AOSMD AOZ1083

AOZ1083
1.2 A Buck LED Driver
General Description
Features
The AOZ1083 is a high efficiency, simple to use,
1.2 A buck HB LED driver optimized for general lighting
applications. The AOZ1083 operates from a 3 V to 26 V
input voltage range and provides up to 1.2 A of
continuous LED current. The 280 mV LED current
feedback voltage minimizes the power dissipation of the
external sense resistor. The fixed switching frequency of
1.5 MHz PWM operation reduces inductor and capacitor
sizes.
z Up to 26 V operating input voltage range
z 240 mΩ internal NMOS
z Up to 95 % efficiency
z Internal compensation
z 1.2 A continuous output current
z Fixed 1.5 MHz PWM operation
z Internal soft start
z 280 mV LED current feedback voltage with ±5 %
accuracy
The AOZ1083 is available in a tiny SOT23-6L package.
z Cycle-by-cycle current limit
z Short-circuit protection
z Thermal shutdown
z Small size SOT23-6L
Applications
z Point of load DC/DC conversion
z Set top boxes
z DVD drives and HDD
z LCD Monitors & TVs
z Cable modems
z Telecom/Networking/Datacom equipment
Typical Application
VIN
C3
C1
4.7µF
VIN
DIM
BS
AOZ1083
L1
2.2µH
VOUT
LX
LED1
C2
10µF
FB
GND
RS
Figure 1. 1.2 A Buck HB LED Driver
Rev. 1.0 July 2011
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Page 1 of 12
AOZ1083
Ordering Information
Part Number
Ambient Temperature Range
Package
Environmental
AOZ1083CI
-40 °C to +85 °C
SOT23-6L
Green Product
AOS Green Products use reduced levels of Halogens, and are also RoHS compliant.
Please visit www.aosmd.com/web/quality/rohs_compliant.jsp for additional information.
Pin Configuration
BST
1
6
LX
GND
2
5
VIN
FB
3
4
DIM
SOT23-6L
(Top View)
Pin Description
Pin Number
Pin Name
1
BST
Bootstrap voltage input. High side driver supply. Connected to 10 nF capacitor between
BST and LX.
2
GND
Ground.
3
FB
4
DIM
PWM dimming pin. This pin is active high.
5
VIN
Supply voltage input. Input range from 3 V to 26 V. When VIN rises above the UVLO
threshold the device starts up.
6
LX
PWM output connection to inductor.
Rev. 1.0 July 2011
Pin Function
LED current feedback. The FB pin regulation voltage is 280 mV. Connect an external
sense resistor between the cathode of the LED string and GND to set LED current.
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Page 2 of 12
AOZ1083
Absolute Maximum Ratings
Recommended Operating Conditions
Exceeding the Absolute Maximum Ratings may damage the
device.
The device is not guaranteed to operate beyond the
Recommended Operating Conditions.
Parameter
Rating
Supply Voltage (VVIN)
LX to GND
Parameter
30 V
Supply Voltage (VVIN)
3.0 V to 26 V
-0.7 V to VVIN+ 2 V
Output Voltage Range
Up to 0.85 x VVIN
Ambient Temperature (TA)
-40 °C to +85 °C
DIM to GND
-0.3 V to 26 V
FB to GND
-0.3 V to 6 V
Package Thermal Resistance (ΘJA)
SOT23-6L(2)
VLX + 6 V
BST to AGND
Junction Temperature (TJ)
+150 °C
Storage Temperature (TS)
-65 °C to +150 °C
ESD Rating
Rating
(1)
2 kV
220 °C/W
Note:
2. The value of ΘJA is measured with the device mounted on a 1-in2
FR-4 board with 2 oz. Copper, in a still air environment with
TA = 25 °C. The value in any given application depends on the
user’s specific board design.
Note:
1. Devices are inherently ESD sensitive, handling precautions are
required. Human body model rating: 1.5 kΩ in series with 100 pF.
Electrical Characteristics
TA = 25 °C, VVIN = VDIM = 12 V. Specifications in BOLD indicate a temperature range of -40 °C to +85 °C. These specifications are
guaranteed by design.
Symbol
VVIN
VUVLO
Parameter
Conditions
Supply Voltage
Input Under-Voltage Lockout Threshold
Min.
3
VVIN Rising
VVIN Falling
IVIN
Supply Current (Quiescent)
IOUT = 0, VFB = 1 V, VDIM > 1.2 V
Shutdown Supply Current
VDIM = 0 V
VFB
Feedback Voltage
TA = 25 ºC
IFB
Units
26
V
2.9
V
V
200
IOFF
VFB_LINE
Max.
2.3
UVLO Hysteresis
VFB_LOAD Load Regulation
Typ.
1
266
280
mV
1.5
mA
8
μA
294
mV
120 mA < Load < 1.08 A
0.5
%
Line Regulation
Load = 600 mA
0.03
%/V
Feedback Voltage Input Current
VFB = 280 mV
500
nA
PWM DIMMING
VDim_OFF Dimming Input Threshold
VDim_ON
Off Threshold
On Threshold
0.4
1.2
VDim_HYS Dimming Input Hysteresis
IDIM
200
Dimming Input Current
V
V
mV
3
μA
1.8
MHz
MODULATOR
fO
DMAX
TON_MIN
ILIM
Frequency
Maximum Duty Cycle
1.5
87
Minimum On Time
%
100
Current Limit
Over-Temperature Shutdown Limit
TSS
1.2
1.5
1.9
ns
2.3
A
150
110
°C
°C
400
μs
VIN = 12 V
240
mΩ
380
TJ Rising
TJ Falling
Soft Start Interval
POWER STATE OUTPUT
RDS(ON)
NMOS On-Resistance
RDS(ON)
NMOS On-Resistance
VIN = 3.3 V
ILEAKAGE
NMOS Leakage
VDIM = 0 V, VLX = 0 V
Rev. 1.0 July 2011
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mΩ
10
μA
Page 3 of 12
AOZ1083
Block Diagram
VIN
Low Voltage
Regulator
OTP
Detect
Current
Sense
DIM
DIM
Detection
BST
LDO
BST
Softstart
OSC
FB
CLK
–
PWM
Logic
+
0.28V
+
–
Error
Amplifier
Driver
LX
PWM
Comparator
OC
Detect
GND
Rev. 1.0 July 2011
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Page 4 of 12
AOZ1083
Typical Performance Characteristics
Circuit of Figure 1. VVIN = 12 V, Load = 1 W White LED unless otherwise specified.
Steady State Test
Dimming Startup Test
VDIM
5V/div
Vo ripple
50mV/div
Vlx
10V/div
Vlx
10V/div
Ilx
500mA/div
Iled
200mA/div
500ns/div
500μs/div
Dimming Shutdown Test
LED Short Test
VDIM
5V/div
Vlx
10V/div
Vlx
10V/div
Ilx
500mA/div
Iled
200mA/div
5ms/div
5μs/div
LED Short Protection
LED Short Recovery
Vlx
10V/div
Vlx
10V/div
Vo
2V/div
Vo
2V/div
Iled
1A/div
Iled
200mA/div
50μs/div
Rev. 1.0 July 2011
500μs/div
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Page 5 of 12
AOZ1083
Detailed Description
The AOZ1083 is a high efficiency, simple to use, 1.2 A
buck HB LED driver optimized for general lighting
applications. Features include enable control, under
voltage lock-out, internal soft-start, output over-voltage
protection, over-current protection and thermal shut
down.
The AOZ1083 is available in a SOT23-6L package.
Soft Start and PWM Dimming
LED Current Programming
LED current can be set by feeding back the output to the
FB pin with the sense resistor RS shown in Figure 1.
The LED current can be programmed as:
0.28
I LED = ----------RS
Protection Features
The AOZ1083 has an internal soft start feature to limit
in-rush current and ensure the output voltage ramps up
smoothly to regulation voltage. A soft start process
begins when the input voltage rises to a voltage higher
than UVLO and the voltage on the Dim pin is HIGH.
In the soft start process, the output voltage is typically
ramped to regulation voltage in 400 μs. The 400 μs soft
start time is set internally.
The DIM pin of the AOZ1083 is active high. Connect the
DIM pin to VIN if the enable function is not used. Pulling
DIM to ground will disable the AOZ1083. Do not leave it
open. The voltage on the DIM pin must be above 1.2 V to
enable the AOZ1083. When voltage on the DIM pin falls
below 0.4 V, the AOZ1083 is disabled.
Steady-State Operation
Under steady-state conditions, the converter operates in
fixed frequency and Continuous-Conduction Mode
(CCM).
The AOZ1083 integrates an internal NMOS as the
high-side switch. Inductor current is sensed by amplifying
the voltage drop across the drain to source of the high
side power MOSFET. Output voltage is divided down by
the external voltage divider at the FB pin. The difference
of the FB pin voltage and reference voltage is amplified
by the internal transconductance error amplifier. The
error voltage is compared against the current signal,
which is the sum of inductor current signal and ramp
compensation signal, at the PWM comparator input.
If the current signal is less than the error voltage, the
internal high-side switch is on. The inductor current flows
from the input through the inductor to the output. When
the current signal exceeds the error voltage, the
high-side switch is off. The inductor current is
freewheeling through the external Schottky diode to
output.
Switching Frequency
The AOZ1083 has multiple protection features to prevent
system circuit damage under abnormal conditions.
Over Current Protection (OCP)
The sensed inductor current signal is also used for over
current protection.
The cycle-by-cycle current limit threshold is set at 2 A.
When the load current reaches the current limit
threshold, the cycle-by-cycle current limit circuit
immediately turns off the high side switch to terminate the
current duty cycle. The inductor current stops rising. The
cycle-by-cycle current limit protection directly limits
inductor peak current. The average inductor current is
also limited due to the limitation on peak inductor current.
When cycle-by-cycle current limit circuit is triggered, the
output voltage drops as the duty cycle decreases.
The AOZ1083 has an internal short circuit protection to
protect itself from catastrophic failure under output short
circuit conditions. As a result, the converter is shut down
and hiccups. The converter will start up via a soft start
once the short circuit condition is resolved. In short circuit
protection mode, the inductor average current is greatly
reduced.
UVLO
An UVLO circuit monitors the input voltage. When the
input voltage exceeds 2.9 V, the converter starts
operation. When the input voltage falls below 2.3 V, the
converter will stop switching.
Thermal Protection
An internal temperature sensor monitors the junction
temperature. It shuts down the internal control circuit and
high side NMOS if the junction temperature exceeds
150º C. The regulator will restart automatically under the
control of the soft-start circuit when the junction
temperature decreases to 100 °C.
The AOZ1083 switching frequency is fixed and set by an
internal oscillator. The switching frequency is set
internally 1.5 MHz.
Rev. 1.0 July 2011
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Page 6 of 12
AOZ1083
Application Information
The basic AOZ1083 application circuit is shown in
Figure 1. Component selection is explained below.
Input Capacitor
The input capacitor must be connected to the VIN pin
and PGND pin of the AOZ1083 to maintain steady input
voltage and filter out the pulsing input current. The
voltage rating of the input capacitor must be greater than
the maximum input voltage plus ripple voltage.
The input ripple voltage can be approximated by
equation below::
IO
VO ⎞ VO
⎛
ΔV IN = ----------------- × ⎜ 1 – --------⎟ × --------f × C IN ⎝
V IN⎠ V IN
Inductor
Since the input current is discontinuous in a buck
converter, the current stress on the input capacitor is
another concern when selecting the capacitor. For a buck
circuit, the RMS value of the input capacitor current can
be calculated by:
VO ⎛
VO ⎞
- ⎜ 1 – -------I CIN_RMS = I O × --------⎟
V IN ⎝
V IN⎠
The inductor is used to supply constant current to output
when it is driven by a switching voltage. For a given input
and output voltage, inductance and switching frequency
together decide the inductor ripple current, which is:
VO ⎛
VO ⎞
ΔI L = ----------- × ⎜ 1 – --------⎟
f×L ⎝
V ⎠
IN
The peak inductor current is:
ΔI
I Lpeak = I O + -------L2
if we let m equal the conversion ratio:
VO
-------- = m
V IN
The relationship between the input capacitor RMS
current and voltage conversion ratio is calculated and
shown in Figure 2. It can be seen that when VO is half of
VIN, CIN is under the worst current stress. The worst
current stress on CIN is at 0.5 x IO.
0.5
High inductance provides low inductor ripple current but
requires a larger size inductor to avoid saturation. Low
ripple current reduces inductor core losses. It also
reduces RMS current through inductor and switches,
which results in less conduction loss.
When selecting the inductor, confirm it is able to handle
the peak current without saturation even at the highest
operating temperature.
The inductor takes the highest current in a buck circuit.
The conduction loss on inductor needs to be checked for
thermal and efficiency requirements.
0.4
ICIN_RMS(m) 0.3
IO
0.2
Surface mount inductors in different shape and styles are
available from Coilcraft, Elytone and Murata. Shielded
inductors are small and radiate less EMI noise but cost
more than unshielded inductors. The choice depends on
EMI requirement, price and size.
0.1
0
For reliable operation and best performance, the input
capacitors must have current rating higher than ICIN_RMS
at the worst operating conditions. Ceramic capacitors are
preferred for input capacitors because of their low ESR
and high ripple current rating. Depending on the
application circuits, other low ESR tantalum capacitor or
aluminum electrolytic capacitor may also be used. When
selecting ceramic capacitors, X5R or X7R type dielectric
ceramic capacitors are preferred for their better
temperature and voltage characteristics. Note that the
ripple current rating from capacitor manufacturers are
based on a certain life time. Further de-rating may need
to be considered for long term reliability.
0
0.5
m
Figure 2. ICIN vs. Voltage Conversion Ratio
Rev. 1.0 July 2011
1
Output Capacitor
The output capacitor is selected based on the DC output
voltage rating, output ripple voltage specification and
ripple current rating.
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Page 7 of 12
AOZ1083
The selected output capacitor must have a higher rated
voltage specification than the maximum desired output
voltage including ripple. De-rating needs to be
considered for long term reliability.
Output ripple voltage specification is another important
factor for selecting the output capacitor. In a buck
converter circuit, output ripple voltage is determined by
inductor value, switching frequency, output capacitor
value and ESR. It can be calculated by the equation
below:
1
ΔV O = ΔI L × ⎛ ESR CO + -------------------------⎞
⎝
8×f×C ⎠
O
where,
CO is output capacitor value, and
ESRCO is the equivalent series resistance of the output
capacitor.
When a low ESR ceramic capacitor is used as the output
capacitor, the impedance of the capacitor at the switching
frequency dominates. Output ripple is mainly caused by
capacitor value and inductor ripple current. The output
ripple voltage calculation can be simplified to:
1
ΔV O = ΔI L × ------------------------8×f×C
O
If the impedance of ESR at switching frequency
dominates, the output ripple voltage is mainly decided by
the capacitor ESR and inductor ripple current. The output
ripple voltage calculation can be further simplified to:
ΔV O = ΔI L × ESR CO
Schottky Diode Selection
The external freewheeling diode supplies the current to
the inductor when the high side NMOS switch is off. To
reduce the losses due to the forward voltage drop and
recovery of diode, Schottky diode is recommended to
use. The maximum reverse voltage rating of the chosen
Schottky diode should be greater than the maximum
input voltage, and the current rating should be greater
than the maximum load current.
Thermal Management and Layout
Considerations
In the AOZ1083 buck regulator circuit, high pulsing
current flows through two circuit loops. The first loop
starts from the input capacitors, to the VIN pin, to the
LX pin, to the filter inductor, to the output capacitor and
load, and then returns to the input capacitor through
ground. Current flows in the first loop when the high side
switch is on. The second loop starts from the inductor,
to the output capacitor and load, to the anode of Schottky
diode, to the cathode of Schottky diode. Current flows in
the second loop when the low side diode is on.
In PCB layout, minimizing the area of the two loops
reduces the noise of the circuit and improves efficiency.
A ground plane is strongly recommended to connect
input capacitor, output capacitor, and PGND pin of the
AOZ1083.
In the AOZ1083 buck regulator circuit, the major power
dissipating components are the AOZ1083, the Schottky
diode and output inductor. The total power dissipation of
the converter circuit can be measured by input power
minus output power:
P total_loss = ( V IN × I IN ) – ( V O × V IN )
For lower output ripple voltage across the entire
operating temperature range, X5R or X7R dielectric type
of ceramic, or other low ESR tantalum capacitors or
aluminum electrolytic capacitors may also be used as
output capacitors.
The power dissipation in the Schottky diode can be
approximated as:
In a buck converter, output capacitor current is
continuous. The RMS current of output capacitor is
decided by the peak to peak inductor ripple current. It can
be calculated by:
where,
ΔI L
I CO_RMS = ---------12
The power dissipation of the inductor can be
approximately calculated by output current and DCR of
the inductor.
Usually, the ripple current rating of the output capacitor is
a smaller issue because of the low current stress. When
the buck inductor is selected to be very small and
inductor ripple current is high, the output capacitor could
be overstressed.
Rev. 1.0 July 2011
P diode_loss = I O × ( 1 – D ) × V FW_Schottky
VFW_Schottky is the Schottky diode forward voltage drop.
P inductor_loss = IO2 × R inductor × 1.1
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Page 8 of 12
AOZ1083
The actual junction temperature can be calculated with
power dissipation in the AOZ1281 and thermal
impedance from junction to ambient.
Several layout tips are listed below for the best electric
and thermal performance.
1. The input capacitor should be connected as close as
possible to the VIN pin and the GND pin.
T junction
= ( P total_loss – P diode_loss – P inductor_loss ) × Θ JA
+ T amb
2. The inductor should be placed as close as possible
to the LX pin and the output capacitor.
The maximum junction temperature of AOZ1083 is
150 ºC, which limits the maximum load current capability.
3. Keep the connection of schottky diode between the
LX pin and the GND pin as short and wide as
possible.
The thermal performance of the AOZ1083 is strongly
affected by the PCB layout. Care should be taken during
the design process to ensure that the IC will operate
under the recommended environmental conditions.
4. Place the feedback resistors and compensation
components as close to the chip as possible.
5. Keep sensitive signal traces away from the LX pin.
6. Pour a maximized copper area to the VIN pin, the
LX pin and especially the GND pin to help thermal
dissipation.
7. Pour copper plane on all unused board areas and
connect the plane to stable DC nodes, like VIN, GND
or VOUT.
Rev. 1.0 July 2011
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Page 9 of 12
AOZ1083
Package Dimensions, SOT23-6
Gauge Plane
D
e1
Seating Plane
0.25mm
c
L
E E1
θ1
e
b
A2
A
.010mm
A1
Dimensions in millimeters
RECOMMENDED LAND PATTERN
1.20
2.40
0.80
0.95
0.63
UNIT: mm
Symbols
A
A1
A2
b
c
D
E
E1
e
e1
L
Min.
0.90
0.00
0.70
0.30
0.08
2.70
2.50
1.50
Nom.
—
—
1.10
0.40
0.13
2.90
2.80
1.60
0.95 BSC
1.90 BSC
0.30
—
θ1
0°
—
Max.
1.25
0.15
1.20
0.50
0.20
3.10
3.10
1.70
Dimensions in inches
Min.
0.035
0.00
0.028
0.012
0.003
0.106
0.098
0.059
0.60
Symbols
A
A1
A2
b
c
D
E
E1
e
e1
L
Nom. Max.
—
0.049
—
0.006
0.043 0.047
0.016 0.020
0.005 0.008
0.114 0.122
0.110 0.122
0.063 0.067
0.037 BSC
0.075 BSC
0.012
—
0.024
8°
θ1
0°
—
8°
Notes:
1. Package body sizes exclude mold flash and gate burrs. Mold flash at the non-lead sides should be less than 5 mils each.
2. Dimension “L” is measured in gauge plane.
3. Tolerance ±0.100 mm (4 mil) unless otherwise specified.
4. Followed from JEDEC MO-178C & MO-193C.
5. Controlling dimension is millimeter. Converted inch dimensions are not necessarily exact.
Rev. 1.0 July 2011
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Page 10 of 12
AOZ1083
Tape and Reel Dimensions, SOT23-6
Tape
P1
D1
T
P2
E1
E2
E
B0
K0
D0
A0
P0
Feeding Direction
Unit: mm
Package
A0
B0
K0
D0
D1
E
E1
E2
P0
P1
P2
T
SOT-23
3.15
±0.10
3.27
±0.10
1.34
±0.10
1.10
±0.01
1.50
±0.10
8.00
±0.20
1.75
±0.10
3.50
±0.05
4.00
±0.10
4.00
±0.10
2.00
±0.10
0.25
±0.05
Reel
W1
S
G
N
M
K
V
R
H
W
Unit: mm
Tape Size
Reel Size
M
N
W
W1
8 mm
ø180
ø180.00
±0.50
ø60.50
Min.
9.00
±0.30
11.40
±1.0
H
K
S
ø13.00
10.60 2.00
+0.50 / -0.20
±0.50
G
ø9.00
R
V
5.00 18.00
Leader/Trailer and Orientation
Trailer Tape
300mm min. or
75 Empty Pockets
Rev. 1.0 July 2011
Components Tape
Orientation in Pocket
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Leader Tape
500mm min. or
125 Empty Pockets
Page 11 of 12
AOZ1083
Part Marking
AOZ1083CI
BA 2D
11
(SOT23-6)
Assembly Lot Code
Week & Year Code
Part Number Code
Assembly Location Code
This data sheet contains preliminary data; supplementary data may be published at a later date.
Alpha & Omega Semiconductor reserves the right to make changes at any time without notice.
LIFE SUPPORT POLICY
ALPHA & OMEGA SEMICONDUCTOR PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL
COMPONENTS IN LIFE SUPPORT DEVICES OR SYSTEMS.
As used herein:
1. Life support devices or systems are devices or
systems which, (a) are intended for surgical implant into
the body or (b) support or sustain life, and (c) whose
failure to perform when properly used in accordance
with instructions for use provided in the labeling, can be
reasonably expected to result in a significant injury of
the user.
Rev. 1.0 July 2011
2. A critical component in any component of a life
support, device, or system whose failure to perform can
be reasonably expected to cause the failure of the life
support device or system, or to affect its safety or
effectiveness.
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