AOSMD AOZ1977-1

AOZ1977-1
High Voltage LED Driver IC
General Description
Features
The AOZ1977-1 is a high-efficiency LED driver
controller for high voltage LED backlighting
applications. It is designed to drive high-brightness
LED light bar in LED TV applications. The AOZ1977-1
can support a wide range of input and output
voltages. The input bias voltage of AOZ1977-1 is
from 8V to 30V.
•
•
The AOZ1977-1 has multiple features to protect the
regulator under fault conditions. A control pin can
disable an external switch to disconnect the LEDs
current path from the output in PWM dimming or
under catastrophic failure conditions. Cycle-by-cycle
current protection limits the peak inductor current.
Thermal shutdown provides another level of
protection.
Low feedback voltage (500mV) helps reduce power
loss.
The AOZ1977-1 features sync function to allow for
synchronization with external clock or multiple
AOZ1977-1.
The AOZ1977-1 is available in a standard SO-16
package and operates over the temperature range of
-40°C to +85°.
•
•
•
•
•
•
•
•
•
•
8V to 30V input bias voltage
Up to 16V driving capability at GATE pin and
DPWM pin.
Disconnect control pin for PWM dimming or fault
conditions.
Bi-directional Clock synchronization
500mV feedback regulation
Feedback short protection
8 bit PWM dimming resolution
Cycle-by-cycle current limit
Output over-voltage protection
LED short and open protection
Thermal shutdown protection
SO-16 package
Applications
•
•
•
LCD TV LED backlight
LED monitor
General LED lighting
Typical Application
Rev. 1.0 November 2011
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Page 1 of 16
AOZ1977-1
Ordering Information
Part Number
Temperature Range
Package
Environmental
AOZ1977AI-1
-40°C to +85°C
SOIC-16
Green
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
VIN
1
16
FB
VDD
2
15
ISET
GATE
3
14
COMP
GND
4
13
DBRT
CS
5
12
OVP
TIMER
6
11
DPWM
OSC
7
10
VREF
SYNC
8
9
ILIM
SOIC-16
(Top View)
Pin Description
Part Number
Pin Name
1
2
VIN
VDD
3
4
5
6
7
8
GATE
GND
CS
TIMER
OSC
SYNC
9
10
11
ILIM
VREF
DPWM
12
OVP
13
DBRT
14
COMP
15
16
ISET
FB
Rev. 1.0 November 2011
Pin Function
Input Supply Pin.
Internal 8V Linear Regulator Output Pin for GATE Driver. Connect a minimum 0.22µF
ceramic capacitor from VDD to ground.
External Boost NMOS Gate Controller Pin. Connect to the gate of external NMOS switch.
Ground Pin.
NMOS Switch Current Sense Pin.
Sets feedback short protection blanking time at start up. Connect CTIMER to GND
Frequency Set Pin. Connect ROSC to ground via a resistor to set the switching frequency.
Frequency Synchronous Pin. Connect SYNC to external clock for desired switching
frequency or connect to multiple controllers for phase locked frequency synchronization.
Current limit Set Pin.
Reference Voltage.
Fault and Dimming control output Pin. DPWM=High for LED connect. DPWM=Low for LED
disconnect. Connect to the gate of external NMOS switch.
Over-Voltage Feedback Input Pin. Use a voltage divider to set the boost regulator output
over-voltage protection threshold.
PWM Brightness Control Input. DBRT controls the LED brightness by turning the LED on
and off using a PWM signal. The brightness is proportional to the PWM duty cycle.
Compensation Pin. COMP is the output of the internal error amplifier. For loop
compensation connect a RC network from COMP to ground.
LED Current Set Pin. Connect ISET to VREF resistor divider to set the LED current level.
Feedback Input Pin. Connect to sense resistor at LED string.
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Page 2 of 16
AOZ1977-1
Pin Functions
Pin1: VIN
This is the input power for the controller IC. If the input
of the boost converter is less than 30V, VIN can be
connected directly to the boost supply voltage. If the
boost supply voltage is higher than 30V, a separate
supply rail between 8V to 30V is required for the VIN
pin. It is recommended that an RC filter should be
added between VIN and boost supply voltage if they
are connected directly.
Please note that when VIN is not directly connected to
the boost supply voltage, proper power up sequence
will be required. Boost supply voltage must be ready
before powering up VIN. There is no power down
sequence required.
Pin2: VDD
This is the output of an internal 8V regulator. It
requires a 2.2µF decoupling capacitor to be
connected to ground. The internal regulator can be
over-driven by external supply between 8V to 16V if
higher gate drive is desired.
PIN3: GATE
This is the driver output for the gate of boost NMOS
switch. The GATE = high voltage is equal to VDD
voltage. It is recommended to add a 1Ω resistor
between this pin and the NMOS gate. The resistor
value can be optimized depending on the switching
frequency and selection of the NMOS switch.
PIN4: GND
This is the signal and power ground for the IC
controller. It is recommended that all the low current
paths are connected to this pin as close as possible to
the IC controller. It is not recommended to connect
any output or input filter capacitors and any current
sense resistors to this pin directly. The IC controller
ground should be an island around the IC connected
to the PWR GND at a single point in the layout.
PIN5: CS
This is the input for peak current sense. This pin
serves the functions of current feedback, peak current
limit detection, and fault current detection. The pin
current limit is set by the voltage defined at PIN9 ILIM.
The current limit is defined as voltage at ILIM divided
by the sense resistor connected from this pin to
ground.
Rev. 1.0 November 2011
If CS pin detect a fault current detection such as short
circuit condition, it will trigger a fault signal. The IC
controller will latch-off until VIN is toggled.
PIN6: TIMER
Startup-short protection timer. Connecting this pin to
GND via a capacitor, sets the time the controller
allows Feedback voltage to remain below 0.19V
during start up. If voltage at FB remains below 0.19V
after set time has expired, the controller will shut down
and latch off.
After the power-up sequence is completed, the TIMER
pin will have no effect. The controller will
instantaneously latch-off whenever feedback voltage
drops below 0.19V.
For most designs it is recommended to use no less
than 100nF capacitor.
TIMER = CTIMER / 1.25 µA
Note that DBRT must be applied before CTIMER times
out.
PIN7: ROSC
This is the pin to select the switching frequency for the
boost controller. A resistor should be connected
between this pin to ground. The switching frequency is
determined by the following equation:
FSW = 1/ (ROSC Ω × 10 pF )
It is recommended that the switching frequency for
normal operation should be between 50KHz to
350KHz.
Pin8: SYNC
This is a bidirectional pin for oscillator clock
synchronization. Clock synchronization will choose
either the internal clock or the external clock through
this pin, whichever is faster. The faster external clock
must be ready before power is applied to this IC
controller. If the internal clock is faster, the SYNC pin
will have the same frequency as the internal clock.
When multiple IC controllers are used in the design, it
is recommended to connect all SYNC pins together.
This will reduce the interference of “beat” frequencies
associated with multiple switching frequencies.
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Page 3 of 16
AOZ1977-1
PIN9: ILIM
This is the current limit set point. The voltage at this
pin will determine the CS current limit threshold
detected at PIN5 CS. The voltage can be derived from
a resistor divider from the 1.2V reference voltage at
Pin10 VREF. To minimize power consumption, it is
recommended that the total resistance for the divider
is approximately 20kΩ.
Pin10: VREF
This is a 1.2V voltage reference for all external bias.
This reference voltage can be used for Pin15 ISET
and Pin9 ILIM bias.
Pin11: DPWM
This is the driver output for the gate of the LED
current control NMOS switch. DPWM = low if PIN13
DBRT signal is low or fault condition is triggered. The
DPWM = high if PIN13 DBRT signal is high under
normal operation. The high voltage is equal to VDD
voltage. It is recommended to add a 1Ω resistor
between this pin and the NMOS gate. The resistor
value can be optimized depending on the switching
frequency and selection of the NMOS.
PIN12: OVP
This is the input for LED Over-Voltage Protection.
OVP monitors the LED output voltage through a
resistor divider. When the voltage at this pin is higher
than 1V, the controller will stop switching immediately
until VIN power is toggled.
Pin14: COMP
This is for feedback loop compensation. It is the
output of the error amplifier that controls PWM logic
for the boost controller. An RC network should be
used to generate the compensation for boost
feedback loop.
Pin15: ISET
This is for full scale LED current setting. A reference
voltage between 0.5V and 0.8V should be applied to
this pin. The voltage can be derived from a resistor
divider from the 1.2V reference voltage at Pin10
VREF. To minimize power consumption, it is
recommended that the total resistance for the divider
is approximately 20kΩ. The FB voltage will regulate to
this voltage level. The full scale LED current is derived
by the FB voltage divided by the Sense resistor.
Pin16: FB
This is the feedback input for boost controller. This pin
should connect to a resistor that senses the LED
current. The FB voltage will be regulated to ISET
voltage to determine the desired LED current when
LED current control NMOS switch is on.
If the FB voltage drops below 0.19V the controller
interprets this condition as either shorted FB sense
resistor or LED cathode shorted to GND or output
shorted to GND and will immediately shutdown and
latch off .
Pin13: DBRT
This is the input for digital brightness control. A PWM
logic signal is applied to this pin to vary the brightness
of the LED. The brightness of the LED is proportional
to the duty cycle of the PWM logic signal. The input
signal will control the output driver at DPWM pin. This
input pin cannot be left floating.
Power up sequencing is important. DBRT logic must
be HIGH before VIN is higher than UVLO threshold.
Rev. 1.0 November 2011
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Page 4 of 16
AOZ1977-1
Functional Block
Absolute Maximum Ratings
Recommended Operating Ratings
Exceeding the Absolute Maximum Ratings may damage the
device.
This device is not guaranteed to operate beyond the
Recommended Operating Ratings.
Parameter
VIN to GND
GATE, FAULTB to GND
VDD to GND
PWMDIM, OSC, ISET, COMP,
FB TIMER, SYNC, CS. ILIM,
VREF, OVP, to GND
Storage Temperature (TS)
(1)
ESD Rating
Parameter
Supply Voltage (VVIN)
Ambient Temperature (TA)
Package Thermal Resistance
SOIC-16 (ΘJA)
Rating
-0.3V to +32V
-0.3V to +16V
-0.3V to +16V
-0.3V to +6V
Rating
8V to 30V
-40°C to +85°C
105°C/W
-65°C to +150°C
2kV
Note:
1. Devices are inherently ESD sensitive, handling precautions are
required. Human body model rating: 1.5kΩ in series with 100pF.
Rev. 1.0 November 2011
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Page 5 of 16
AOZ1977-1
Electrical Characteristics
TA = 25°C, VIN = 24V unless otherwise specified.
Symbol
VVIN
IVIN_ON
VUVLO_RISE
VUVLO_FALL
VVIN_HYS
VVDD
Parameter
VIN Supply Voltage
VIN Quiescent Current
VIN UVLO Threshold
VIN UVLO Hysteresis
VDD Regulation Voltage
Conditions
Min.
Typ.
8
Not Switching
VIN rising
VIN falling
6.2
8.5V < VVIN < 30V
7.5
ROSC = 1MΩ
ROSC = 285kΩ
ROSC = 1MΩ
85
298
GATE = 0V. VDD = 8V
GATE = 8V. VDD = 8V
CGATE = 1nF. VDD = 8V
10% to 90% of VDD
CGATE = 1nF. VDD = 8V
90% to 10% of VDD
200
400
Max
Units
30
2
V
mA
7
6.5
500
8
7.3
V
8.5
mV
V
100
350
150
115
402
200
Oscillator
FSW
Switching Frequency
TON
Minimum ON Time (PWM)
kHz
ns
GATE Driver
IGATE_SOURCE
IGATE_SINK
Source Current
Sink Current
TGATE_RISE
Rise Time
TGATE_FALL
Fall Time
250
450
mA
mA
50
85
ns
25
45
ns
5
5
5
5
5
5
2000
µA
µA
µA
µA
µA
µA
Hz
200
1.212
µA
V
140
1.1
% of VCS
Inputs
ICS
IISET
IILIM
IDBRT
IOVP
IFB
FDBRT
CS Input Current
ISET Input Current
ILIM Input Current
DBRT Input Current
OVP Input Current
FB Input Current
DBRT Dimming Frequency
CS = 0.3V
ISET = 0.5V
ILIM = 0.4V (140% of CS)
DBRT = 5V
OVP = 1.2V
FB = 0.5V
PWM minimum ON time >9µs
VREF Output Source Current
VREF Reference Voltage
RVREF = 6kΩ to GND
RVREF = 6kΩ to GND
Current Limit Set
OVP Threshold Voltage
OVP Hysteresis
TIMER Charge Current
Thermal Shutdown Threshold
Thermal Shutdown Hysteresis
CS = 0.3V
DPWM Source current
DPWM Sink current
GATE = 0V
GATE = 8V
100
Outputs
IVREF
VVREF
1.188
1.2
126
0.9
133
1
200
1.25
145
35
Protection
VILIM
VOVP
VOVP_HYS
ITIMER
TTHERMAL_SD
TTHERMAL_HYS
V
mV
µA
°C
°C
DPWM Drive
IDPWM_SOURCE
IDPWM_SINK
36
46
mA
mA
2.0
V
V
Logic Input
VDBRT_HI
VDBRT_LO
DBRT Logic High
DBRT Logic Low
Rev. 1.0 November 2011
0.8
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Page 6 of 16
AOZ1977-1
Typical Performance Characteristics
Switching Waveforms of Gate, Inductor Current and LX Voltage: VLED = 200V, ILED = 200mA
PVIN = 90V
PVIN = 100V
GATE
(10V/div)
GATE
(10V/div)
Inductor
Current
(0.5A/div)
Inductor
Current
(0.5A/div)
LX
Voltage
(100V/div)
LX
Voltage
(100V/div)
5µs/div
5µs/div
PVIN = 120V
PVIN = 150V
GATE
(10V/div)
GATE
(10V/div)
Inductor
Current
(0.5A/div)
Inductor
Current
(0.5A/div)
LX
Voltage
(100V/div)
LX
Voltage
(100V/div)
5µs/div
5µs/div
Rev. 1.0 November 2011
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Page 7 of 16
AOZ1977-1
PWM Dim Waveforms: VIN = 100V, 200V LED / 200mA, DBRT = 400Hz
DBRT = 10%
DBRT = 50%
LED
Voltage
(50V/div)
LED
Voltage
(50V/div)
LED
Current
(0.2A/div)
LED
Current
(0.2A/div)
DBRT
(2V/div)
DBRT
(2V/div)
1ms/div
1ms/div
DBRT = 90%
Zoomed DBRT = 0.5%
LED
Voltage
(50V/div)
LED
Voltage
(50V/div)
LED
Current
(0.2A/div)
LED
Current
(0.2A/div)
DBRT
(2V/div)
DBRT
(2V/div)
2µs/div
1ms/div
Rev. 1.0 November 2011
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Page 8 of 16
AOZ1977-1
Additional Waveforms
PVIN = 100V, VLED = 200V, ILED = 200mA, FSW = 100kHz
Feedback Short Protection
During Steady State
Feedback Short Protection
During Start-Up
Feedback
Voltage
(0.5Vdiv)
Feedback
Voltage
(0.5Vdiv)
LX Voltage
(100/div)
LX Voltage
(100/div)
LED Voltage
(100V/div)
LED Voltage
(100V/div)
LED
Current
(200mA/div)
LED
Current
(200mA/div)
1ms/div
50ms/div
Partial LED String Short Protection
OVP Protection
LED Voltage
(50V/div)
Feedback
Voltage
(1Vdiv)
LX Voltage
(100/div)
LX Voltage
(100/div)
LED
Current
(100mA/div)
1ms/div
Rev. 1.0 November 2011
LED
Current
(100mA/div)
100µs/div
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Page 9 of 16
AOZ1977-1
Detailed Description
The AOZ1977-1 is a boost DC/DC controller designed
to power a series of LEDs by regulating the current
into an LED string. The LED current information is
provided to the system through the sense resistor
RFB at the bottom of LED string, between FB and
GND pins.
Protection Features
Over-Current Protection at Boost Switch
The current limit is a function of RS resistor value at
CS pin and the voltage setting at ILIM pin. The voltage
at ILIM is directly compared to the sense voltage at
CS pin. When CS voltage reaches ILIM set voltage,
current limit protection triggers and the boost switch
will be turned off immediately until the next clock
cycle. To make sure that current limit protection does
not affect the normal operation, the current limit
should be set at least 30% higher than the inductor
peak current. However, the voltage at ILIM must be
less than 0.4V. When CS voltage is higher than 0.4V,
fault detection is active and it might affect the normal
operation. ILIM voltage is generated by connecting a
resistor divider (RL1 and RL2 in typical application
diagram) from 1.2V VREF pin to ILIM and GND pins.
To minimize power consumption, it is recommended
that the total resistance for the divider is
approximately 20kΩ.
LED Short Protection
When FB voltage exceeds 1V, the system will
consider some or all LEDs are shorted
instantaneously. Under this condition, the controller
will latch off until VIN is recycled.
LED Open Protection
When all LEDs are open, the system will respond by
boosting the output voltage. Once the output voltage
reaches the OVP threshold, OVP protection will
trigger, controller will latch off until VIN is recycled.
Feedback short
AOZ1977-1 also protects against shorted feedback
sense resistor or LED cathode shorted to GND. The
controller will latch off when feedback voltage drops to
0.19V or below.
Thermal Protection
An internal temperature sensor monitors the junction
temperature. It shuts down the internal control circuit
and all drivers if the junction temperature exceeds
145ºC.
For example:
If peak current is 0.55A.
30% higher is 0.72A.
CS voltage is 0.72A * 0.55Ω = 0.4V.
Over-Voltage Protection at Output
Over-voltage protection is monitoring the LED output
voltage through a resistor divider (Rov1 and Rov2 in
Typical Application Circuit) from VOUT to OVP and
GND pins. When the voltage at this pin is higher than
1V, the controller will stop switching immediately and
will latch off until VIN is recycled.
Rev. 1.0 November 2011
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Page 10 of 16
AOZ1977-1
Application Information
Inductor Selection
Inductor choice will be affected by many parameters,
like duty cycle based on input/output setting, switching
frequency, full scale LED current level, and mode of
operations. Boost controller can operate under
discontinuous mode, continuous mode, or critical
conduction mode. For high voltage boost LED driver
applications, it is recommended to use critical
conduction mode for good stability and best efficiency.
effect, it is always preferable to use shielded type
inductors.
Diode Selection
It is recommended to use fast recovery diode for D1.
For most applications, Schottky diodes with correct
current and voltage rating are suitable. The diode
current rating should be at least higher than the full
scale LED current. The diode voltage rating should be
higher than the OVP level of VOUT voltage.
ILPEAK
Inductor Current in Critical Conduction Mode
Input _ Current = I IN
COUT =
V
×I
= OUT OUT
VIN
In critical conduction mode:
ILPEAK = di = 2 × I IN
The duty cycle for the boost DC/DC system is defined
as:
Duty _ Cycle = D =
Output Capacitors
The amount and type of capacitor used is mainly
determined by the design output ripple (VRIPPLE)
requirement:
VOUT − VIN ( MIN )
VOUT
IOUT
VRIPPLE
×
D
FSW
When selecting output capacitors, it is more important
to check the effective ESR of the capacitor than the
actual capacitance value. For examples, a 10µF
capacitor with 0.02Ω ESR will handle higher ripple
current but produce less output ripple than a 33µF
capacitor with 0.04Ω ESR. It is recommended to use
low ESR MLCC ceramic capacitors. For high voltage
cost effective application, multiple Electrolytic
capacitors in parallel will reduce the total effective
ESR.
To determine the ON time for the boost switch:
ON _ time = dt =
D
FSW
For the application with VIN=100V, VOUT=200V, LED
current=200mA:
I IN =
200V × 0.2 A
= 0.44 A
90V
The ripple current at the input capacitor is:
di = 2 × 0.44 A = 0.89 A
D=
I IN _ RIPPLE =
200V − 90V
= 0.55
200V
FSW is the switching frequency, 100KHz in this
example.
dt × VIN
5.5 µs × 90V
=
= 560 µH
di
0.88 A
After the inductor value is calculated, we need to
consider the DCR resistance and the Isat saturation
current of the inductor. Inductor DCR is inversely
proportional to the Isat. It is recommended to select
an inductor for which the Isat value should be at least
50% higher than the ILpeak value. To minimize EMI
Rev. 1.0 November 2011
0.3 × VIN × (VOUT − VIN )
= 0.17 A
FSW × L × VOUT
where,
The inductor value is determined by:
L=
Input Capacitors
The input capacitors for boost converters do not
require low ESR due to the fact that the input current
is continuous. Also, they do not contain large peak
current as compared to the output capacitors.
Electrolytic capacitors should work well with the
appropriate voltage and ripple current rating, it is not
recommended to use Tantalum capacitors because
Boost converters do exhibit high surge currents during
startup which can cause tantalum capacitors to fail.
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Page 11 of 16
AOZ1977-1
Current Sense Resistors
There are two current sense resistors in this
application, an LED current sense resistor RFB and a
Boost switch current sense resistor RS.
The RHP zero has the effect of a zero in the gain
causing an imposed +20dB/decade on the roll off, but
o
has the effect of a pole in the phase, subtracting 90
in the phase. The RHP zero can be calculated by:
RFB LED current sense resistor is set by:
fZ 2 =
RFB =
2
ISET _ VOLTAGE 0.5V
=
= 2 .5 Ω
LED _ CURRENT
0 .2 A
LED current is a function of ISET voltage and RFB
resistance. ISET voltage is generated by connecting a
resistor divider (Rr1 and Rr2 in typical application
diagram) from 1.2V VREF pin to ISET and GND pins.
To minimize power consumption, it is recommended
that the total resistance for the divider is
approximately 20kΩ.
RS boost switch current sense resistor is set by:
RS =
0.3V
0.3V
=
= 0.375Ω
Inductor _ Peak _ Current 0.8 A
For typical application, we recommend to set the
voltage at CS to approximately 0.3V when inductor
current reaches the peak, and 0.4V at ILIM pin set by
R11 and R12 divided from 1.2V VREF.
Boost Feedback Loop Compensation
The AOZ1977-1 employs peak current mode control
for easy use and fast transient response. Peak current
mode control eliminates the double pole effect of the
output L&C filter. It greatly simplifies the
compensation loop design.
With peak current mode control, the boost power
stage can be simplified to be a one-pole, one left
plane zero and one right half plane (RHP) system in
frequency domain. The pole is dominant pole and can
be calculated by:
fP 1 =
1
2π × CO × RL
fZ1 =
The RHP zero obviously can cause the instable issue
if the bandwidth is higher. It is recommended to
design the bandwidth to lower than the one half
frequency of RHP zero.
The compensation design is actually to shape the
converter close loop transfer function to get desired
gain and phase. Several different types of
compensation network can be used for AOZ1977-1.
For most cases, a series capacitor and resistor
network connected to the COMP pin sets the polezero and is adequate for a stable high-bandwidth
control loop.
In the AOZ1977-1, FB pin and COMP pin are the
inverting input and the output of internal
transconductance error amplifier. A series R and C
compensation network connected to COMP provides
one pole and one zero. The pole is:
fP 2 =
1
2π × CO × ESRCO
GEA
2π × CC × GVEA
where,
GEA is the error amplifier transconductance, which is
-6
200∙10 A/V,
GVEA is the error amplifier voltage gain, which is 1000
V/V, and
CC is compensation capacitor.
The zero given by the external compensation network,
capacitor CC and resistor RC, is located at:
fZ 2 =
The zero is a ESR zero due to output capacitor and its
ESR can be calculated by:
VIN
2π × L × IO × VO
1
2π × CC × RC
Choosing the suitable CC and RC by trading-off
stability and bandwidth.
where,
CO is the output filter capacitor,
RL is load resistor value, and
ESRCO is the equivalent series resistance of output
capacitor.
Rev. 1.0 November 2011
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Page 12 of 16
AOZ1977-1
PCB Layout Consideration
Correct layout practices are essential for a working
design that will meet expectations. It is recommended
to use two-layer board for the design. However, a
single layer board would be sufficient if basic layout
rules are followed. In any SMPS layout, external
components should be grouped into Power or IC
control. From typical application circuit, there are two
GND symbols. The striped one is for Power GND and
the solid one is for Signal/Control GND. Both symbols
are connected to a single point connection on the
layout. All Power connections should be as short and
wide as possible in order to reduce undesired
parasitic inductance. The output capacitors should be
physically placed in the current path between the
SMPS and the load. Input capacitors should be placed
as close as possible to the input side of the inductor.
To prevent interference and system noise, it is critical
that the switch node connection for boost switch,
inductor, and output diode must be as short and close
as possible. A GND copper layer covers the top layer
to help shield the noise. For two-layer board, it is
essential that the GND plane under this switching
node should be filled and uninterrupted
Single Point Connection: Connecting PWR GND and Signal GND
Rev. 1.0 November 2011
www.aosmd.com
Page 13 of 16
AOZ1977-1
Package Dimensions, SOIC-16L
16
1
2
3
.004"(0.10mm)
RECOMMENDED LAND PATTERN
2.2
5.74
2.87
1.27
Symbols
Min.
Nom.
Max.
Symbols
Min.
Nom.
Max.
A
1.35
1.60
1.75
A
0.053
0.063
0.069
A1
0.10
—
0.25
A1
0.004
—
0.010
A2
—
1.45
—
A2
—
0.057
—
b
0.33
—
0.51
b
0.013
—
0.020
C
0.19
—
0.25
C
0.007
—
0.010
D
9.80
—
10.00
D
0.386
—
0.394
E1
3.80
3.90
4.00
E1
0.150
0.154
0.157
e
e
1.27 TYP
0.050 TYP
E
5.80
6.00
6.20
E
0.228
0.236
0.244
L
0.40
—
1.27
L
0.016
—
0.050
θ
0°
—
8°
θ
0°
—
8°
0.8
0.63
Notes:
1. All dimensions are in millimeters.
2. Dimensions are inclusive of plating
3. Package body sizes exclude mold flash and gate burrs. Mold flash at the non-lead sides should be less than 6 mils.
2. Dimension L is measured in gauge plane.
3. Tolerance is 0.10mm unless otherwise specified.
4. Controlling dimension is millimeter, converted inch dimensions are not necessarily exact.
Rev. 1.0 November 2011
www.aosmd.com
Page 14 of 16
AOZ1977-1
Tape and Reel Dimensions, SOIC-16L
P0
K0
T
D0
A
P2
E1
E2
CL
B1
B0
E
B2
K1
SECTIONA--A
A1
P1
A
D1
A0
FEEDING DIRECTION
UNIT: MM
Package
SO16
(16 mm)
A0
B0
6.50 10.30
±0.1 ±0.1
K0
2.30
±0.1
K1
D0
D1
E
E1
1.80 1.55 1.6 16.00 1.75
±0.1 ±0.05 ±0.1 ±0.3 ±0.1
E2
P0
P1
P2
T
B1
B2
A1
7.50
±0.1
4.0
±0.1
8.00
±0.1
2.0
±0.1
0.3
±0.05
REF.
6.6
REF.
1.5
REF.
3.5
W3 (Include flange distortion at outer edge)
W1 (Measured at Hub)
S
K
M
N (Hub Dia.)
H
W2 (Measured at Hub)
T
UNIT: MM
Tape Size
M
N
T
W1
16mm
Ø332
MAX.
Ø100.0
±2.0
2.0
±0.5
16.4
Trailer Tape
300mmmin.
Rev. 1.0 November 2011
W2
W3
22.4
15.9~19.4
MAX.
ComponentsTape
Orientation in Pocket
www.aosmd.com
S
K
H
2.2
TYP.
10.1
MIN.
Ø13.0
±0.2
Leader Tape
500mmmin.
Page 15 of 16
AOZ1977-1
Part Marking
AOZ1977AI-1
(SOIC-16)
Z1977AI-1
Part Number Code
FX YW LT
Assembly Lot Code
Fab & Assembly Location
Year & Week Code
This datasheet contains preliminary data; supplementary data may be published at a later date.
Alpha and 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 November 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.
www.aosmd.com
Page 16 of 16