; while
significantly improving electronic transformer compatibility
with standard trailing-edge dimmers. The MAX31840 is
designed for the boost architecture to address 35W and
higher-wattage MR16 LED replacement bulbs.
The MAX31840 is a high-end MR16 LED driver that
incorporates a proprietary circuit that enables deep
dimming down to ~1%; an improvement over others that
only dim down to 10% or 20%. An integrated bleeder and
constant brightness controller enables the MAX31840
to shine, flicker-free, with a broad range of electronic
transformers. An optimized compensation circuit and
boost FET are integrated to further reduce BOM and
board space, simplifying design and saving cost.
The MAX31840 is available in an 8-pin, 3mm x 3mm
TDFN enhanced power package and is rated over the
-40°C to +125°C operating temperature range.
Applications
●● 12V MR16 GU5.3 LED Bulb
●● Other 12V LED bulbs (MR11, AR111, 12V Track Lighting)
19-100100; Rev 0; 6/17
Benefits and Features
●● High Integration Saves PCB Space and BOM Costs
• 36V Boost N-Channel DMOS FET
• Bleeder FET Control
• Deep Dimming Control
• Constant Brightness Control
• Internal Compensation
• LED Overvoltage Protection
• Overcurrent and Overtemperature Protection
●● High-Performance for New LED Dimming
Requirements
• Meets California Title 24 Part 6 JA8
• Flickering < 30%
• > 0.9 Power Factor
• Dimming to <1% Brightness, Depending on LEDs
• Tight LED Current Regulation of 2% Typical
Ordering Information appears at end of data sheet.
MAX31840
MR16 LED Driver with Integrated Control
MOSFET and Deep Dimming
Simplified Block Diagram
INPUT
12V/0.5A
D1
L1
100uH/1.2A
LED7
IN
LED6
5.6V
R6
UV
26V
OV
5V
BIAS
LED5
R4
2ohm
1W
560ohm
ACREC
C1
0.22uF
25V
DRAIN
DEEP
DIMMING
PWM
DCDC
NFET
AVDET
C5
1uF
6.3V
C3
22uF
35V
LED4
SOURC
E
LED3
MAX
BRIGHTNESS
CSA
LED2
CS
BGT
M1
NDS351AN
BLEED
0.5V
MAX31840
BSRC
R2
LED1
0.2V
R1
0.2ohm
GND (EP)
0.5ohm
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Maxim Integrated │ 2
MAX31840
MR16 LED Driver with Integrated Control
MOSFET and Deep Dimming
Absolute Maximum Ratings
IN, DRAIN to GND.................................................-0.3V to +36V
ACREC to GND......................................................-0.3V to +26V
AVDET, BGT, BSRC to GND....................................-0.3V to +6V
CS, SOURCE to GND.............................................-0.3V to 1.5V
Maximum RMS Current Through DRAIN and SOURCE.......±1A
Continuous Power Dissipation (TA = +70°C) TDFN
(derate 23.8mW/°C above +70°C).............................1904mW
Any Pin to Any Pin ESD Rating................................ ±2kV(HBM)
Operating Temperature Range.......................... -40°C to +125°C
Maximum Junction Temperature......................................+150°C
Storage Temperature Range............................. -65°C to +150°C
Lead Temperature (soldering, 10s).................................. +300°C
Soldering Temperature (reflow)........................................+260°C
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these
or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect
device reliability.
Package Information
8 TDFN-EP
PACKAGE CODE
T833+3
Outline Number
21-0137
Land Pattern Number
90-0059
Thermal Resistance, Single-Layer Board:
Junction to Ambient (θJA)
54
Junction to Case (θJC)
8
Thermal Resistance, Four-Layer Board:
Junction to Ambient (θJA)
42
Junction to Case (θJC)
8
For the latest package outline information and land patterns (footprints), go to www.maximintegrated.com/packages. Note that a “+”,
“#”, or “-” in the package code indicates RoHS status only. Package drawings may show a different suffix character, but the drawing
pertains to the package regardless of RoHS status.
Package thermal resistances were obtained using the method described in JEDEC specification JESD51-7, using a four-layer board.
For detailed information on package thermal considerations, refer to www.maximintegrated.com/thermal-tutorial.
Electrical Characteristics
(VIN = VACDEC = 12V; VACREC = VSOURCE = VCS = VGND = 0V; 1kΩ from DRAIN to IN, 100kΩ from BSRC to BGT; TA = TJ = -40°C
to +125°C, unless otherwise noted. Typical values are at TA = +25°C.) (Note 1 )
PARAMETER
Operating Voltage Range
SYMBOL
VIN
CONDITIONS
Guaranteed by Undervoltage Lockout and
IN Overvoltage Protection
MIN
6.5
When MOSFET fully on, VCS = 0.
IN Supply Current
Undervoltage Lockout
IIN
UVLOIN
When MOSFET switching at 60% duty,
refers to Typical Application Circuit, when
VLED/VACREC = 30V/12V, measure IN
current
IN rising, when DRAIN goes low
5
UVLO Hysteresis
IN Overvoltage Protection
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MAX
UNITS
26
V
1
2.3
1.5
3.2
5.6
6.1
200
VOVP
IN rising, when DRAIN goes high
34.8
IN Overvoltage Hysteresis
Switching Frequency
TYP
35.9
630
700
V
mV
37
1.15
Switching frequency at DRAIN
mA
V
V
770
kHz
Maxim Integrated │ 3
MAX31840
MR16 LED Driver with Integrated Control
MOSFET and Deep Dimming
Electrical Characteristics (continued)
(VIN = VACDEC = 12V; VACREC = VSOURCE = VCS = VGND = 0V; 1kΩ from DRAIN to IN, 100kΩ from BSRC to BGT; TA = TJ = -40°C
to +125°C, unless otherwise noted. Typical values are at TA = +25°C.) (Note 1 )
PARAMETER
SYMBOL
CS Average Voltage
Power Switch On-Resistance
Switch Leakage Current
RDSON
ILEAK
MIN
TYP
MAX
TA = +25°C
CONDITIONS
196
200
204
​-40°C ≤ TA ≤ +125°C
190
210
UNITS
mV
IDS = 1A
100
200
mΩ
VDRAIN = 36V, TA = 25°C
0.01
20
μA
DRAIN Rise Time
tRDRAIN
IDS = 1A
10
ns
DRAIN Fall Time
tFDRAIN
IDS = 1A
10
ns
SOURCE Limit Threshold
VSOURCETH
SOURCE connected to CS
0.66
SOURCE Current-Limit
Comparator Propagation
Delay
CS Input Bias Current
ICS
VCS = 0V and VCS = 0.3V, TA = 25°C
-1
Temperature rising
Thermal Shutdown
Hysteresis
ACREC Input Threshold
VACREC
ACREC Constant
Brightness Center Point
VTHAVREC
ACREC Constant
Brightness Range
Bleeder Startup Pulse
CS Bleeder Enable
Threshold
Deep Dim Delay
BGT Output Voltage
0.78
25
Thermal-Shutdown
Temperature
BSRC Voltage
0.72
tOS
VTHBLEEDER
tDIM
ns
+1
μA
165
°C
15
°C
ACREC rising
3.5
3.8
4.2
V
VACREC when VCS = 0.2V (constant
brightness center point)
11.4
12
12.6
V
12
±15%
Where LED brightness is held constant
VBSRC
V
Bleeder in regulation
0.475
From ACREC rising to BGT falling
CS Rising. When CS falling VBSRC goes
low, 100mV (typ) hysteresis
From ACREC high to
boost off
0.525
75
186
tACREC = 2ms
tACREC = 4ms
0.5
V
200
V
μs
214
mV
3.9
ms
0.9
3.3
tACREC = 6ms
3.6
6.3
BSRC < 0.5V, output high
1
5.2
BSRC > 0.5V, output low
0
0.5
V
Note 1: All devices are 100% tested at TA = TJ = +25°C. Limits over temperature are guaranteed by design.
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Maxim Integrated │ 4
MAX31840
MR16 LED Driver with Integrated Control
MOSFET and Deep Dimming
Typical Operating Characteristics
(TA = +25°C, unless otherwise noted.)
IQ vs. VIN
IQ vs. TEMPERATURE
toc01
1.5
1.18
VIN = 32V
1.4
Temp = 25°C
1.16
1.3
1.14
IQ (mA)
IQ (mA)
toc02
1.2
1.2
1.12
1.1
1.1
1.08
1
1.06
1.04
0.9
1.02
1
0.8
-50
0
50
100
10
150
15
20
25
30
35
VIN (V)
TEMPERATURE (°C)
UVOL vs. TEMPERTURE
FREQUENCY vs. TEMPERATURE
toc03
705
toc04
5.7
701
5.65
699
697
UVLO (V)
OSCILLATION FREQUENCY (kHz)
703
695
5.6
693
691
5.55
689
687
5.5
685
-50
0
50
-50
100
0
TEMPERATURE (°C)
VCS vs. VACREC
90
OUTPUT
CONNECTS TO
A STRING OF
10 HBLED
360
80
200
190
180
340
70
ILED (mA)
DIMMING PHASE (%)
220
VCS (mV)
toc07
380
toc06
100
230
210
60
50
30
280
260
10
160
7
9
11
AVERAGE VACREC (V)
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13
15
320
300
40
20
170
100
LED CURRENT vs. AVERAGE VACREC
DIMMING PHASE vs. INPUT PHASE
toc05
240
50
TEMPERATURE (°C)
240
0
0
20
40
60
INPUT PHASE (%)
80
100
7
9
11
13
AVERAGE VACREC (V)
Maxim Integrated │ 5
MAX31840
MR16 LED Driver with Integrated Control
MOSFET and Deep Dimming
Pin Configuration
DRAIN
1
+
ACREC 2
IN
3
AVDET
4
8
SOURCE
7
CS
6
BGT
5
BSRC
MAX31840
EP/GND
TDFN
Pin Description
PIN
NAME
1
DRAIN
Drain of the Internal Switching MOSFET
FUNCTION
2
ACREC
Rectified AC Voltage Sensing. Connect this pin to positive side of the rectified AC waveform. Also,
connect a bypass capacitor to ground. The zero crossing and dimmer phase information are
detected and used to drive an external bleeding FET.
3
IN
Input. Connect to LED string anode to get OVP protection during open LED. Also, input to internal
supplies. Bypass it with a 150µF capacitor. Also need a bootstrap diode from rectified input to
jump-start internal digital circuit.
4
AVDET
Average AC Voltage Detection. Connect a bypass capacitor to ground for the constant power
circuit. This pin is connected to an internal voltage controlled current source.
5
BSRC
Bleeder FET Source Connection. Connect to the source of an NMOS FET for precise bleeding
current level control.
6
BGT
7
CS
8
SOURCE
-
GND
Bleeder FET Gate Connection. Connect to the gate of an NMOS FET to supplement input current to
maintain electronic transformer operation.
Current Sense. This pin includes a 5kΩ/4pF RC filter at its input to average the current information
over the switching cycle. Connect this pin directly to SOURCE.
Source of the Internal Switching MOSFET
Ground via the exposed pad.
Functional Diagram
Internal Functional Block
Refer to the Simplified Block Diagram.
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Maxim Integrated │ 6
MAX31840
Detailed Description
The MAX31840 is an average current-mode-control LED
driver IC for boost topology in low-voltage SSL applications.
The IC has an integrated 0.2Ω (max), 36V switching
MOSFET that allows the device to be used in lighting
applications for MR16 and other SSL applications. The
LED driver uses constant-frequency, average currentmode control to control the duty cycle of the integrated
switching MOSFET. The IC has all the necessary features
required for LED MR16 lighting applications. The IC uses
an input-current-control scheme to achieve power factor
correction. The IC turns on an external bleeder when the
boost operation is off. This feature allows the IC to be
compatible with electronic transformers and trailing-edge
dimmers (for electronic transformers).
The switch current is sensed on CS. The voltage on CS
goes through an internal RC filter. This voltage is then
fed to the negative input of a transconductance amplifier.
The positive input of the gm amplifier is the programmed
input current level. The output voltage of the amplifier is
compared with a ramp at the switching frequency to set the
duty cycle. The switching frequency is set at 700kHz. The
average current-mode controller inside the IC regulates
the input current. The IC also features an internal
overvoltage protection of 36V on IN to protect the internal
switching MOSFET from damage if the LED string is open
or if the voltage is too high.
The IC regulates the average voltage on CS to 200mV.
The average input current is determined by the value of
the resistor connected from the CS pin to ground.
To keep the input power almost constant for line-voltage
variation of ±13%, a constant brightness circuit has been
integrated into the MAX31840. The rectified AC supply after
a RC filter, consists of an internal resistor in conjunction
with the capacitor connected from the AVDET pin to
ground, is used to sense the average voltage level.
The IC has a bleeder gate (BGT) ping and a bleeder
source (BSRC) pin for the control of an external bleeder
N-channel MOSFET. A bleeder is required to draw current
after each AC zero-crossing cycle when the boost converter
just get started. The same bleeder is also used to provide
deep dimming. The bleeder driving circuit inside the IC
maintains the BSRC pin at 0.5V. The bleeder current is
determined by the value of the resistor connected from
the BSRC pin to the ground.
Internal Oscillator
The IC has an internal oscillator with a fixed switching
frequency of 700kHz. 700kHz was chosen to balance
between inductor size and EMI emission.
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MR16 LED Driver with Integrated Control
MOSFET and Deep Dimming
Input Voltage (IN)
The IC is powered by the voltage on IN and needs to be
maintained within the operating voltage range of from 6.5V
to 35V. An internal UVLO is set at 5.6V. Below 5.4V, there
is no switching of the internal power MOSFET and the
gate driver for the MOSFET is low. The typical hysteresis
of the UVLO threshold is 200mV. There is an internal LDO
of 5V that is used to power all the internal circuitry and
the gate driver for the internal switching MOSFET. The
switching of the internal MOSFET ceases once the rising
voltage on IN exceeds 35V and stays off until the voltage
on IN drops by 1.2V.
Rectified AC (ACREC)
The ACREC pin senses the zero crossings for the external
bleeder driver. The ACREC pin is also used to detect the
dimmer phase to drive the same shared external bleeder
FET. The zero crossing bleeding happens at every AC
zero crossing and lasts a very short time duration. For
deep dimming, an internal circuit detects the time duration
of the dimming phase per a half AC period. It then turns
off the the boost controller at a shorter duration according
to the dimming phase for the next half AC period. The
smaller the dimming phase the shorter the duration. At
around 15° of dimming phase, the deepest dimming is
reached per R4 and C1 values on the ACREC pin. For
both zero crossing and deep dimming, the bleeder FET
is turned on when the LED boost is off, to maintain a
minimum input loading on the electronic transformer. The
deep dimming control is capable of delivering <1% of
maximum power to the LEDs.
External Bleeder Driver (BGT/BSRC)
The BGT and BSRC pins drive an external N-channel
MOSFET for both zero crossing and deep dimming bleeding.
A resistor at the BSRC pin to ground is used to configure
the electronic transformer loading current during either
zero cross and deep dimming. With 0.5V of source voltage,
and a 0.5Ω resistor from source to GND, the bleeder
would draw 1A from the input when the ACREC voltage is
high and the boost regulator is off.
Internal Switching MOSFET
The IC has an integrated switching MOSFET with a maximum
RDSON of 200mΩ at +125°C. The typical RDSON at
+25°C is 100mΩ. This allows the IC to be used in a boost
LED driver for power levels up to 12W. The maximum
voltage rating of the MOSFET is 36V operation. The drain
of the internal MOSFET is connected to the DRAIN pin
and the source of the internal MOSFET is connected to
the SOURCE pin.
Maxim Integrated │ 7
MAX31840
MR16 LED Driver with Integrated Control
MOSFET and Deep Dimming
Current Sense (CS)
RC filter, the transconductance error amplifier (gm), the
internal compensation circuits, an oscillator providing the
700kHz ramp, the control voltage on the positive input of
the gm amplifier, and the PWM comparator (PWMC).
The source of the internal MOSFET is connected to
SOURCE. A current-sense resistor must be connected
between SOURCE and ground to set the regulated average
input current. The current information is read by CS, so
SOURCE must be connected to CS. The set point of the
current is determined by the IC's control loop and is nominally
200mV. With a 200mΩ RCS resistor, the average input
current will be set to 1A. There is a separate peak-limit
comparator that terminates switching every cycle if the
voltage on CS exceeds 720mV. This comparator has a
leading-edge blanking time of 50ns. This limits the peak
current in the switching MOSFET and the inductor during
transients to 3.6A when the average current is set to 1A.
Peak-Limit Comparator
The IC has a peak-limit comparator that limits the peak
current in the switching MOSFET. If the current-sense
voltage on CS exceeds 0.72V, the peak-limit comparator
terminates switching for that switching cycle. This limits the
peak current in the switching MOSFET and the inductor
during transients.
PWM Comparator
The PWM comparator (PWMC) determines the on-time of the
switching MOSFET on a cycle-by-cycle basis by comparing
the output of the gm amplifier to a 2VP-P ramp signal.
At the start of each clock cycle, an RS flip-flop resets
and the gate driver turns on the switching MOSFET. The
comparator sets the flip-flop as soon as the ramp signal
exceeds the COMP voltage, thus terminating the on cycle.
Control Loop
The IC uses an average current-mode control scheme to
regulate the input current. The control loop regulates the
average voltage on CS. An internal RC filter removes current
spikes appearing on this pin. The current-regulation loop
consists of the current-sense resistor RCS, the internal
INPUT
D1
L1
LED+
CONTROL
VOLTAGE
DRAIN
gm
PWMC
INTERNAL
COMPENSATION
DRIVER
NFET
SOURC
E
2VP_P
CS
10pF
LED-
5kΩ
RCS
Figure 1. Control Loop
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Maxim Integrated │ 8
MAX31840
Deep Dimming
Controlled by the same dimmer, a Halogen bulb appears to
be more dim-able compared with a LED replacement. The
brightness of a Halogen bulb is proportional to the cube
of the average voltage across its inputs. Figure 2 shows
the supply waveform of a typical electronic transformer
with an oscillation frequency of 20kHz for a duration of
a half 60Hz AC cycle. The red and blue curves show
minimum and maximum dimmer phases of 12% to 70%,
respectively. By calculating the area under these curves, we
can find that the corresponding average voltage variation
is 13:100. For this voltage variation ratio, the brightness
variation for a Halogen bulb is about 0.2:100. For the LED
MR16 LED Driver with Integrated Control
MOSFET and Deep Dimming
replacement, the brightness variation is only 13:100 since
its brightness is linearly proportional to the average voltage
across it.
The deep dimming circuit inside the MAX31840 starts
to cut down the LED on duration at dimming phase of
about 60%. It eventually cuts down the LED-On duration
to a minimum at an input phase of about 15%. Since
the brightness is determined by the input duty and the
sinusoidal input voltage, the deep dimming profile is more
gradual at both low and high duties, as seen in Figure 3.
The MAX31840 controls the boost regulator and bleeder
to maintain continuous input current, while lowering the
power delivered to the LED’s, in order to achieve this
dimming profile.
Figure 2. Typical Trailing-Edge Dimming Phase Variation
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Maxim Integrated │ 9
MAX31840
MR16 LED Driver with Integrated Control
MOSFET and Deep Dimming
Figure 3. Deep Dimming Effect vs. Dimming Phase of A Dimmer
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Maxim Integrated │ 10
MAX31840
MR16 LED Driver with Integrated Control
MOSFET and Deep Dimming
Applications Information
Boost Configuration
For MR16 and other 12V AC input applications, this
MAX31840 boost controller is used for the LED strings
with forward voltage exceeds 18V. The number of LEDs
can range from 6 to 10 LEDs depending on the forward
voltage. The maximum voltage across the LED string
should not exceed 34V. In this boost configuration, the
current in the inductor is the same as the current in the
current-sense resistor R1.
Resistor (R1)
The current in resistor R1 is the same as the current in
inductor L1. If the desired maximum output power with
12V AC at 50Hz or 60Hz is POUT, the input power PIN
is given:
PIN = POUT/n
where n is the efficiency. The input current is given by:
IIN = PIN/12V
Resistor R1 is then given by:
R1 = 0.2V/IIN
where R1 is in ohms and IIN is in amps.
Boost Inductor (L1)
For optimum efficiency, the boost inductor must be
operating in continuous-conduction mode. The maximum
peak current in the inductor occurs at the peak of the
highest input voltage. The peak to peak ripple at this input
voltage is ΔIL. The highest input voltage is 13.2V AC,
which is 10% higher than the typical value.
The peak current in the inductor is:
The percentage peak to peak ripple is typically selected
in the 30% to 60% range of the maximum input current.
Assuming a 60% peak to peak inductor-current ripple, the
maximum inductor current is given by:
IPK = 1.3IINMAX
The minimum inductor value is given by:
18.66V × DMIN
LMIN = 0.6I
INMAX × 700kHz
where the switching frequency is 700kHz. The saturation
current of the inductor should be higher than peak to peak
and the minimum value of the inductor at IP-P should
exceed LMIN.
The temperature of the inductor can be in the +90°C to
+100ºC range in the application and the losses should be
estimated at these elevated temperatures.
Boost Diode (D1)
A Schottky diode must be used as rectifier diode D1 to
reduce power dissipation. The voltage rating of diode
D1 must be greater than the maximum output voltage.
Choose a diode that minimizes dissipation at temperatures
in the +90°C to +100°C range. The diode should be
selected to minimize reverse leakage at the maximum
output voltage while minimizing forward losses when the
diode is conducting.
Resistor (R2)
The current in resistor R2 is the same as the bleeding
current for both zero cross and deep dimming. The source
voltage is regulated at 0.5V. The current through R2 is
given:
IR2 = 0.5/R2
IPK = IIN + 0.5ΔIL
The output voltage of the LED string is given by VLED. As
a first-order approximation, the LED voltage is assumed
constant. The duty cycle at the peak of the input voltage
is therefore:
Or the resistor value is dependent on the desired bleeding
current by:
R2 = 0.5/IR2
DMIN = 1 − V √ = 1 − V
LED
LED
13.2 × 2
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18.66V
Maxim Integrated │ 11
MAX31840
MR16 LED Driver with Integrated Control
MOSFET and Deep Dimming
Typical Application Circuit
Boost for 50W MR16 Bulb Application
D3
12V AC FROM AN
ELECTRONIC TRANSFORMER
T4
D2
C2
4700pF
25V
D1
L1
R6
R4
2Ω
1W
560Ω
100µH/1.2A
VLP8040T
T1
R3
100Ω
LED8
LED7
ACREC
IN
LED6
C4
C1
0.22µF
25V
MB16S
DRAIN
AVDET
0.1µF
50V
C3
C5
150µF
35V
MAX31840
1µF
LED5
LED4
M1
T2
IRLML2502
SOURCE
BGT
LED3
BSRC
R2
0.5Ω
CS
LED2
GND (EP)
LED1
T3
R1
0.2Ω
Ordering Information
PART NUMBER
MAX31840ATA+
TEMP RANGE
PIN-PACKAGE
-40°C to +125°C
8 TDFN-EP*
+Denotes a lead(Pb)-free/RoHS-compliant package.
*EP = Exposed pad.
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Maxim Integrated │ 12
MAX31840
MR16 LED Driver with Integrated Control
MOSFET and Deep Dimming
Revision History
REVISION
NUMBER
REVISION
DATE
0
6/17
DESCRIPTION
Initial release
PAGES
CHANGED
—
For pricing, delivery, and ordering information, please contact Maxim Direct at 1-888-629-4642, or visit Maxim Integrated’s website at www.maximintegrated.com.
Maxim Integrated cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim Integrated product. No circuit patent licenses
are implied. Maxim Integrated reserves the right to change the circuitry and specifications without notice at any time. The parametric values (min and max limits)
shown in the Electrical Characteristics table are guaranteed. Other parametric values quoted in this data sheet are provided for guidance.
Maxim Integrated and the Maxim Integrated logo are trademarks of Maxim Integrated Products, Inc.
© 2017 Maxim Integrated Products, Inc. │ 13
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