MICREL MIC3223YTSE

MIC3223
High Power Boost LED Driver with
Integrated FET
General Description
Features
The MIC3223 is a constant current boost LED driver
capable of driving a series string of high power LEDs. The
MIC3223 can be used in general lighting, bulb replacement,
garden pathway lighting and other solid state illumination
applications.
The MIC3223 is a peak current mode control PWM boost
regulator and the 4.5V and 20V operating input voltage
range allows multiple applications from a 5V or a 12V bus.
The MIC3223 implements a fixed internal 1MHz switching
frequency to allow for a reduction in the design footprint
size. Power consumption has been minimized through the
implementation of a 200mV feedback voltage that provides
an accuracy of ±5%. The MIC3223 can be dimmed through
the use of a PWM signal and features an enable pin for a
low power shutdown state.
The MIC3223 is a very robust LED driver and offers the
following protection features: over voltage protection (OVP),
thermal shutdown, switch current limiting and under voltage
lockout (UVLO).
The MIC3223 is offered in a low profile exposed pad 16-pin
TSSOP package.
Data sheets and support documentation can be found on
Micrel’s web site at: www.micrel.com.
•
•
•
•
•
•
•
•
•
4.5V to 20V supply voltage
200mV feedback voltage with an accuracy of ±5%
Step-up output voltage (boost) conversion up to 37V
1MHz switching frequency
100mΩ/3.5A internal power FET switch
LEDs can be dimmed using a PWM signal
User settable LED current (through external resistor)
Externally programmable soft-start
Protection features that include:
– Output over-voltage protection (OVP)
– Under-voltage lockout (UVLO)
– Over temperature protection
• Junction temperature range: -40°C to +125°C
• Available in a exposed pad 16-pin TSSOP package
Applications
•
•
•
•
•
•
Architectural lighting
Industrial lighting
Signage
Landscape lighting (garden/pathway)
Under cabinet lighting
MR-16 bulbs
_______________________________________________________________________________________________________________________
Typical Application
Micrel Inc. • 2180 Fortune Drive • San Jose, CA 95131 • USA • tel +1 (408) 944-0800 • fax + 1 (408) 474-1000 • http://www.micrel.com
January 2010
M9999-011510-A
Micrel, Inc.
MIC3223
Ordering Information
Part Number
Junction Temp. Range
Package
Lead Finish
–40° to +125°C
16-pin ePad TSSOP
PB- free
MIC3223YTSE
Pin Configuration
16-Pin ePad TSSOP (TSE)
Pin Description
Pin Number
Pin Name
1
EN
Enable (Input): Logic high enables and logic low disables operation.
2
SS
Soft Start (Input resistance of 30k). Connect a capacitor to GND for soft-start. Clamp the
pin to a known voltage to control the internal reference voltage and hence the output
current.
3
COMP
4
FB
5
OVP
6
PGND
7,8,9,10
SW
11
VIN
12
DRVVDD
13
VDD
14
DIM_IN
15
DIM_OUT
16
AGND
17
EP
January 2010
Pin Function
Compensation Pin (Input): Add external R and C-to-GND to stabilize the converter.
Negative Input to Error Amp
Connect to the centre tap of an external resistor divider, the top of which is tied to Vout
and bottom-to-ground.
Power Ground
Switch Node (Input): Internal NMOS switch Drain Pin
Input Supply
For 4.5V < VIN < 6V, connect DRVVDD to VIN. DRVVDD is the input voltage supply for
the converter’s internal power FET gate driver. For VIN > 6V, connect this pin to VDD.
For 4.5V < VIN < 6V, this pin becomes the input voltage supply for the converter’s internal
circuit. For VIN > 6V, this pin is an output of the internal 5.5V regulator that supplies
internal circuits. User must add 10µF decoupling capacitor from VDD-to-AGND.
PWM input to control LED dimming.
Output driver to drive external FET for LED dimming.
Analog Ground
Connect to Power Ground
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M9999-011510-A
Micrel, Inc.
MIC3223
Absolute Maximum Ratings(1)
Operating Ratings(2)
Supply Voltage (VIN) .....................................................+22V
Switch Voltage (VSW)..................................... -0.3V to +42V
Regulated Voltage (VDD) ............................... -0.3V to +6.5V
Dimming In Voltage (VDIM_IN) ...............-0.3V to (VDD + 0.3V)
Dimming Out Voltage (VDIM_OUT)..........-0.3V to (VDD + 0.3V)
Soft-Start Voltage (VSS) .......................-0.3V to (VDD + 0.3V)
Enable Voltage (VEN)............................-0.3V to (VIN + 0.3V)
Feedback Voltage (VFB) ......................-0.3V to (VDD + 0.3V)
Switch Current (ISW) ..................................Internally Limited
Comp Voltage (VCOMP).......................-0.3V to (+VDD + 0.3V)
FET Driver Supply (VDRVVDD) ......................... -0.3V to +6.5V
PGND to AGND ............................................ -0.3V to +0.3V
Over Voltage Protection (VOVP) ...........-0.3V to (VDD + 0.3V)
Peak Reflow Temperature (soldering, 10-20sec.) ..... 260°C
Storage Temperature (TS)..........................-65°C to +150°C
ESD Rating(3) ................................................................+2kV
Supply Voltage (VIN)...................................... +4.5V to +20V
Switch Voltage (VSW)....................................................+37V
Junction Temperature (TJ) .........................-40°C to +125°C
Junction Thermal Resistance
ePad TSSOP-16L (θJA)...................................36.5°C/W
Electrical Characteristics(4)
VIN = VEN = 12V; L = 22µH, CIN =4.7µF, COUT =2x4.7µF; TA = 25°C, BOLD values indicate –40°C≤ TJ ≤ +125°C, unless otherwise noted.
Symbol
Parameter
VIN
Voltage Supply Range
VUVLO
Under Voltage Lockout
VOVP
Over Voltage Protection
IVIN
Quiescent Current
ISD
Shutdown Current
VFB
Feedback Voltage
IFB
Feedback Input Current
VDD
Internal Voltage Regulator
DMAX
Maximum Duty Cycle
VDD Line Regulation
Condition
Min
Typ
4.5
Monitoring for VDD
Max
Units
20
V
3
3.7
4.4
V
1.216
1.28
1.344
V
2.1
5
mA
10
µA
200
210
mV
216
mV
VFB=250mV
VEN =0V
Room Temperature
190
Over Temperature
184
VFB=200mV
85
VLED=18V, VIN=8V to 16V, ILED=350mA
-450
nA
5.3
V
90
95
0.5
9
%
ISW
Switch Current Limit
RSW
Switch RDSON plus RCS
ISW
Switch Leakage Current
VEN
Enable Threshold
IEN
Enable Pin Current
VDIM_TH_H
DIM_IN Threshold High
Logic High
VDIM_TH_L
DIM_IN Threshold Low
Logic Low
Hys
DIM_IN Hysteresis
IDIM_IN
DIM_IN Pin Current
VDIM_IN = 5V
TDR
Dim Delay (Rising)
DIM_IN Rising
40
ns
TDF
Dim Delay (Falling
DIM_IN Falling
30
ns
January 2010
3.5
%
10.5
100
VEN=0, VSW=37V
0.01
Turn On
mΩ
10
1.5
µA
V
Turn Off
20
0.4
V
40
µA
1.5
V
0.4
500
V
mV
1
3
A
µA
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Micrel, Inc.
MIC3223
Symbol
Parameter
DIM MIN
Minimum Dimming Pulse
RDO
DIM_OUT Resistance High
RDO
DIM_OUT Resistance Low
Condition
Min
Typ
Max
Units
DIM_IN =1µs CDIM_OUT = 1.25nF
0.7
1.3
µs
DIM_OUT measured from 4V rising to 2.5
falling
0.5
1.5
µs
DIM_OUT pull up resistance
IDIM_OUT = +2mA
Dim Out pull down resistance
IDIM_OUT = -2mA
70
Ω
40
Ω
FSW
Oscillator Frequency
0.7
1
1.3
MHz
RSS
Soft Start Resistance
30
46
62
kΩ
TSD
Over Temperature Threshold
Shutdown
Temperature rising
165
°C
Hysteresis
10
°C
Notes
1. Exceeding the absolute maximum rating may damage the device.
2. The device is not guaranteed to function outside its operating rating.
3. Devices are ESD sensitive. Handling precautions recommended. Human body model, 1.5kΩ in series with 100pF.
4. Specification for packaged product only.
Test Circuit
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MIC3223
Typical Characteristics
98
5.50
T = 25°C
96
9.5
5.45
5.40
92
90
88
86
84
82
5.35
5.30
5.25
5.20
5.15
VOUT = 25V
5.10
IOUT = 0.5A
5.05
80
9.0
T = 25°C
CURRENT LIM IT (A)
VDD VOLTAGE (V)
94
EFFICIENCY (%)
Current Lim it
v s. Input Voltage
VDD Voltage
v s. Input Voltage
Efficiency
v s. Input Voltage
VOUT = 25V
10
15
20
5
10
INPUT VOLT AGE (V)
7.5
7.0
15
4
20
1.2
0.220
0.218
0.204
0.202
0.200
0.198
0.196
0.194
VOUT = 30V
0.192
IOUT =0.36A
T = 25°C
1.1
FEEDBACK VOLTAGE (V)
SWITCHING FREQUENCY (MHz)
0.206
1.1
1.0
VDD = VIN
VIN = 4.5V to 6V
1.0
VOUT = 30V
IOUT = 0.36A
4
9
14
4
19
0.216
0.214
0.212
0.210
0.208
0.206
9
INPUT VOLT AG E (V)
VOUT = 26V
0.202
IOUT = 0.36A
14
-40
19
RSW _NODE vs.
T emperature
1.20
0.17
1.15
SWITCHING FREQUENCY (MHz)
0.18
10.0
0.16
RSW_NO DE (Ω)
9.5
9.0
8.5
8.0
7.5
7.0
0.15
0.14
0.13
VIN = 12V
0.12
VOUT = 36V
0.11
VIN = 12V
ISW = 1.3A
0.10
6.0
20
40
60
80
-40
100 120
-20
0
20
40
60
Efficiency
v s. Output Current
80
8V
86
84
82
80
0.5
1
OUT PUT CURRENT (A)
January 2010
1.5
IOUT = 0.36A
-20
0
20
40
60
80
100 120
Efficiency
v s. Output Current
20V
94
14V
90
88
86
84
18V
92
90
88
86
84
82
VOUT = 25V
VOUT = 25V
80
80
0
VOUT = 26V
0.85
96
82
VOUT = 25V
VIN = 12V
0.90
T EM PERAT URE (°C)
EFFICIENCY (%)
EFFICIENCY (%)
10V
88
0.95
98
92
90
100 120
1.00
-40
16V
94
92
80
0.80
100 120
96
12V
94
60
1.05
Efficiency
v s. Output Current
96
40
1.10
T EM PERAT URE (°C)
T EM PERAT URE (°C)
20
Switching Frequency
v s. Temperature
10.5
0
0
T EM PERAT URE (°C)
11.0
-20
-20
INPUT VOLT AGE (V)
Current Lim it
v s. Temperature
6.5
VIN = 12V
0.204
0.200
0.9
0.190
CURRENT LIM IT (A)
19
Feedback Voltage
v s. Temperature
0.208
EFFICIENCY (%)
14
INPUT VOLT AGE (V)
Switching Frequency
v s. Input Voltage
0.210
-40
9
INPUT VOLT AGE (V)
Feedback Voltage
v s. Input Voltage
REFERENCE VOTLAG E (V)
8.0
VIN = 4.5V to 6V
IOUT = 0.5A
5.00
5
T = 25°C
8.5
0
0.5
1
OUT PUT CURRENT (A)
5
1.5
0
0.5
1
1.5
OUT PUT CURRENT (A)
M9999-011510-A
Micrel, Inc.
MIC3223
Typical Characteristics (continued)
Efficiency
v s. Output Current
Efficiency
v s. Output Current
96
96
94
94
92
10V
EFFICIENCY (%)
EFFICIENCY (%)
92
90
88
86
84
82
12V
90
88
86
84
82
VOUT = 25V
80
VOUT = 25V
80
0
0.5
1
OUT PUT CURRENT (A)
January 2010
1.5
0
0.5
1
1.5
OUT PUT CURRENT (A)
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MIC3223
Functional Characteristics
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MIC3223
Functional Characteristics (continued)
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MIC3223
Functional Diagram
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MIC3223
current is regulated. If VFB drops, VEA increases and
therefore the power FET remains on longer so that VCS
can increase to the level of VEA. The reverse occurs
when VFB increases.
Functional Description
A constant current output converter is the preferred
method for driving LEDs. Small variations in current
have a minimal effect on the light output, whereas small
variations in voltage have a significant impact on light
output. The MIC3223 LED driver is specifically designed
to operate as a constant current LED Driver.
The MIC3223 is designed to operate as a boost
converter, where the output voltage is greater than the
input voltage. This configuration allows for the design of
driving multiple LEDs in series to help maintain color and
brightness. The MIC3223 can also be configured as a
SEPIC converter, where the output voltage can be either
above or below the input voltage.
The MIC3223 has an input voltage range, from 4.5V and
20V, to address a diverse range of applications. In
addition, the LED current can be programmed to a wide
range of values through the use of an external resistor.
This provides design flexibility in adjusting the current for
a particular application need.
The MIC3223 features a low impedance gate driver
capable of switching large MOSFETs. This low
impedance provides higher operating efficiency.
The MIC3223 can control the brightness of the LEDs via
its PWM dimming capability. Applying a PWM signal (up
to 20kHz) to the DIM_IN pin allows for control of the
brightness of the LEDs.
The MIC3223 boost converter employs peak current
mode control. Peak current mode control offers
advantages over voltage mode control in the following
manner. Current mode control can achieve a superior
line transient performance compared to voltage mode
control and is easier to compensate than voltage mode
control, thus allowing for a less complex control loop
stability design. Page 9 of this datasheet shows the
functional block diagram.
PWM Dimming
This control process just described occurs during each
DIM_IN pulse and when ever DIM_IN is high. When
DIM_IN is low, the boost converter will no longer switch
and the output voltage will drop. For high dimming ratios
use an external PWM Dimming switch as shown in the
Typical Application. When the dim pulse is on the
external switch is on and circuit operates in the closed
loop control mode as described. When the DIM_IN is low
the boost converter does not switch and the external
switch is open and no LED current can flow and the
output voltage does not droop. When DIM_IN goes high
the external switch is driven on and LED current flows.
The output voltage remains the same (about the same)
during each on and off DIM_IN pulse.
PWM Dimming can also be used in the Test Circuit in
applications that do not require high dimming ratios. In
the Test Circuit, the load is not removed from the output
voltage between DIM_IN pulses and will therefore drain
the output capacitors. The voltage that the output will
discharge to is determined by the sum of the VF (forward
voltage drops of the LEDs). When VOUT can no longer
forward bias the LEDs, then the LED current will stop
and the output capacitors will stop discharging. During
the next DIM_IN pulse VOUT has to charge back up
before the full LED current will flow. For applications that
do not require high dimming ratios.
Boost Converter operation
The boost converter is a peak current mode pulse width
modulation (PWM) converter and operates as follows. A
flip-flop (FF) is set on the leading edge of the clock
cycle. When the FF is set, a gate driver drives the power
FET on. Current flows from VIN through the inductor (L)
and through the power switch and also through the
current sense resistor to PGND. The voltage across the
current sense resistor is added to a slope compensation
ramp (needed for stability). The sum of the current sense
voltage and the slope compensation voltages (called
VCS) is fed into the positive terminal of the PWM
comparator. The other input to the PWM comparator is
the error amp output (called VEA). The error amp’s
negative input is the feedback voltage (VFB). VFB is the
voltage across RADJ (R5). In this way the output LED
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MIC3223
Output Over Voltage Protection (OVP)
The MIC3223 provides an OVP circuitry in order to
protect the system from an overvoltage fault condition.
This OVP threshold can be programmed through the
use of external resistors (R3 and R4 in the Typical
Application). A reference value of 1.245V is used for the
OVP. Equation 3 can be used to calculate the resistor
value for R9 to set the OVP point. Normally use 100k for
R3.
Application Information
Constant Output Current Converter
The MIC3223 is a peak current mode boost converter
designed to drive high power LEDs with a constant
current output. The MIC3223 operates with an input
voltage range from 4.5V to 20V. In the boost
configuration, the output can be set from VIN up to 37V.
The peak current mode control architecture of the
MIC3223 provides the advantages of superior line
transient response as well as an easier to design
compensation.
The MIC3223 LED driver features a built-in soft start
circuitry in order to prevent start-up surges. Other
protection features include:
DRVVDD
An internal linear regulator is used to provide the
necessary internal bias voltages to the gate driver that
drives the external FET. When VIN is above 6V connect
DRVVDD to VDD.
When VIN is 6V or below connect the DRVVDD pin to
VIN. Use a bypass capacitor, 10µF ceramic capacitor.
• Over Voltage Protection (OVP) – output over
voltage protection to prevent operation above a
safe upper limit
• Under Voltage Lockout (UVLO) – UVLO designed
to prevent operation below a safe lower limit
Setting the LED Current
The current through the LED string is set via the value
chosen for the current sense resistor RADJ which is R5 in
the schematic of the Typical Application. This value can
be calculated using Equation 1:
ILED =
UVLO
Internal under voltage lock out (UVLO) prevents the part
from being used below a safe VIN voltage. The UVLO is
3.7V. Operation below 4.5V is not recommended.
0.2V
R ADJ
Soft Start
Soft start is employed to lessen the inrush currents
during turn on. At turn on the following occurs;
1. After about 1.5ms CSS will start to rise in a
exponential manner according to;
Another important parameter to be aware of in the boost
converter design is the ripple current. The amount of
ripple current through the LED string is equal to the
output ripple voltage divided by the LED AC resistance
(RLED – provided by the LED manufacturer) plus the
current sense resistor RADJ. The amount of allowable
ripple through the LED string is dependent upon the
application and is left to the designer’s discretion. The
equation is shown in Equation 2.
VSS
ΔILED ≈
Where
VOUTRIPPLE =
(RLED + R ADJ )
ILED × D
COUT × FSW
Reference Voltage
The voltage feedback loop the MIC3223 uses an internal
voltage of 200mV with an accuracy of ±5%. The
feedback voltage is the voltage drop across the current
sense resistor as shown in the Typical Application.
When in regulation the voltage at VFB will equal 200mV.
January 2010
−t
⎛
⎞
⎜
(37kΩ×C SS ) ⎟
= 0.2⎜1 − e
⎟
⎜
⎟
⎝
⎠
2. According to the block diagram, VSS is the ref
node of the error amp. PWM switching start
when VSS begins to rise.
3. When the CSS is fully charged, 0.2V will be at the
error amp reference and steady state operation
begins.
4. Design for soft-start time using the above
equation.
VOUTRIPPLE
Eq. (2)
R3
(VOVP /1.245) − 1
VDD
An internal linear regulator is used to provide the
necessary internal bias voltages. When VIN is 6V or
below connect the VDD pin to VIN. Use a 10µF ceramic
bypass capacitor.
• Current Limit (ILIMIT) – Current sensing for over
current and overload protection
Eq. (1)
R4 =
Eq. (3)
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MIC3223
If high dimming ratios are required, a lower Dimming
frequency is required. During each DIM_IN pulse the
inductor current has to ramp up to it steady state value in
order for the programmed LED current to flow. The
smaller the inductance value the faster this time is and a
narrower DIM_IN pulse can be achieved. But smaller
inductance means higher ripple current.
Figure 1. Soft start
LED Dimming
The MIC3223 LED driver can control the brightness of
the LED string via the use of pulse width modulated
(PWM) dimming. An input signal from DC up to 20kHz
can be applied to the DIM_IN pin (see Typical
Application) to pulse the LED string ON and OFF. It is
recommended to use PWM dimming signals above
120Hz to avoid any recognizable flicker by the human
eye. PWM dimming is the preferred way to dim an LED
in order to prevent color/wavelength shifting. Color
wavelength shifting will occur with analog dimming. By
employing PWM Dimming the output current level
remains constant during each DIM_IN pulse. The boost
converter switches only when DIM_IN is high. Between
DIM_IN pulses the output capacitors will slowly
discharge. The higher the DIM_IN frequency the less the
output capacitors will discharge.
Figure 3. PWM Dimming 20%
Figure 3 shows that switching occurs only during DIM_IN
on pulses. When DIM_IN is low the boost converter
stops switching and the external LED is turned off. The
LED current flows only when DIM_IN is high. Figure 3
shows that the compensation pin (VCOMP) does not
discharge between DIM_IN pulses. Therefore, when the
DIM_IN pulse starts again the converter resumes
operation at the same VCOMP voltage. This eliminates the
need for the comp pin to charge up during each DIM_IN
pulse and allows for high Dimming ratios.
PWM Dimming Limits
The minimum pulse width of the DIM_IN is determined
by the DIM_IN frequency and the L and C used in the
boost stage output filter. At low DIM_IN frequencies
lower dimming ratios can be achieved.
Dim_ratio =
LED_ON_TIM E
PERIOD PWMD
Figure 4. PWM Dimming 10% and ILED 100Hz
Figure 2. DIM_IN Dimming Ratio
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MIC3223
Figure 5. PWM Dimming 20% and ILED 1kHz
Figure 7. 5µs DIM_IN Pulse
In Figure 4 is at 100Hz dimming frequency and Figure 5
is 1kHz dimming frequency. The time it takes for the
LED current to reach it full value is longer with a lower
Dimming frequency. The reason is the output capacitors
slowly discharge between dimming pulses.
Figure 7 shows the minimum DIM_IN pulse at these
operating conditions before the ILED current starts to drop
due to low VOUT. The converter is ON (switching) only
during a DIM_IN pulse.
Figure 7 shows that at this DIM_IN pulse width the
converter is ON (switching) long enough to generate the
necessary VOUT to forward bias the LED string at the
programmed current level. Therefore this condition will
result in the desired ILED.
Figure 6. PWM Dimming 20% and ILED 1kHz
Figure 6 shows the output voltage VOUT discharge
between DIM_IN pulses. The amount of discharge is
dependent on the time between DIM_IN pulses.
Figure 8. 2.5µs DIM_IN Pulse
Figure 8 shows that at this DIM_IN pulse width the
converter in not ON (switching) long enough to generate
the necessary VOUT to forward bias the LED string at the
programmed current level. As a result the LED current
drops. Therefore, this condition will not result in the
desired ILED.
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MIC3223
Design Procedure for a LED Driver
Symbol
Parameter
Min
Nom
Max
Units
Input
VIN
Input Voltage
IIN
Input Current
8
12
14
V
2
A
Output
LEDs
Number of LEDs
5
6
7
VF
Forward Voltage of LED
3.2
3.5
4.0
V
VOUT
Output Voltage
16
21
28
V
ILED
LED Current
0.33
0.35
0.37
A
IPP
Required I Ripple
Pout
Output Power
DIM_IN
PWM Dimming
OVP
Output Over Voltage Protection
30
V
FSW
Switching Frequency
1
MHz
eff
Efficiency
80
%
VDIODE
Forward drop of schottky diode
0.5
V
40
0
mA
10.36
W
100
%
System
Table 1. Design example parameters
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MIC3223
Design Example
In this example, we will be designing a boost LED driver
operating off a 12V input. This design has been created to
drive 6 LEDs at 350mA with a ripple of about 20%. We are
designing for 80% efficiency at a switching frequency of
1MHz.
Select RADJ
Having chosen the LED drive current to be 350mA in this
example, the current can be set by choosing the RADJ
resistor from Equation 1:
R ADJ =
0.2V
= 0.57Ω
0.35A
Use the next lowest standard value 0.56Ω.
ILED = 0.36A
The power dissipation in this resistor is:
PRADJ = ILED 2 × R ADJ = 71mW
Use a resistor rated at quarter watt or higher.
Operating Duty Cycle
The operating duty cycle can be calculated using Equation
four provided below:
(V − VIN + VDIODE )
D = OUT
Eq. (4)
VOUT + VDIODE
VDIODE is the Vf of the output diode D1 in the Typical
Application. It is recommended to use a schottky diode
because it has a lower Vf than a junction diode.
These can be calculated for the nominal (typical) operating
conditions, but should also be understood for the minimum
and maximum system conditions as listed below.
Dnom =
Dmax =
Dmin =
(VOUT(nom) − VIN(nom) + VDIODE )
VOUT(nom) + VDIODE
(VOUT(max) − VIN(min) + VDIODE )
VOUT(max) + VDIODE
(VOUT(min) − VIN(max) + VDIODE )
VOUT(min) + VDIODE
(21 − 12 − 0.5) = 0.44
Dnom =
Using Equation 5, the following values have been
calculated:
IIN_RMS(max) =
IIN_RMS(nom ) =
Eq (5)
VOUT(max) × IOUT(max)
eff × VIN(min)
VOUT(nom) × IOUT(nom)
eff × VIN(nom)
VOUT(min) × IOUT(min)
IIN_RMS(min) =
eff × VIN(max)
Eq. (6)
Therefore Dnom = 44%, Dmax = 72% and Dmin = 15%.
Inductor Selection
First calculate the RMS input current (nominal, min and
max) for the system given the operating conditions listed in
the design example table. The minimum value of the RMS
input current is necessary to ensure proper operation.
January 2010
= 0.46A (RMS)
L=
VIN × D
I
×F
IN_PP SW
Using the nominal values, we get:
L=
12V × 0.44
0.3A × 1MHz
= 18μH
Select the next higher standard inductor value of 22µH.
Going back and calculating the actual ripple current gives:
IIN_PP(max) =
VIN(min) × D max
L × FSW
=
8V × 0.72
= 0.26A PP
22 μH × 1MHz
The average input current is different than the RMS input
current because of the ripple current. If the ripple current is
low, then the average input current nearly equals the RMS
input current. In the case where the average input current
is different than the RMS, equation 7 shows the following:
Eq. (7)
( 21- 12 + 0.5) = 0.44
=
21+ 0.5
= 0.74A (RMS)
IOUT is the same as ILED.
Selecting the inductor current (peak-to-peak), IL_PP, to be
between 20% to 50% of IIN_RMS(nom), in this case 40%, we
obtain:
IIN_PP(nom) = 0.4 × IIN_RMS(nom) = 0.4 × 0.74 = 0.30AP-P
It can be difficult to find large inductor values with high
saturation currents in a surface mount package. Due to
this, the percentage of the ripple current may be limited by
the available inductor. It is recommended to operate in the
continuous conduction mode. The selection of L described
here is for continuous conduction mode.
IIN_AVE(max) =
(IIN_RMS(max) )2 −
21 + 0.5
Dnom
= 1.54A (RMS)
IIN_AVE(max) = (1.54 )2 −
(IIN_PP ) 2
12
(0.24) 2
≈ 1.54 A
12
The Maximum Peak input current IL_PK can found using
Equation 8:
Eq. (8)
IL_PK(max) = IIN_AVE(max) + 0.5 ×IL_PP(max) = 1.67A
The saturation current (ISAT) at the highest operating
temperature of the inductor must be rated higher than this.
The power dissipated in the inductor is:
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MIC3223
Eq. (9)
PINDUCTOR = IIN_RMS(max)2 × DCR
A Coilcraft # MSS1260-223ML is used in this example. Its
DCR is 52mΩ, ISAT =2.7A
PINDUCTOR = 1.542 × 52 mΩ = 0.123W
Output Capacitor
In this LED driver application, the ILED ripple current is a
more important factor when compared to that of the output
ripple voltage (although the two are directly related). To
find the COUT for a required ILED ripple use the following
calculation:
For an output ripple ILED(ripple) = 20ma
Eq. (10)
C OUT =
ILED(nom) × D nom
ILED(ripple) × (R ADJ + R LED_total ) × FSW
Find the equivalent ac resistance RLED_ac from the
datasheet of the LED. This is the inverse slope of the ILED
vs. Vf curve i.e.:
ΔVf
ΔLED
In this example use RLED_ac = 0.6Ω for each LED.
If the LEDs are connected in series, multiply RLED_ac = 0.6Ω
by the total number of LEDs. In this example of six LEDs,
we obtain the following:
RLED_total ≡ Rdynamic = 6 × 0.6Ω = 3.6Ω
Eq. (12)
RLED_ac =
Eq. (11)
C OUT =
ILED(nom) × D nom
ILED(ripple) × (R ADJ + R LED_total ) × FSW
= 1.9 μF
Use 2.2µF or higher.
There is a trade off between the output ripple and the
rising edge of the DIM_IN pulse. This is because between
PWM dimming pulses, the converter stops pulsing and
COUT will start to discharge. The amount that COUT will
discharge depends on the time between PWM Dimming
pluses. At the next DIM_IN pulse, COUT has to be charged
up to the full output voltage VOUT before the desired LED
current flows.
Input Capacitor
The input capacitor is shown in the Typical Application.
For superior performance, ceramic capacitors should be
used because of their low equivalent series resistance
(ESR). The input capacitor CIN ripple current is equal to the
ripple in the inductor. The ripple voltage across the input
capacitor, CIN is the ESR of CIN times the inductor ripple.
The input capacitor will also bypass the EMI generated by
the converter as well as any voltage spikes generated by
the inductance of the input line. For a required VIN(ripple):
Eq. (13)
January 2010
C IN =
IIN_PP
VIN(ripple) × FSW
=
(0.3A)
= 0.75 μF
8 × 50mV × 1MHz
This is the minimum value that should be used. To protect
the IC from inductive spikes or any overshoot, a larger
value of input capacitance may be required.
Use 2.2µF or higher as a good safe min.
Rectifier Diode Selection
A schottky diode is best used here because of the lower
forward voltage and the low reverse recovery time. The
voltage stress on the diode is the max VOUT and therefore
a diode with a higher rating than max VOUT should be used.
An 80% de-rating is recommended here as well.
Eq. (14)
IDIODE(max) = IOUT(max) = 0.36A
Since IIN_AVE(max) occurs when D is at a maximum.
Eq. (15)
PDIODE(max) ≈ VDIODE × IDIODE_(max)
A SK35B is used in this example, it’s VDIODE is 0.5V
PDIODE(max) ≈ 0.5V × 0.36A = 0.18W
MIC3223 Power Losses
To find the power losses in the MIC3223:
There is about 6mA input from VIN into the VDD pin.
The internal power switch has an RDSON of about 170mΩ
at.
PMIC3223 = VIN × 6mA + PwrFET
Eq. (16)
PwrFET = IFET_RMS(max)2 × Rds_on_@100°
+ VOUT(max) × IIN_AVE(max) × tsw × Fsw
Rds_on_@100° ≈ 160mΩ
tsw ≈ 30ns is the internal Power FET ON an OFF
transition time.
2
⎛
IL_PP
2
ISWRMS(max) = D⎜ IIN_AVE(max) +
⎜
12
⎝
⎞
⎟ = 1.3A
⎟
⎠
PwrFET = 1.3A2 × 160mΩ + 28V × 1.54A × 30ns
× 1MHz = 1.6W
PMIC3223 = 8 × 6mA + 1.77W = 1.66W
Snubber
A snubber is a damping resistor in series with a DC
blocking capacitor in parallel with the power switch (same
as across the flyback diode because VOUT is an ac
ground). When the power switch turns off, the drain to
source capacitance and parasitic inductance will cause a
high frequency ringing at the switch node. A snubber
circuit as shown in the application schematic may be
required if ringing is present at the switch node. A critically
damped circuit at the switch node is where R equals the
characteristic impedance of the switch node.
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M9999-011510-A
Micrel, Inc.
MIC3223
Eq.(17)
R
snubber
=
Lparisitic
Cds
The explanation of the method to find the best R snubber
is beyond the scope of this data sheet.
Use Rsnubber = 2Ω, ½ watt and Csnubber = 470pf to 1000pf.
The power dissipation in the Rsnubber is:
Rsnubber = Csnubber × VOUT2 × FSW
Psnubber = 470pF × 28V2 × 1MHz = 0.4W
Figure 10. Simplified Control Loop
Eq. (19)
Where
T(s) = Gea(s) × Gvc(s) × H(s)
For a LED driver H(s) =
Power Loss in the L
0.123 W
Power Loss in the sckottky diode
0.2 W
Psnubber
0.4 W
MIC3223 Power Loss
1.66 W
Total Losses
2.4W
Efficiency
80%
⎛
⎛
1
Gea (s) = gm ⎜ Z O || ⎜ R comp +
⎜
⎜
sCcomp
⎝
⎝
G VC (s) =
Eq. (18)
R OVP_L
Compensation
Figure 9. Current Mode Loop Diagram
Current mode control simplifies the compensation. In
current mode, the complex poles created by the output L
and C are reduced to a single pole. The explanation for
this is beyond the scope of this datasheet, but it’s
generally thought to be because the inductor becomes a
constant current source and can’t act to change phase.
From the small signal block diagram the loop transfer
function is:
Where
VOUT
Is the DC operating point of the converter.
ILED
Rdymanic is the ac load the converter sees. When the load
on the converter is a string of LEDs, Rdymanic is the series
sum of the RLED(ac) of each LED.
RLED_total is usually between 0.1Ω to 1Ω per LED. It can be
calculated from the slope of ILED vs. Vf plot of the LED.
Ri = Ai × Rcs = 0.86Ω
Ai = 114 and Rcs ≡ 7.5mΩ; are internal to the ic.
The equation for Gvc(s) is theoretical and should give a
good idea of where the poles and zeros are located.
R OP =
Eq.(20) shows that s =
D'2 R dynamic
→ fRHPZ =
D'2 R dynamic
L
2πL
is a RHP Zero. The loop bandwidth should be about 1/5 to
1/10 of the frequency of RHPZ to ensure stability. From
Equation (20) it is shown that there is only the single pole.
1
1
→ fpole =
and a Zero
s=
R dynamic COUT
2πR dynamic COUT
due to the ESR of the output capacitor.
s=
January 2010
VOUT (s)
VCONTROL (s)
⎛
⎞
sL
⎜1 −
⎟(1 + sC
OUTRESR )
2
⎜
⎟
⎛ 1 ⎞⎛ D' R OP ⎞ ⎝ D' R dynamic ⎠
= ⎜ ⎟⎜
⎟
⎛ sR dynamic COUT ⎞
⎝ Ri ⎠⎝ 2 ⎠
⎟
⎜1 +
⎟
⎜
2
⎠
⎝
Table 2 showing the Power losses in the Design Example.
100kΩ × 1.245
= 4.33kΩ
=
30 − 1.245
⎞⎞
⎟⎟
⎟⎟
⎠⎠
Eq. (20)
Table 2. Major Power Losses
OVP - Over Voltage Protection
Set OVP higher than the maximum output voltage by at
least one Volt. To find the resistor divider values for OVP
use equation 18 and set the OVP = 30V and ROVP_H =
100kΩ:
R ADJ
and
R ADJ + R dynamic
17
1
1
→ fESR =
RESR COUT
2πRESR COUT
M9999-011510-A
Micrel, Inc.
This greatly simplifies the compensation.
One needs only to get a bode plot of the transfer function
of the control to output Gvc(s) with a network analyzer
and/or calculate it. From the bode plot find what the gain of
R
Gvc(s) is at f = HPZ . Next design the error amp gain
10
Gea(s) so the loop gain at the cross over frequency T(fco) is
R
0 db where fco = HPZ or less.
10
MIC3223
The error amp is a gm type and the gain Gea(s) is
⎛
⎛
1
Gea (s) = gm ⎜ Z O || ⎜ R comp +
⎜
⎜
sC
comp
⎝
⎝
Eq. (21)
gm =
⎞⎞
⎟⎟
⎟⎟
⎠⎠
0.8mA
and Zo = 1.2MΩ.
V
The zero is fzero =
Error Amp
f
1
R
= co = HPZ .
2R compCcomp 10
100
Error Amp Gain and Phase
60
Gain
GAIN (dB) / PHASE (°)
40
20
0
-20
Phase
-40
-60
-80
1.E+02
1.E+03
1.E+04
1.E+05
1.E+06
FREQUENCY (Hz)
Figure 11. Internal Error Amp and External Compensation
Set the fco at the mid band where Gea(fco) = gm × Rcomp. At
fzero × 10 the phase boost is near its maximum.
Figure 12. Error Amp Transfer Function
January 2010
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M9999-011510-A
Micrel, Inc.
MIC3223
Other Applications
Figure 13. MIC3223 Typical Application without External PWM Dimming Switch
2. Even though the RRC is very short (tens of
nanoseconds) the peak currents are high (multiple
amperes). These fast current spikes generate EMI
(electromagnetic interference). The amount of RRC
is related to the die size and internal capacitance of
the diode. It is important not to oversize (i.e. not
more than the usual de rating) the diode because
the RRC will be needlessly higher. Example: If a 2A
diode is needed do not use a higher current rated
diode because the RRC will be needlessly higher. If
a 25V diode is needed do not use a 100V etc.
3. The high RRC causes a voltage drop on the ground
trace of the PCB and if the converter control IC is
referenced to this voltage drop, the output regulation
will suffer.
4. For good output regulation, it is important to connect
the IC’s reference to the same point as the output
capacitors to avoid the voltage drop caused by RRC.
This is also called a star connection or single point
grounding.
5. Feedback trace: The high impedance traces of the
FB should be short.
Audio noise
Audio noise from the output capacitors may exits in a
standard boost LED converter. The physical dimensions
of ceramic capacitors change with the voltage applied to
them. During PWM Dimming, the output capacitors in
standard converters are subjected to fast voltage and
current transients that may cause the output capacitors
to oscillate at the PWM Dimming frequency. This is one
reason users may want PWM dimming frequencies
above the audio range.
PCB Layout
1. All typologies of DC-to-DC converters have a
Reverse Recovery Current (RRC) of the flyback
or (freewheeling) diode. Even a Schottky diode,
which is advertised as having zero RRC, it really
is not zero. The RRC of the freewheeling diode
in a boost converter is even greater than in the
Buck converter. This is because the output
voltage is higher than the input voltage and the
diode has to charge up to –VOUT during each ontime pulse and then discharge to Vf during the
off-time.
January 2010
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M9999-011510-A
Micrel, Inc.
MIC3223
Evaluation Board Schematic
37V Max 1A LED Driver
January 2010
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M9999-011510-A
Micrel, Inc.
MIC3223
Bill of Materials
Item
Part Number
GRM319R61E475KA12D
C1
C2
C3, C7
C4, C6
C5
C8
Manufacturer
Description
Qty
(1)
muRata
C3216X7R1E475M
TDK(2)
12063D475KAT2A
AVX(3)
GRM188R71C273KA01D
muRata
GRM188R60J106ME47D
muRata
C1608X5R0J106K
TDK
08056D106MAT2A
AVX
12105C475KAZ2A
AVX
GRM32ER71H475KA88L
muRata
GRM188R71C473KA01D
muRata
0603YC473K4T2A
AVX
GRM188R72A102KA37D
muRata
SK35B
L1
MSD1260-223ML-LD
Coilcraft(6)
R1, R3
CRCW0603100KFKEA
R2
R4
1
Ceramic Capacitor, 0.027µF, 6.3V, Size 0603, X7R
1
Ceramic Capacitor, 10µF, 6.3V, Size 0603, X7R
2
Ceramic Capacitor, 4.7µF, 50V, Size 1210, X7R
2
Ceramic Capacitor, 0.047µF, 6.3V, Size 0603, X7R
1
Ceramic Capacitor, 1000pF, 100V Size 0603, X7R
(4)
D1
Ceramic Capacitor, 4.7µF, 25V, Size 1206, X7R
Schottky Diode, 3A, 50V (SMB)
1
Inductor, 22µH, 5A
1
Vishay Dale(4)
Resistor, 100k, 1%, Size 0603
2
CRCW0603549RFKEA
Vishay Dale
Resistor, 549Ω, 1%, Size 0603
1
CRCW06033K24FKEA
Vishay Dale
Resistor, 3.24k, 1%, Size 0603
1
R5
CRCW1206R560FKEA
Vishay Dale
Resistor, 0.56Ω, 1%, 1/2W, Size 1206
(for .35A LED current Change for different ILED)
1
R6
RMC 1/4 2 1% R
Stackpole Electronics,
Inc.(7)
Resistor, 2Ω, 1%, 1/2W, Size 1210
1
Si2318DS
Vishay Siliconix(4)
N-Channel 40V MOSFET
1
High Power Boost LED Driver with Integrated FET
1
Q1
U1
MCC
(8)
AM2340N
Analog Power
MIC3223
Micrel, Inc.(9)
Notes:
1. Murata: www.murata.com.
2. TDK: www.tdk.com.
3. AVX: www.avx.com.
4. Vishay: www.vishay.com.
5. Internacional Rectifier: www.ift.com.
6. Coilcraft: www.coilcraft.com
7. Stackpole Electronics, Inc.: www.
8. Analog Power: www.analogpowerinc.com
8. Micrel, Inc.: www.micrel.com.
January 2010
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M9999-011510-A
Micrel, Inc.
MIC3223
PCB Layout Recommendations
Top Layer
Bottom Layer
January 2010
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Micrel, Inc.
MIC3223
Package Information
16-Pin ePad TSSOP (TSE)
January 2010
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M9999-011510-A
Micrel, Inc.
MIC3223
Recommended Land Pattern
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.
January 2010
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M9999-011510-A