HP 15S-EQ0034NW - Identyfikacja brakującego elementu
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Application Notes: AN_SY8368
High Efficiency Fast Response
8A Continuous, 16A Peak, 28V Input
Synchronous Step Down Regulator
General Description
Features
The SY8368 develops a high efficiency synchronous
step-down DC-DC regulator capable of delivering 8A
continuous, 16A peak current. The SY8368 operates
over a wide input voltage range from 4V to 28V and
integrates main switch and synchronous switch with
very low RDS(ON) to minimize the conduction loss.
• Low RDS(ON) for internal switches (top/bottom):
20/10 mΩ
• Wide input voltage range: 4-28V
• Instant PWM architecture to achieve fast transient
responses
• Internal 400uS softstart limits the inrush current
• Pseudo-constant frequency: 800kHz.
• 8A continuous/16A peak output current capability
• ±1.5% 0.6V reference
• Programmable peak current limit
• Power good indicator
• Output discharge function
• Short circuit latch off protection
• Over voltage latch off protection
• Input UVLO
• Over temperature protection
• RoHS Compliant and Halogen Free
• Compact package: QFN3x3-10
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The SY8368 adopts the instant PWM architecture to
achieve fast transient responses for high step down
applications and high efficiency at light loads. In
addition, it operates at pseudo-constant frequency of
800kHz under continuous conduction mode to
minimize the size of inductor and capacitor.
SY8368 □ (□□)□
Tempera ture Code
Packa ge Code
Optional Spec Code
Note
--
Applications
en
Package type
QFN3x3-10
•
•
•
•
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on
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Ordering Number
SY8368QNC
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Ordering Information
LCD-TV/Net-TV/3DTV
Set Top Box
Notebook
High Power AP
VIN
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Typical Applications
IN
PG
PG (Open Drain Output)
BS
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CIN
10uF
CBS
100nF
High/Floating/Low
ILMT
Sil
GND
VOUT=5V
LX
EN
ON/OFF
CVCC
2.2uF
VCC
L 1.5uH
C1
220pF
R1
100k
COUT
22uF×3
R3
1k
FB
R2
13.7k
Figure 1 Schematic
AN_SY8368 Rev. 0.9B
Figure 2. Efficiency
Silergy Corp. Confidential- Prepared for Customer Use Only
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�AN_SY8368
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Pinout (top view)
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(QFN3x3-10)
Pin Number
1
PG
2
ILMT
3
FB
4
VC
5
BS
6
IN
GND
LX
7,8
9
10
Pin Description
Enable control. Pull this pin high to turn on the IC. Do not leave this pin floating.
Power good Indicator. Open drain output when the output voltage is within 90% to
120% of regulation point.
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Pin Name
EN
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Top Mark: YWxyz, (Device code: YW, x=year code, y=week code, z= lot number code)
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Current limit setting pin. The current limit is set to 8A, 12A or 16A when this pin
is pull low, floating or pull high respectively.
Output Feedback Pin. Connect this pin to the center point of the output resistor
divider (as shown in Figure 1) to program the output voltage:
Vout=0.6*(1+R1/R2)
Internal 3.3V LDO output. Power supply for internal analog circuits and driving
circuit. Bypass a capacitor to GND.
Boot-Strap Pin. Supply high side gate driver. Decouple this pin to LX pin with
0.1uF ceramic cap.
Input pin. Decouple this pin to GND pin with at least 10uF ceramic cap
Ground pin
Inductor pin. Connect this pin to the switching node of inductor
AN_SY8368 Rev. 0.9B
Silergy Corp. Confidential- Prepared for Customer Use Only
2
�AN_SY8368
Absolute Maximum Ratings
(Note 1)
IN, LX, PG, EN ------------------------------------------------------------------------------------------------------ -0.3V to 30V
BS-LX, FB, ILMT, VCC ------------------------------------------------------------------------------------------- -0.3V to 4V
Power Dissipation, PD @ TA = 25°C QFN3x3-10 -----------------------------------------------------------------------3.3W
Package Thermal Resistance (Note 2)
θ JA -----------------------------------------------------------------------------------------------------------------30°C/W
θ JC ---------------------------------------------------------------------------------------------------------------- 4°C/W
Junction Temperature Range ------------------------------------------------------------------------------------------------ 125°C
Lead Temperature (Soldering, 10 sec.) ------------------------------------------------------------------------------------ 260°C
Storage Temperature Range -------------------------------------------------------------------------------------- -65°C to 150°C
Dynamic LX voltage in 50ns duration --------------------------------------------------------------------- IN+3V to GND-4V
Recommended Operating Conditions (Note 3)
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Supply Input Voltage ---------------------------------------------------------------------------------------------------- 4V to 28V
Junction Temperature Range ------------------------------------------------------------------------------------- -40°C to 125°C
Ambient Temperature Range -------------------------------------------------------------------------------------- -40°C to 85°C
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Block Diagram
AN_SY8368 Rev. 0.9B
Silergy Corp. Confidential- Prepared for Customer Use Only
3
�AN_SY8368
Electrical Characteristics
(VIN = 12V, VOUT =5V, COUT = 100uF, TA = 25°C, IOUT = 2A unless otherwise specified)
Parameter
Input Voltage Range
Quiescent Current
Symbol
VIN
IQ
Shutdown Current
Feedback Reference
Voltage
FB Input Current
Top FET RON
Bottom FET RON
Discharge FET RON
Bottom FET Current
Limit
Test Conditions
ISHDN
VREF
Min
4.0
Typ
VFB=4V
µA
V
nA
mΩ
mΩ
Ω
-50
20
10
50
ILMT=’0’
ILMT=Floating
ILMT=’1’
8
12
16
Vcc-0.8
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IFB
Rds(on)1
Rds(on)2
Rdis
ILIM
10
0.609
50
0.591
Unit
V
µA
3
0.6
IOUT=0,
VFB=VREF*105%
EN=0
Max
28
100
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ILMT Rising Threshold
VILMTH
VCC
V
ILMT Falling Threshold
VILMTL
0.8
V
ILMT Floating Threshold VILMIF
1.3
2
V
Soft Start Time
TSS
400
µS
EN Rising Threshold
VENH
0.8
V
EN Falling Threshold
VENL
0.4
V
Input UVLO Threshold
3.9
V
VUVLO
UVLO hysteresis
VHYS
0.3
V
Oscillator Frequency
FOSC
Vo=5V
0.68
0.8
0.92
MHz
Min ON Time
TON,MIN
VIN=VINMAX
50
ns
Min OFF Time
TOFF,MIN
80
ns
VCC Output
VCC
VIN=4V
3.2
3.3
3.4
V
Output Over Voltage
VFB Rising
115
120
125
%VREF
Threshold
Output Over Voltage
2
%VREF
Hysteresis
Output Over Voltage
20
us
Delay Time
Power Good Threshold
VFB Rising (Good)
88
90
92
%VREF
Power Good Hysteresis
2
%VREF
Power Good Delay Time
10
us
Thermal Shutdown
TSD
150
°C
Temperature
Thermal Shutdown
THYS
15
°C
hysteresis
Note 1: Stresses beyond the “Absolute Maximum Ratings” may cause permanent damage to the device. These are
stress ratings only. Functional operation of the device at these or any other conditions beyond those indicated in the
operational sections of the specification is not implied. Exposure to absolute maximum rating conditions for
extended periods may affect device reliability
Note 2:
θ JA is measured in the natural convection at TA = 25°C on a four-layer Silergy Evaluation Board..
Note 3: The device is not guaranteed to function outside its operating conditions.
AN_SY8368 Rev. 0.9B
Silergy Corp. Confidential- Prepared for Customer Use Only
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�AN_SY8368
Typical Performance Characteristics
Efficiency vs. Load Current
Efficiency vs. Load Current
100
100
90
90
80
80
70
70
60
60
50
50
VIN=7.4V,VOUT=5.0V
VIN=12V,VOUT=5.0V
VIN=19V,VOUT=5.0V
VIN=28V,VOUT=5.0V
40
30
VIN=5.0V,VOUT=3.3V
VIN=12V,VOUT=3.3V
VIN=19V,VOUT=3.3V
VIN=28V,VOUT=3.3V
40
30
20
20
0.001
0.01
0.10
1.00
10.00
0.001
0.01
0.10
10.00
Load Current (A)
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Load Current (A)
1.00
Efficiency vs. Load Current
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Efficiency vs. Load Current
95
95
85
85
75
65
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75
65
55
55
45
VIN=5.0V,VOUT=1.8V
VIN=12V,VOUT=1.8V
VIN=19V,VOUT=1.8V
VIN=28V,VOUT=1.8V
15
0.01
0.10
1.00
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0.001
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25
Load Current (A)
VIN=5.0V,VOUT=1.2V
VIN=12V,VOUT=1.2V
VIN=19V,VOUT=1.2V
VIN=28V,VOUT=1.2V
35
en
35
45
25
15
10.00
0.001
0.01
0.10
1.00
10.00
Load Current (A)
Load Transient
(VIN=12V, VOUT=5V, ILOAD=2-6A)
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Load Transient
(VIN=12V, VOUT=5V, ILOAD=0.8-8A)
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∆VOUT
100mV/div
∆VOUT
IL
2A/div
5A/div
Sil
IL
100mV/div
Time (200µs/div)
AN_SY8368 Rev. 0.9B
Time (200µs/div)
Silergy Corp. Confidential- Prepared for Customer Use Only
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�AN_SY8368
Startup from Enable
Shutdown from Enable
(VIN=12V, VOUT=5V, ILOAD=8A)
(VIN=12V, VOUT=5V, ILOAD=8A)
5V/div
VLX
EN
5V/div
VLX
EN
10V/div
10V/div
VOUT
5V/div
VOUT
IL
5V/div
IL
5A/div
5A/div
Time (400µs/div)
Time (400µs/div)
Shutdown from VIN
(VIN=12V, VOUT=5V, ILOAD=8A)
VOUT
5V/div
IL
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10V/div
5A/div
10V/div
10V/div
VOUT
5V/div
IL
5A/div
Time (2ms/div)
fid
Time (4ms/div)
VIN
VLX
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VLX
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10V/div
en
VIN
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Startup from VIN
(VIN=12V, VOUT=5V, ILOAD=8A)
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Short Circuit Protection
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(VIN=12V, VOUT=5V, ILMT floating, Null Load to Short)
VOUT
5A/div
Sil
IL
2V/div
Time (100µs/div)
AN_SY8368 Rev. 0.9B
Silergy Corp. Confidential- Prepared for Customer Use Only
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�AN_SY8368
Output Ripple
(VIN=12V, VOUT=5V, ILOAD=8A)
∆Vout(AC)
20mV/div
5V/div
IL
5A/div
Frequency(kHz)
VLX
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Time (2µs/div)
AN_SY8368 Rev. 0.9B
Silergy Corp. Confidential- Prepared for Customer Use Only
7
�AN_SY8368
Operation
The SY8368 develops a high efficiency synchronous
step-down DC-DC regulator capable of delivering 8A
continuous, 16A peak current. The SY8368 operates
over a wide input voltage range from 4V to 28V and
integrates main switch and synchronous switch with
very low RDS(ON) to minimize the conduction loss.
The SY8368 adopts the instant PWM architecture to
achieve fast transient responses for high step down
applications and high efficiency at light loads. In
addition, it operates at pseudo-constant frequency of
800kHz under continuous conduction mode to
minimize the size of inductor and capacitor.
Output inductor L:
There are several considerations in choosing this
inductor.
1) Choose the inductance to provide the desired
ripple current. It is suggested to choose the ripple
current to be about 40% of the maximum output
current. The inductance is calculated as:
VOUT (1 − VOUT /VIN, MAX )
FSW × I OUT, MAX × 40%
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L=
where Fsw is the switching frequency and IOUT,MAX is
the maximum load current.
The SY8368 regulator IC is quite tolerant of different
ripple current amplitude. Consequently, the final choice
of inductance can be slightly off the calculation value
without significantly impacting the performance.
2) The saturation current rating of the inductor must
be selected to be greater than the peak inductor
current under full load conditions.
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Because of the high integration in the SY8368 IC, the
application circuit based on this regulator IC is rather
simple. Only input capacitor CIN, output capacitor COUT,
output inductor L and feedback resistors (R1 and R2)
need to be selected for the targeted applications
specifications.
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Applications Information
Output capacitor COUT:
The output capacitor is selected to handle the output
ripple noise requirements. Both steady state ripple and
transient requirements must be taken into consideration
when selecting this capacitor. For most applications,
an X5R or better grade ceramic capacitor greater than
66uF capacitance can work well. The capacitance
derating with DC voltage must be considered.
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0.6V
R2 =
R1 .
VOUT − 0.6V
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Feedback resistor dividers R1 and R2:
Choose R1 and R2 to program the proper output voltage.
To minimize the power consumption under light loads,
it is desirable to choose large resistance values for both
R1 and R2. A value of between 10kΩ and 1MΩ is
highly recommended for both resistors. If Vout is 3.3V,
R1=100k is chosen, then using following equation, R2
can be calculated to be 22.1k:
0.6VFB
GND
R1
R2
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OUT
To minimize the potential noise problem, place a
typical X5R or better grade ceramic capacitor really
close to the IN and GND pins. Care should be taken to
minimize the loop area formed by CIN, and IN/GND
pins. In this case, a 10uF low ESR ceramic capacitor is
recommended.
AN_SY8368 Rev. 0.9B
VOUT(1-VOUT/VIN,MAX)
2 ⋅ FSW ⋅ L
VOUT
Input capacitor CIN:
The ripple current through input capacitor is calculated
as:
I
= I ⋅ D(1 − D) .
CIN _ RMS
ISAT, MIN & gt; IOUT, MAX +
3)
The DCR of the inductor and the core loss at the
switching frequency must be low enough to
achieve the desired efficiency requirement. It is
desirable to choose an inductor with DCR & lt; 10mΩ
to achieve a good overall efficiency.
Current limit setting
The current limit is set to 8A, 12A or 16A when ILMT
pin is pull low, floating or pull high respectively.
Soft-start
The SY8368 has a built-in soft-start to control the rise
rate of the output voltage and limit the input current
surge during IC start-up. The typical soft-start time is
400us.
Enable Operation
Silergy Corp. Confidential- Prepared for Customer Use Only
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�AN_SY8368
Pulling the EN pin low ( & lt; 0.4V) will shut down the
device. During shutdown mode, the SY8368
shutdown current drops to lower than 10uA, Driving
the EN pin high ( & gt; 0.8V) will turn on the IC again.
may further speed up the load transient responses.
External Bootstrap Cap
This capacitor provides the gate driver voltage for
internal high side MOSEFET. A 100nF low ESR
ceramic capacitor connected between BS pin and LX
pin is recommended.
VCC LDO
The 3.3V VCC LDO provides the power supply for
internal control circuit. Bypass this pin to ground with
a 2.2uf ceramic capacitor.
2) CIN must be close to Pins IN and GND. The loop
area formed by CIN and GND must be minimized.
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VCC
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LX
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CBS
100nF
Layout Design:
The layout design of SY8368 regulator is relatively
simple. For the best efficiency and minimum noise
problem, we should place the following components
close to the IC: CIN, CVCC L, R1 and R2.
1) It is desirable to maximize the PCB copper area
connecting to GND pin to achieve the best thermal and
noise performance. If the board space allowed, a
ground plane is highly desirable.
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BS
3) The PCB copper area associated with LX pin must
be minimized to avoid the potential noise problem.
2.2uF
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Power Good Indication
PG is an open drain output. This pin is externally
pulled high when the FB voltage is within 90% to
120% of the internal reference voltage. Otherwise is
pulled low.
5) If the system chip interfacing with the EN pin has a
high impedance state at shutdown mode and the IN pin
is connected directly to a power source such as a Li-Ion
battery, it is desirable to add a pull down 1Mohm
resistor between the EN and GND pins to prevent the
noise from falsely turning on the regulator at shutdown
mode.
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Load Transient Considerations:
The SY8368 regulator IC adopts the instant PWM
architecture to achieve good stability and fast transient
responses. In applications with high step load current,
adding an RC network RFF and CFF parallel with R1
4) The components R1 and R2, and the trace connecting
to the FB pin must NOT be adjacent to the LX net on
the PCB layout to avoid the noise problem.
AN_SY8368 Rev. 0.9B
Silergy Corp. Confidential- Prepared for Customer Use Only
9
�AN_SY8368
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QFN3x3-10 FC Package Outline Drawing
Bottom View
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Top View
Side View
Notes:
Recommended PCB Layout
(Reference only)
All dimension in MM and exclude mold flash & metal burr
AN_SY8368 Rev. 0.9B
Silergy Corp. Confidential- Prepared for Customer Use Only
10
�AN_SY8368
Taping & Reel Specification
1. Taping orientation
Feeding direction
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QFN3x3
Reel
Width
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2. Carrier Tape & Reel specification for packages
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Reel
Size
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Package
types
QFN3x3
Tape
width
(mm)
Pocket
pitch(mm)
Reel size
(Inch)
Reel
width(mm)
Trailer
length(mm)
Leader length
(mm)
Qty per
reel
12
8
13 "
12.4
400
400
5000
3. Others: NA
AN_SY8368 Rev. 0.9B
Silergy Corp. Confidential- Prepared for Customer Use Only
11
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