MICREL MIC2846A

MIC2846A
High Efficiency 6 Channel Linear WLED
Driver with DAM™, Digital Control and Dual
Low IQ LDOs
General Description
Features
The MIC2846A is a high efficiency White LED (WLED)
driver featuring two low quiescent current LDOs. It is
designed to drive up to six LEDs and greatly extend
battery life for portable display backlighting and keypad
backlighting in mobile devices. The MIC2846A architecture
provides the highest possible efficiency by eliminating
switching losses present in traditional charge pumps or
inductive boost circuits. With a typical dropout of 40mV at
20mA, the MIC2846A allows the LEDs to be driven directly
from the battery eliminating switching noise and losses
present with the use of boost circuitry.
The MIC2846A features Dynamic Averaged Matching™
(DAM™) which is specifically designed to get the optimum
matching despite process variations. This ensures a
typical matching of ±1.5% between all six LED channels.
The LED brightness is preset by an external resistor and
can be dimmed using a single-wire digital control. The
digital interface takes commands from digital programming
pulses to change the brightness in a logarithmic scale
similar to the eye’s perception of brightness. The singlewire digital brightness control is divided into two modes of
operation; full brightness mode or battery saving mode for
a total of 49 brightness steps.
The MIC2846A also features two independently enabled
low quiescent current LDOs. Each LDO offers ±3%
accuracy over temperature, low dropout voltage (150mV
@ 150mA), and low ground current under all load
conditions (typically 35µA). Both LDOs can be turned off to
draw virtually no current.
The MIC2846A is available in the 2.5mm x 2.5mm 14-pin
Thin MLF® leadless package with a junction temperature
range of -40°C to +125°C
Datasheet and support documentation can be found on
Micrel’s web site at: www.micrel.com.
WLED Driver
• High Efficiency (no Voltage Boost losses)
• Dynamic Average Matching™ (DAM™)
• Single wire digital control
• Input voltage range: 3.0V to 5.5V
• Dropout of 40mV at 20mA
• Matching better than ±1.5% (typical)
• Current accuracy better than ±1.5% (typical)
• Maintains proper regulation regardless of how many
channels are utilized
LDOs
• Very low ground current – Typical 35µA
• Stable with 1µF ceramic output capacitor
• Dropout at 150mV at 150mA
• Thermal shutdown and current limit protection
• Available in a 2.5mm x 2.5mm 14-pin Thin MLF®
package
Applications
• Mobile handsets
• LCD Handset backlighting
• Handset keypad backlighting
• Digital cameras
• Portable media/MP3 players
• Portable navigation devices (GPS)
• Portable applications
DAM, Dynamic Average Matching is a trademark of Micrel, Inc.
MLF and MicroLeadFrame are registered trademark Amkor Technology Inc.
Micrel Inc. • 2180 Fortune Drive • San Jose, CA 95131 • USA • tel +1 (408) 944-0800 • fax + 1 (408) 474-1000 • http://www.micrel.com
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M9999-041210-D
Micrel Inc.
MIC2846A
Typical Application
Digital
LCD Display Backlight with 6 WLEDs and Camera Module
6
Digital
High Current Flash Driver
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MIC2846A
Ordering Information(1,2,3)
Part Number
Mark
Code
LDO1
VOUT
LDO2
VOUT
Temperature Range
Package
MIC2846A-MFYMT
YPMF
2.8V
1.5V
–40°C to +125°C
14-Pin 2.5mm x 2.5mm TMLF®
MIC2846A-MGYMT
YPMG
2.8V
1.8V
–40°C to +125°C
14-Pin 2.5mm x 2.5mm TMLF®
MIC2846A-PGYMT
YPPG
3.0V
1.8V
–40°C to +125°C
14-Pin 2.5mm x 2.5mm TMLF®
MIC2846A-PPYMT
YPPP
3.0V
3.0V
–40°C to +125°C
14-Pin 2.5mm x 2.5mm TMLF®
MIC2846A-SCYMT
YPSC
3.3V
1.0V
–40°C to +125°C
14-Pin 2.5mm x 2.5mm TMLF®
Note:
®
1. Thin MLF ▲ = Pin 1 identifier.
®
2. Thin MLF is a GREEN RoHS-compliant package. Lead finish is NiPdAu. Mold compound is halogen free.
3. Contact Micrel for other output voltages.
Pin Configuration
14-Pin 2.5mm x 2.5mm Thin MLF® (MT) (Top View)
Pin Description
Pin Number
Pin Name
1
VIN
2
LDO2
3
EN2
Enable Input for LDO2. Active High Input. Logic High = On; Logic Low = Off; Do not leave floating.
4
DC
Enable input for LED driver. Can be used for dimming using the digital control interface. See Digital
Dimming Interface for details. Do not leave floating.
5
RSET
6
D1
LED1 driver. Connect LED anode to VIN and cathode to this pin.
7
D2
LED2 driver. Connect LED anode to VIN and cathode to this pin.
8
D3
LED3 driver. Connect LED anode to VIN and cathode to this pin.
9
GND
10
D4
LED4 driver. Connect LED anode to VIN and cathode to this pin.
11
D5
LED5 driver. Connect LED anode to VIN and cathode to this pin.
12
D6
LED6 driver. Connect LED anode to VIN and cathode to this pin.
13
EN1
14
LDO1
EPAD
HS PAD
April 2010
Pin Function
Voltage Input. Connect at least 1µF ceramic capacitor between VIN and GND.
Output of LDO2. Connect at least 1µF ceramic output capacitor.
An internal 1.27V reference sets the nominal maximum LED current. Example, apply a 20.5kΩ
resistor between RSET and GND to set LED current to 20mA at 100% duty cycle.
Ground.
Enable Input for LDO1. Active High Input. Logic High = On; Logic Low = Off; Do not leave floating.
Output of LDO1. Connect at least 1µF ceramic output capacitor.
Heat sink pad. Not internally connected. Connect to ground.
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MIC2846A
Absolute Maximum Ratings(1)
Operating Ratings(2)
Main Input Voltage (VIN) ................................... -0.3V to +6V
Enable Input Voltage (VDC, VEN1, VEN2) ............ -0.3V to +6V
LED Driver Voltage (VD1-D6).............................. -0.3V to +6V
Power Dissipation ................................. Internally Limited(3)
Lead Temperature (soldering, 10sec.)....................... 260°C
Storage Temperature (Ts) ..........................-65°C to +150°C
ESD Rating(4) ................................................. ESD Sensitive
Supply Voltage (VIN).................................. +3.0V to +5.5V
Enable Input Voltage (VDC, VEN1, VEN2) .............. 0V to VIN
LED Driver Voltage (VD1-6) ................................. 0V to VIN
Junction Temperature (TJ) .....................–40°C to +125°C
Junction Thermal Resistance
2.5mm x 2.5mm Thin MLF-14L (θJA) ..............89°C/W
Electrical Characteristics
Linear WLED Drivers
VIN = VDC = 3.8V, VEN1 = VEN2 = 0V, RSET = 20.5kΩ; VD1-D6 = 0.6V; TJ = 25°C, bold values indicate –40°C ≤ TJ ≤ 125°C;
unless noted.
Parameter
Conditions
Min
Typ
Max
Units
Current Accuracy(5)
1.5
%
(6)
1.5
%
Matching
Drop-out
Where ILED = 90% of LED current seen at
VDROPNOM = 0.6V, 100% brightness level
40
80
mV
Ground/Supply Bias Current
ILED = 20mA
1.4
1.8
mA
Shutdown Current
(current source leakage)
VDC = 0V for more than 1260µs
0.01
1
µA
0.2
V
Digital Dimming
VDC Input Voltage (VDC)
Logic Low
1.2
Logic High
V
VDC Enable Input Current
VDC = 1.2V
0.01
tSHUTDOWN
Time DC pin is low to shutdown the device
1260
tMODE_UP
Time DC pin is low to change to Count Up Mode
100
160
µs
tMODE_DOWN
Time DC pin is low to change to Count Down Mode
420
500
µs
32
µs
tPROG_HIGH, tPROG_LOW
Time for valid edge count; Ignored if outside limit range
2
tDELAY
Time DC pin must remain high before a mode change
can occur
100
tPROG_SETUP
First down edge must occur in this window during
presetting brightness
tSTART_UP
Delay time starting when DC is first pulled high until
LEDs start up
1
µA
µs
µs
5
75
140
µs
µs
LDOs
VIN = VEN1 = VEN2 = 3.8V, VDC = 0V; COUT1 = COUT2 = 1μF, IOUT1 = IOUT1 = 100μA; TJ = 25°C, bold values indicate –40°C ≤
TJ ≤125°C; unless noted.
Parameter
Conditions
Min
Output Voltage Accuracy
Variation from nominal VOUT
VIN Line Regulation
Load Regulation
(7)
Dropout Voltage
April 2010
-2
-3
0.02
IOUT = 100μA to 150mA
VOUT >= 3.0V; IOUT = 150mA
Ground Pin Current
Ground Pin Current in Shutdown
Typ
VEN = 0V
4
Max
Units
+2
+3
%
%
0.3
%/V
7
mV
150
330
mV
35
70
µA
0.05
1.0
µA
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MIC2846A
LDOs (continued)
Parameter
Conditions
Min
Ripple Rejection
f = 1kHz; COUT = 2.2μF
Current Limit
VOUT = 0V
Output Voltage Noise
Frequency 10Hz to 100kHz
Typ
Max
65
175
300
Units
dB
500
200
mA
µVRMS
Enable Inputs (EN1,2)
Enable Input Voltage
0.2
Logic Low
1.2
Logic High
Enable Input Current
VEN1 = VEN1 = 1.2V
Turn-on Time
COUT = 1µF; 90% of VOUT
V
V
0.01
1
µA
50
100
µs
Notes:
1. Exceeding the absolute maximum rating may damage the device.
2. The device is not guaranteed to function outside its operating rating.
3. The maximum allowable power dissipation of any TA (ambient temperature) is PD(max) = (TJ(max) – TA) / θJA. Exceeding the maximum allowable power
dissipation will result in excessive die temperature, and the regulator will go into thermal shutdown (150°C).
4. Devices are ESD sensitive. Handling precautions recommended. Human Body Model (HBM), 1.5kΩ in series with 100pF.
5. As determined by average current of all channels in use and all channels loaded.
6. The current through each channel meets the stated limits from the average current of all channels.
7. Dropout voltage is defined as the input-output differential at which the output voltage drops 2% below its nominal value measured at VIN = VOUT+ 1V.
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MIC2846A
Typical Characteristics (WLED Driver)
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MIC2846A
Typical Characteristics (LDO)
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MIC2846A
Functional Characteristics (WLED Driver)
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Functional Characteristics (LDO)
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MIC2846A
Functional Diagram
Figure 1. MIC2846A Functional Block Diagram
Functional Description
The MIC2846A has two LDOs with a dropout voltage of
150mV at 150mA and consume 35µA of current in
operation. Each LDO has an independent enable pin,
which reduces the operating current to less than 1µA in
shutdown. Both linear regulators are stable with just 1µF
of output capacitance.
The MIC2846A is a six channel linear LED driver with
dual 150mA LDOs. The LED driver incorporates a
Dynamic Averaged MatchingTM (DAMTM) technique
designed specifically to optimize on current accuracy
and matching across process variation. It can maintain
proper current regulation with LED current accuracy of
1.5% while the typical matching between the six
channels is 1.5% at room temperature. The LED
currents are independently driven from the input supply
and will maintain regulation with a dropout of 40mV at
20mA. The low dropout of the linear LED Drivers allows
the LEDs to be driven directly from the battery voltage
and eliminates the need for boost or large and inefficient
charge pumps. The maximum LED current for each
channel is set via an external resistor while a single-wire
digital interface controls dimming.
April 2010
Block Diagram
As shown in Figure 1, the MIC2846A consists of two
LDOs with six current mirrors set to copy a master
current determined by RSET. The linear LED drivers have
a designated control block for enabling and dimming of
the LEDs. The MIC2846A dimming is controlled by the
Digital Control block that receives digital signals for
dimming. The LDOs each have their own control and are
independent of the linear LED drivers. Each LDO
consists of internal feedback resistors, an error amplifier,
a PFET transistor and a control circuit for enabling.
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MIC2846A
VIN
The input supply (VIN) provides power to the LDOs, the
linear LED drivers and the control circuitry. The VIN
operating range is 3V to 5.5V. A minimum bypass
capacitor of 1µF should be placed close to the input
(VIN) pin and the ground (GND) pin. Refer to the layout
recommendations section for details on placing the input
capacitor (C1).
LDO1/LDO2
The output pins for LDO one and LDO two are labeled
LDO1 and LDO2, respectively. A minimum of 1µF
bypass capacitor should be placed as close as possible
to the output pin of each LDO. Refer to the layout
recommendations section for details on placing the
output capacitor (C2, C3) of the LDOs.
Figure 2. Peak LED Current vs. RSET (100% Duty Cycle)
D1-D6
The D1 through D6 pins are the LED driver for LED 1
through 6, respectively. The anodes of the LEDs are
connected to VIN and the cathodes of the LEDs are
connected to D1 through D6. When operating with less
than six LEDs, leave the unused D pins unconnected.
The six LED channels are independent of one another
and may be combined or used separately. During startup, the D1 through D6 channels are turned on in
synchronization at around 250µs apart.
EN1/EN2
A logic high signal on the enable pin activates the LDO
output voltage of the device. A logic low signal on the
enable pin deactivates the output and reduces supply
current to less than 1µA. EN1 controls LDO1 and EN2
controls LDO2. Do not leave these control pins floating.
DC
The DC pin is used to enable and control dimming of the
linear drivers on the MIC2846A. See the MIC2846A
Digital Dimming Interface in the Application Information
section for details. Pulling the DC pin low for more than
1260μs puts the MIC2846A into a low IQ sleep mode.
The DC pin cannot be left floating; a floating enable pin may
cause an indeterminate state on the outputs. A 200kΩ pull
down resistor is recommended.
GND
The ground pin is the ground path for the linear drivers
and LDOs. The ground of the input capacitor should be
routed with low impedance traces to the GND pin and
made as short as possible. Refer to the layout
recommendations for more details.
RSET
The RSET pin is used by connecting a RSET resistor to
ground to set the peak current of the linear LED
driver. The average LED current can be calculated
by the equation (1).
ILED (mA) = 410 * ADC / RSET (kΩ)
(1)
ADC is the average duty cycle of the LED current
controlled by the single-wire digital dimming. See Table
1 for ADC values. When the device is fully on the
average duty cycle equals 100% (ADC=1). A plot of ILED
versus RSET at 100% duty cycle is shown in Figure 2.
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MIC2846A
Dynamic Average Matching (DAM™)
The Dynamic Average Matching™ architecture
multiplexes four voltage references to provide highly
accurate LED current and channel matching. The
MIC2846A achieves industry leading LED channel
matching of 1.5% across the entire dimming range.
Application Information
0
Average
Duty
Cycle (%)
100
1
80
Brightness Level
(0 - 48)
Average
ILED (mA)
IPEAK (mA)
12
9.6
2
60
7.2
3
48.33
5.8
4
36.67
4.4
5
29.17
3.5
6
21.67
2.6
7
16.67
2
8
11.67
1.4
9
9.17
1.1
10
6.67
0.8
11
5
0.6
12
3.33
0.4
High Current Parallel Operation
6
60% of IPEAK
RSET = 20.5kΩ
IPEAK = 12mA
Digital
13
2.5
0.3
14
1.67
0.2
15
0.83
0.1
16
0
0
17
0.83
0.1
18
0.83
0.17
Figure 3. High Current LED Driver Circuit
19
1.25
0.25
20
1.67
0.33
21
2.08
0.42
22
2.5
0.5
23
2.92
0.58
24
3.33
0.67
25
4.17
0.83
26
5
1
27
5.83
1.17
The linear drivers are independent of each other and can
be used individually or paralleled in any combination for
higher current 4applications. A single WLED can be
driven with all 6 linear drivers by connecting D1 through
D6 in parallel to the cathode of the WLED as shown in
Figure 3. This will generate a current 6 times the
individual channel current and can be used for higher
current WLEDs such as those used in flash or torch
applications.
28
6.67
1.33
29
7.92
1.58
30
9.17
1.83
31
10.42
2.08
32
11.67
2.33
33
14.17
2.83
34
16.67
3.33
35
19.17
3.83
36
21.67
4.33
37
25.42
5.08
38
29.17
5.83
39
32.92
6.58
40
36.67
7.33
41
42.5
8.5
42
48.33
9.67
43
54.17
10.83
44
60
12
45
70
14
46
80
16
47
90
18
48
100
20
0
60% of IPEAK
Digital Dimming
The MIC2846A utilizes an internal dynamic pulse width
to generate an average duty cycle for each brightness
level. By varying the duty cycle the average current
achieves 49 logarithmically spaced brightness levels.
This generates a brightness scale similar to the
perception of brightness seen by the “human eye.”
Figure 4 shows the LED current at different brightness
levels. When dimming, the D1 through D6 pins are 60°
out of phase from each other to reduce electromagnetic
interference. The MIC2846A uses an internal frequency
of approximately 700Hz to dim the WLEDs. With the
period of approximately 1.43ms, the 60° phase shift
equates to a timing offset of 238μs. As shown in Figure
5, brightness level 32 was selected to show the phase
shift across the channels.
100% of IPEAK
RSET = 20.5kΩ
IPEAK = 20mA
Table 1. Digital Interface Brightness Level Table
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MIC2846A
brightness level.
Start Up
Assuming the MIC2846A has been off for a long time
and no presetting brightness command is issued
(presetting is discussed in a later section), the
MIC2846A will start-up in its default mode approximately
140µs (tSTART_UP) after a logic level high is applied to the
DC pin, shown in Figure 6. In the default mode the LEDs
are turned on at the maximum brightness level of 48.
Each falling edge during the tPROG_SETUP period will cause
the default brightness level to decrease by one. This is
discussed in more detail in the Presetting Brightness
section.
Figure 4. LED Current with Brightness Level Change
Figure 6. Typical Start-Up Timing
Shutdown
Whenever the DC input pin is pulled low for a period
greater than or equal to tSHUTDOWN (1260µs), the
MIC2846A will be shutdown as shown in Figure 7.
Figure 5. LED Current 60° Phase Shift
Digital Dimming Interface
The MIC2846A incorporates an easy to use single-wire,
serial programming interface that allows users to set
LED brightness up to 49 different levels, as shown in the
table1.
Brightness levels 0 through 15 are logarithmically
spaced with a peak current equal to 60% of the current
programmed by RSET. Brightness level 16 is provided for
applications that want to “fade to black” with no current
flowing through the LEDs. Brightness Level 17 has the
same duty cycle as level 18, but the peak current is only
60% of the current set by RSET; therefore, the average
current is 0.1mA. Brightness levels 18 through 48 are
also logarithmically spaced, but the peak current is equal
to 100% of the current determined by RSET. Refer to
Table 1 for the translation from brightness level to
average LED duty cycle and current. The MIC2846A is
designed to receive programming pulses to increase or
decrease brightness. Once the brightness change signal
is received, the DC pin is simply pulled high to maintain
the brightness. This “set and forget” feature relieves
processor computing power by eliminating the need to
constantly send a PWM signal to the dimming pin. With
a digital control interface, brightness levels can also be
preset so that LEDs can be turned on at any particular
April 2010
Figure 7. Shutdown Timing
Once the device is shutdown, the control circuit supply is
disabled and the LEDs are turned off, drawing only
0.01µA. Brightness level information stored in the
MIC2846A prior to shutdown will be erased.
Count Up Mode/Count Down Mode
The mode of MIC2846A can be in either Count Up Mode
or Count Down Mode. The Count Down/Up Modes
determine what the falling edges of the programming
pulses will do to the brightness. In Count Up Mode,
subsequent falling edges will increase brightness while
in Count Down Mode, subsequent falling edges will
decrease brightness. By default, the MIC2846A is in
Count Down Mode when first turned on. The counting
mode can be changed to Count Up Mode, by pulling the
DC pin low for a period equal to tMODE_UP (100µs to
160µs), shown in Figure 8. The device will remain in
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MIC2846A
Count Up Mode until its mode is changed to Count Down
Mode or by disabling the MIC2846A to reset the mode
back to default.
Figure 8. Mode Change to Count Up
Figure10. Brightness Programming Pulses
To change the mode back to Count Down Mode, pull the
DC pin low for a period equal to tMODE_DOWN (420µs to
500µs), shown in Figure 9. Now the internal circuitry will
remain in Count Down Mode until changed to Count Up
as described previously.
Multiple brightness levels can be set as shown in Figure
11. When issuing multiple brightness level adjustments
to the DC pin, ensure both tPROG_LOW and tPROG_HIGH are
within 2µs to 32µs.
To maintain operation at the current brightness level
simply maintain a logic level high at the DC pin.
Figure 9. Mode Change to Count Down
Programming the Brightness Level
MIC2846A is designed to start driving the LEDs 140µs
(tSTART_UP) after the DC pin is first pulled high at the
maximum brightness level of 48. After start up, the
internal control logic is ready to decrease the LED
brightness upon receiving programming pulses (negative
edges applied to DC pin). Since MIC2846A starts in
Count Down Mode, the brightness level can be
decreased without a mode change by applying two
programming pulses, as shown in Figure10. Note that
the extra pulse is needed to decrease brightness
because the first edge is ignored. Anytime the first falling
edge occurs later than 32µs after a Mode Change, it will
be ignored. Ignoring the first falling edge is necessary in
order that Mode Change (tMODE_UP, tMODE_DOWN) pulses do
not result in adjustments to the brightness level. Each
programming pulse has a high (tPROG_HIGH) and a low
(tPROG_LOW) pulse width that must be between 2µs to
32µs. The MIC2846A will remember the brightness level
and mode it was changed to. For proper operation,
ensure that the DC pin remains high for at least tDELAY
(140µs) before issuing a mode change command.
Figure11. Decreasing Brightness Several Levels
As mentioned, MIC2846A can be programmed to set
LED drive current to produce one of 49 distinct
brightness levels. The internal logic keeps track of the
brightness level with an Up/Down counter circuit. The
following section explains how the brightness counter
functions with continued programming edges.
Counter Roll-Over
The MIC2846A internal up/down counter contains
registers from 0 to 48 (49 levels). When the brightness
level is at 0 and a programming pulse forces the
brightness to step down, then the counter will roll-over to
level 48. This is illustrated in Figure 12.
Figure 12. Down Counter Roll-Over
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Similarly, when the counter mode is set to Count Up and
a programming pulse forces the brightness level to step
up from level 48, then the counter will roll-over to level 0
as illustrated in Figure 13.
Presetting Brightness
Presetting the brightness will allow the MIC2846A to
start-up at any brightness level (0 to 48). The MIC2846A
does not turn on the linear LED driver until the DC pin is
kept high for tSTART_UP (140µs). This grants the user time
to preset the brightness level by sending a series of
programming edges via the DC pin. The precise timing
for the first down edge is between 5µs to 75µs after the
DC pin is first pulled high. The 70µs timeframe between
5µs and 75µs is the tPROG_SETUP period. The first
presetting pulse edge must occur somewhere between
the timeframe of 5µs to 75µs, otherwise the MIC2846A
may continue to start up at the full (default) brightness
level.
Figure 13. Up Counter Roll-Over
One-Step Brightness Changes
The “One-Step” brightness change procedure relieves
the user from keeping track of the MIC2846A’s up/down
counter mode. It combines a Mode Change with a
programming edge; therefore, regardless of the previous
Count Mode, it will change the brightness level by one.
Figure 16. Presetting Timing
Figure 16 shows the correct presetting sequence to set
the MIC2846A brightness to level 39 prior to start up.
Notice that when using the presetting feature the first
programming pulse is not ignored. This is because the
counter’s default mode is Count Down and a Mode
Change cannot be performed in the presetting mode.
(Note that the tPROG_HIGH and tPROG_LOW pulse width must
still be between 2µs to 32µs.)
Figure 14. One-Step Brightness Decrease
The One-Step Brightness Decrease method is quite
simple. First, the DC pin is pulled low for a period equal
to the tMODE_DOWN (420µs to 500µs) and immediately
followed by a falling edge within tPROG_HIGH (2µs to 32µs)
as shown in Figure 14. This will decrease the brightness
level by 1. Similarly a One-Step Brightness Increase can
be assured by first generating a DC down pulse whose
period is equal to the tMODE_UP (100µs to 160µs) and
immediately followed by a falling edge within tPROG_HIGH
(2µs to 32µs). Figure 15 illustrates the proper timing for
execution of a One-Step Brightness Increase.
Figure 15. One-Step Brightness Increase
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output current and the voltage drop across the part. For
example if the input voltage is 3.6V, the output voltage is
2.8V, and the output current = 150mA. The actual power
dissipation of the regulator circuit can be determined
using the equation:
LDO
MIC2846A LDOs are low noise 150mA LDOs. The
MIC2846A LDO regulator is fully protected from damage
due to fault conditions, offering linear current limiting and
thermal shutdown.
PLDO1 = (VIN – VOUT1) I OUT + VIN IGND
Because this device is CMOS and the ground current
(IGND) is typically <100µA over the load range, the power
dissipation contributed by the ground current is < 1% and
can be ignored for this calculation.
PLDO1 = (3.6V – 2.8V) × 150mA
Input Capacitor
The MIC2846A stability can be maintained using a
ceramic input capacitor of 1µF. Low-ESR ceramic
capacitors provide optimal performance at a minimum
amount of space. Additional high-frequency capacitors,
such as small-valued NPO dielectric-type capacitors,
help filter out high-frequency noise and are good
practice in any noise sensitive circuit. X5R or X7R
dielectrics are recommended for the input capacitor. Y5V
dielectrics lose most of their capacitance over
temperature and are therefore, not recommended.
PLDO1 = 0.120W
Since there are two LDOs in the same package, the
power dissipation must be calculated individually and
then summed together to arrive at the total power
dissipation.
PTOTAL = PLDO1 + PLDO2
Output Capacitor
The MIC2846A LDOs require an output capacitor of at
least 1µF or greater to maintain stability, however, the
output capacitor can be increased to 2.2µF to reduce
output noise without increasing package size. The
design is optimized for use with low-ESR ceramic chip
capacitors. High ESR capacitors are not recommended
because they may cause high frequency oscillation.
X7R/X5R dielectric-type ceramic capacitors are
recommended due to their improved temperature
performance compared to Z5U and Y5V capacitors.
X7R-type capacitors change capacitance by 15% over
their operating temperature range and are the most
stable type of ceramic capacitors. Z5U and Y5V
dielectric capacitors change value by as much as 50%
and 60%, respectively, over their operating temperature
ranges. To use a ceramic chip capacitor with Y5V
dielectric, the value must be much higher than an X7R
ceramic capacitor to ensure the same minimum
capacitance over the equivalent operating temperature
range.
To determine the maximum ambient operating
temperature of the package, use the junction-to-ambient
thermal resistance (θJA = 60°C/W) of the device and the
following basic equation:
⎛ TJ(max) − TA
PTOTAL(max) = ⎜⎜
θ JA
⎝
TJ(max) = 125°C, is the maximum junction temperature of
the die and θJA, is the thermal resistance = 60°C/W.
Substituting PTOTAL for PTOTAL(max) and solving for the
ambient operating temperature will give the maximum
operating conditions for the regulator circuit.
For example, when operating the MIC2846A LDOs
(LDO1=2.8V and LDO2=1.5V) at an input voltage of
3.6V with 150mA load on each, the maximum ambient
operating temperature TA can be determined as follows:
PLDO1 = (3.6V – 2.8V) × 150mA = 0.120W
PLDO2 = (3.6V – 1.5V) × 150mA = 0.315W
PTOTAL=0.120W+ 0.315W = 0.435W
= (125°C – TA)/(60°C/W)
TA = 125°C – 0.435W × 60°C/W
TA = 98.9°C
Therefore, under the above conditions, the maximum
ambient operating temperature of 98.9°C is allowed.
No-Load Stability
Unlike many other voltage regulators, the MIC2846A
LDOs will remain stable and in regulation with no load.
Thermal Considerations
The MIC2846A LDOs are each designed to provide
150mA of continuous current. Maximum ambient
operating temperature can be calculated based on the
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MIC2846A
MIC2846A Typical Application Circuit
6
Digital
Bill of Materials
Item
C1, C2,
C3
D1 – D6
R1
R2
U1
Part Number
Manufacturer
C1608X5R0J105K
TDK
06036D105KAT2A
AVX(2)
GRM188R60J105KE19D
Murata(3)
VJ0603G225KXYAT
Vishay(4)
SWTS1007
Seoul Semiconductor(5)
99-116UNC
EverLight(6)
CRCW060320K5F5EA
Vishay(4)
CRCW06032003FKEA
(4)
MIC2846A-xxYMT
Description
Qty.
(1)
Vishay
Micrel, Inc.(7)
Ceramic Capacitor, 1µF, 6.3V, X5R, Size 0603
1
WLED
6
Resistor, 20.5k, 1%, 1/16W, Size 0603
1
Resistor, 200k, 1%, 1/16W, Size 0603
1
6 Channel Digital Control Linear WLED Driver with
DAM™ and Dual Low IQ LDO
1
Notes:
1. TDK: www.tdk.com
2. AVX: www.avx.com
3. Murata: www.murata.com
4. Vishay: www.vishay.com
5. Seoul Semiconductor: www.seoulsemicon.com
6. EverLight: www.everlight.com
7. Micrel, Inc.: www.micrel.com
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MIC2846A
PCB Layout Recommendations (Fixed)
Top Layer
Bottom Layer
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MIC2846A
Package Information
14-Pin (2.5mm x 2.5mm) Thin MLF® (MT)
MICREL, INC. 2180 FORTUNE DRIVE SAN JOSE, CA 95131 USA
TEL +1 (408) 944-0800 FAX +1 (408) 474-1000 WEB http://www.micrel.com
The information furnished by Micrel in this data sheet is believed to be accurate and reliable. However, no responsibility is assumed by Micrel for its
use. Micrel reserves the right to change circuitry and specifications at any time without notification to the customer.
Micrel Products are not designed or authorized for use as components in life support appliances, devices or systems where malfunction of a product
can reasonably be expected to result in personal injury. Life support devices or systems are devices or systems that (a) are intended for surgical implant
into the body or (b) support or sustain life, and whose failure to perform can be reasonably expected to result in a significant injury to the user. A
Purchaser’s use or sale of Micrel Products for use in life support appliances, devices or systems is a Purchaser’s own risk and Purchaser agrees to fully
indemnify Micrel for any damages resulting from such use or sale.
© 2009 Micrel, Incorporated.
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