SKY87608_201860B.pdf

PRELIMINARY DATA SHEET
SKY87608: 28 V, 3 A Non-Synchronous Step-Down Converter
Applications
Description
• Set-top boxes
The SKY87608 is a step-down DC-DC converter that operates
with a wide 4.5 V to 28 V input voltage range and regulates the
output voltage as low as 0.9 V while supplying up to 3 A to the
output. The 450 kHz switching frequency allows for an efficient
step-down regulator design.
• Distributed power systems
• Industrial applications
Features
• 4.5 V to 28 V input voltage
• Up to 97% efficiency
• Internal 180 mΩ high-side N-channel MOSFET
• Internal 12 Ω refresh MOSFET
• Up to 3 A load current
• Adjustable output voltage (0.9 V to 0.8 × VIN)
• Fixed 450 kHz switching frequency
• 4 ms soft-start period
• External compensation
• Less than 1 µA shutdown current
The SKY87608 uses an adjustable output voltage that can be set
from 12% to 80% of the input voltage by an external resistive
voltage divider. Internal soft-start prevents excessive inrush
current without requiring an external capacitor.
The SKY87608 includes input under-voltage and overcurrent
protection to prevent damage in the event of a fault condition.
Thermal overload protection prevents damage to the SKY87608 or
circuit board when operating beyond its thermal capability.
The SKY87608 is available in a small Pb-free, 8-pin,
SOP-8L-EP package.
A typical application circuit is shown in Figure 1. The pin
configuration is shown in Figure 2. Signal pin assignments and
functional pin descriptions are provided in Table 1.
• Current limit protection
• Standard 8-pin SOP-8L package (MSL1, 260 °C per JEDEC-JSTD-020) with exposed pad
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PRELIMINARY DATA SHEET • SKY87608 28V, 3A NON-SYNCHRONOUS STEP-DOWN CONVERTER
Figure 1. SKY87608 Typical Application Circuit
Figure 2. SKY87608 8-Pin SOP-8L
(Top View)
Table 1. SKY87608 Signal Descriptions
Pin #
Name
1
IN
Input supply. Connect IN to the input power source. Bypass IN to GND with a 10 μF or greater ceramic capacitor. IN
connects to the source of the internal high-side N-channel MOSFET and linear regulators powering the controller and
drivers.
Description
2
LX
Inductor switching. LX is internally connected to the source of the internal high-side N-channel MOS- FET, the high-side
driver, and current-sense circuitry. Connect to the power inductor, and the Schottky diode as shown in the Typical
Application Circuit diagram.
3
NC
Do NOT connect externally. Leave pin floating.
4
GND
Ground. GND is internally connected to the analog ground of the control circuitry, and the source of the 12 Ω refresh
MOSFET.
5
FB
6
COMP
7
EN
Enable input. Logic high enables the regulator. A logic low forces the SKY87608 into shutdown mode, placing the
output into a high-impedance state and reducing the quiescent current to less than 1 μA.
8
BST
Boot-strapped high-side driver supply. Connect a 0.1 μF ceramic capacitor between BST and LX as shown in the
Typical Application Circuit diagram.
–
EP
Exposed paddle. Connect to PCB ground plane.
Feedback input. FB senses the output voltage for regulation control. Connect a resistive divider network from the output
to FB to GND to set the output voltage accordingly. The FB regulation threshold is 0.9 V for the SKY87608.
Compensation pin of the error amplifier.
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PRELIMINARY DATA SHEET • SKY87608 28V, 3A NON-SYNCHRONOUS STEP-DOWN CONVERTER
Electrical and Mechanical Specifications
Typical performance characteristics of the SKY87608 are
illustrated in Figures 3 through 24.
The absolute maximum ratings of the SKY87608 are provided in
Table 2. Thermal information is provided in Table 3, and electrical
specifications are provided in Table 4.
Table 2. SKY87608 Absolute Maximum Ratings (Note 1)
Symbol
Minimum
Maximum
Units
IN to GND voltage
Parameter
VIN
–0.3
+30
V
LX to GND voltage
VLX
–0.3
VIN + 0.3
V
BST to GND voltage
VBST
VCC – 0.6
VIN + 6
V
EN to GND voltage
VEN
–0.3
+30
V
FB to GND voltage
VFB
–0.3
+6
V
VCOMP
–0.3
+6
V
COMP to GND voltage
Note 1: Exposure to maximum rating conditions for extended periods may reduce device reliability. There is no damage to device with only one parameter set at the limit and all other
parameters set at or below their nominal value. Exceeding any of the limits listed may result in permanent damage to the device.
CAUTION: Although this device is designed to be as robust as possible, Electrostatic Discharge (ESD) can damage this device. This device
must be protected at all times from ESD. Static charges may easily produce potentials of several kilovolts on the human body
or equipment, which can discharge without detection. Industry-standard ESD precautions should be used at all times.
Table 3. SKY87608 Thermal Information (Note 1) (Note 2)
Parameter
Operating ambient temperature
Operating junction temperature
Maximum soldering temperature (at leads, 10 seconds.)
Symbol
Minimum
TA
–40
TJ
–40
Typical
Maximum
Units
+85
°C
+150
°C
TLEAD
300
°C
Maximum junction-to-ambient thermal resistance
θJA
41
°C/W
Maximum power dissipation (Note 3)
PD
2.8
W
SKY87608 SOP-8L-EP Thermal Impedance
Note 1: Performance is guaranteed only under the conditions listed in this Table.
Note 2: Mounted on 1 inch2 FR4 board.
Note 3: Derate 27 mW/°C above 25 °C.
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PRELIMINARY DATA SHEET • SKY87608 28V, 3A NON-SYNCHRONOUS STEP-DOWN CONVERTER
Table 4. SKY87608 Electrical Specifications (Note 1)
(VIN = 12 V, VEN = 5 V, AGND = PGND, TA = –40 °C to 85 °C, Typical Values are at TA = 25 °C, Unless Otherwise Noted)
Parameter
Symbol
Test Condition
Input voltage
VIN
No load supply current
IQ
No load current; not switching
Shutdown current
ISHDN
EN = GND, VIN = 28 V
Output voltage (Note 2)
VOUT
Min
Typical
Max
28
V
1.6
3.2
mA
1
5
µA
4.5
0.9
Nominal feedback voltage
0.8 × VIN
0.9
FB accuracy
VFB
No load, VIN = 24 V
0.88
FB leakage current
IFB
FB = 1.5 V or GND
–0.2
Load regulation
∆VOUT / IOUT
VIN = 12 V, VOUT = 5 V
Line regulation
∆VOUT / VIN
VIN = 4.5 V to 28 V
Oscillator frequency
fOSC
Minimum on-time
tON(MIN)
0.90
0.92
V
+0.2
µA
%
0.5
450
%
520
260
Maximum duty cycle
DMAX
No Load
80
83
High-side MOSFET “on” resistance
RDS(ON)HI
IN to LX
40
180
Peak current limit threshold
IPK
3.75
5.0
Refresh MOSFET “on” resistance
RDS(ON)LO
LX to GND
Input under-voltage lockout
VUVLO
VIN rising, hysteresis = 200 mV
Over-temperature shutdown threshold
TSHDN
Rising edge, hysteresis = 15 °C
EN input logic threshold
VEN
EN input current
IEN
Soft-start period
tSS
VIN = 24 V
%
320
mΩ
A
Ω
4.2
160
V
°C
0.4
1.7
V
–2.0
40
µA
4
Note 1: Performance is guaranteed only under the conditions listed in this Table.
Note 2: The minimum output voltage must be greater than tON(MIN) × fOSC × VIN(MIN) due to duty cycle limitations.
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4
kHz
ns
12
3.5
V
V
1.0
380
Units
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PRELIMINARY DATA SHEET • SKY87608 28V, 3A NON-SYNCHRONOUS STEP-DOWN CONVERTER
Typical Performance Characteristics
Figure 3. Efficiency vs Output Current (VOUT = 3.3 V)
Figure 4. Efficiency vs Output Current (VOUT = 5.0 V)
Figure 5. Efficiency vs Output Current (VOUT = 15 V)
Figure 6. Load Regulation (VOUT = 3.3 V)
Figure 7. Load Regulation (VOUT = 15 V)
Figure 8. Line Regulation (VOUT = 3.3 V)
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PRELIMINARY DATA SHEET • SKY87608 28V, 3A NON-SYNCHRONOUS STEP-DOWN CONVERTER
Typical Performance Characteristics
Figure 9. Line Regulation (VOUT = 15 V)
Figure 10. Oscillator Frequency vs Temperature (IOUT = 100 mA)
Figure 11. Feedback Voltage Error vs Temperature
Figure 12. Quiescent Current vs Input Voltage
(Switching; No Load)
Figure 13. High Side MOSFET On-Resistance vs Input Voltage
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PRELIMINARY DATA SHEET • SKY87608 28V, 3A NON-SYNCHRONOUS STEP-DOWN CONVERTER
Typical Performance Characteristics
Figure 14. Soft Start (VOUT = 5 V, VIN = 12 V, IOUT = 100 mA)
Figure 15. Soft Start (VOUT = 5 V, VIN = 24 V, IOUT = 100 mA)
Figure 16. Soft Start (VOUT = 5 V, VIN = 12 V, IOUT = 3 A)
Figure 17. Soft Start (VOUT = 5 V, VIN = 24 V, IOUT = 3 A)
Figure 18. Output Voltage Ripple
(VOUT = 5 V, VIN = 12 V, IOUT = 100 mA)
Figure 19. Output Voltage Ripple
(VOUT = 5 V, VIN = 24 V, IOUT = 100 mA)
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PRELIMINARY DATA SHEET • SKY87608 28V, 3A NON-SYNCHRONOUS STEP-DOWN CONVERTER
Typical Performance Characteristics
Figure 20. Output Voltage Ripple
(VOUT = 5 V, VIN = 12 V, IOUT = 3 A)
Figure 21. Output Voltage Ripple
(VOUT = 5 V, VIN = 24 V, IOUT = 3 A)
Figure 22. Load Transient
(VOUT = 5 V, VIN = 12 V, IOUT = 0.1 to 3 A)
Figure 23. Load Transient
(VOUT = 5 V, VIN = 24 V, IOUT = 0.1 to 3 A)
Figure 24. Load Transient
(VOUT = 15 V, VIN = 24 V, IOUT = 0.1 to 3 A)
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PRELIMINARY DATA SHEET • SKY87608 28V, 3A NON-SYNCHRONOUS STEP-DOWN CONVERTER
Figure 25. SKY87608 Functional Block Diagram
Functional Description
Voltage Soft-Start
A functional block diagram is provided in Figure 25.
The soft-start circuit ramps the reference voltage from ground
up to the 0.9 V nominal feedback regulation voltage (see
Figure 25). The internal soft-start capacitor sets the soft-start
period as 4 ms (typical).
Control Scheme
The SKY87608 is a non-synchronous, fixed-frequency, currentmode step-down converter. The regulator includes an internal
high-side N-channel MOSFET capable of supporting loads up to
3 A. A floating gate driver powers the high-side N-channel
MOSFET from an external boot-strap capacitor through the BST
pin. The capacitor is charged when LX is pulled low through the
rectifier, and the BST capacitor maintains sufficient voltage to
enhance the high-side N-channel MOSFET during the on-time.
An internal 12 Ω boost capacitor refresh MOSFET allows
reliable power-up regardless of the output voltage level.
The SKY87608 supports an adjustable output voltage using an
external resistive voltage divider, allowing the output to be set
to any voltage between 12% and 80% of the input voltage. The
SKY87608 switches at 450 kHz.
Current Limit Protection
The SKY87608 includes protection for overload and short-circuit
conditions by limiting the peak inductor current. During the “on”
time, the controller monitors the current through the high-side
MOSFET. If the current exceeds the peak current-limit threshold
(5 A, typical), the controller immediately turns off the high-side
MOSFET.
The soft-start is discharged/reset if any of the following occurs:
the regulator is disabled (EN pulled low), the input voltage drops
below the UVLO threshold, or thermal shutdown is activated.
Thermal Shutdown
The SKY87608 includes thermal protection that disables the
regulator when the die temperature reaches 160 °C. The
thermal shutdown resets the soft-start circuit and automatically
restarts when the temperature drops below 145 °C.
Application Information
To ensure that the maximum possible performance is obtained
from the SKY87608, please refer to the following application
recommendations for component selection.
Adjustable Output Resistor Selection
The output voltage (VOUT) may be set from 0.9 V to 80% of VIN.
The resistive feedback voltage divider sets the output voltage
according to the following relationship:
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PRELIMINARY DATA SHEET • SKY87608 28V, 3A NON-SYNCHRONOUS STEP-DOWN CONVERTER
RFB1 is rounded to the nearest 1% resistor value. RFB2 is
typically selected to be between 10 kΩ and 200 kΩ. The lower
resistance improves noise immunity, but results in higher
feedback current and reduced efficiency, as shown in
Figure 26.
For other output voltages, the inductance can be calculated
based on the internal slope compensation requirement and
equal to:
Manufacturer’s specifications list both the inductor DC current
rating, which is a thermal limitation, and the peak current
rating, which is determined by the saturation characteristics.
The inductor should not show any appreciable saturation under
normal load conditions.
The saturation current is a very important parameter for
inductor selection. It must be more than the sum of DC current
and maximum peak current through the inductor, and the
adequate margin is important for safe application. The
maximum peak current is given by the following equation:
Figure 26. FB Resistor Divider
Table 5 shows the divider resistor value for different output
voltages.
Table 5. Resistor Selection for Different Output Voltages
Output Voltage (V)
RFB1 (kΩ)
(RFB2 = 20 kΩ)
1.5
13.3
3.3
53.6
5.0
91
8.0
158
10
200
12
249
15
316
18
383
20
422
Where L is the inductance and f is the operation frequency.
Some inductors that meet the peak and average current ratings
requirements still result in excessive losses due to a high Direct
Current Resistance (DCR). Always consider the losses
associated with the DCR and their effect on the total regulator
efficiency when selecting an inductor. Table 6 shows the
recommended inductor examples for different output voltages.
Input Capacitor
Typically, the input impedance is so low (or has other input
capacitors distributed throughout the system) that a single
10 μF X7R or X5R ceramic capacitor located near the SKY87608
is sufficient. However, additional input capacitance may be
necessary depending on the impedance of the input supply. To
estimate the required input capacitance requirement, determine
the acceptable input ripple level (VPP) and solve for CIN:
Inductor Selection
The step-down converter uses peak current mode control with
slope compensation to maintain stability for duty cycles greater
than 50%. The output inductor value must be selected to make
the inductor current down slope to meet the internal slope
compensation requirements. The internal slope compensation is
designed to be 75% of the inductor current down slope of 5 V
output with 6.8 μH inductor.
Always examine the ceramic capacitor DC voltage coefficient
characteristics when evaluating ceramic bypass capacitors.
In addition to the capacitance requirement, the RMS current
rating of the input capacitor must be able to support the pulsed
current drawn by the step-down regulator. The input RMS
current requirement may be determined by:
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PRELIMINARY DATA SHEET • SKY87608 28V, 3A NON-SYNCHRONOUS STEP-DOWN CONVERTER
Table 6. Inductor Selection for Different Output Voltages
VOUT
(V)
2.5
1.5
3.3
5
10
12
15
18
20
Saturation Current
(A)
DCR
(mΩ)
CDRH8D38NP-2R5N
5.5
17.5
744777002
6.5
DR73-2R2-R
CDRH105RNP-4R7N
CDRH10D68NP-4R7N
Inductance
(µH)
2.2
4.7
6.8
15
18
22
27
27
Part Number
Dimension(mm)
L×W×H
Manufacturer
8.3×8.3×4
Sumida
20
7.3×7.3×4.5
Wurth Elektronik
5.52
16.5
7.9×7.9×3.8
Coil Tronics
6.4
12.3
10.5×10.3×5.1
6.6
9.8
10.5×10.5×7.1
7447715004
6.3
16
12×12×4.5
CDRH105RNP-6R8N
5.4
18
10.5×10.3×5.1
CDRH124NP-6R8M
4.9
23
12.3×12.3×4.5
7447715006
4.7
25
12×12×4.5
CDRH127NP-15M
4.5
27
12.3×12.3×8
CDRH127/LDHF-150M
5.65
26,4
12.3×12.3×8
744771115
4.55
30
DR125-150-R
5.69
29.8
Sumida
Wurth Elektronik
Sumida
Wurth Elektronik
Sumida
12×12×6
Wurth Elektronik
13×13×6.3
Coil Tronics
CDRH127/LDHF-180M
5.1
28
12.3×12.3×8
Sumida
744771118
4.3
34
12×12×6
Wurth Elektronik
DR125-180-R
5.32
37.7
13×13×6.3
Coil Tronics
CDRH127/LDHF-220M
4.7
36.4
12.3×12.3×8
Sumida
744770122
5.0
43
12×12×8
Wurth Elektronik
DR125-220-R
4.71
39.6
13×13×6.3
Coil Tronics
CDRH127/LDHF-270M
4.2
41.6
12.3×12.3×8
Sumida
744770127
3.8
46
12×12×8
7447709270
5.8
40
12×12×10
CDRH127/LDHF-270M
4.2
41.6
744770127
3.8
46
12×12×8
7447709270
5.8
40
12×12×10
The term D × (1 – D) appears in both the input ripple voltage
and input capacitor RMS current equations, so the maximum
occurs when VOUT = 0.5 × VIN (50% duty cycle). This results in a
set of “worst case” capacitance and RMS current design
requirements:
The input capacitor provides a low impedance loop for the
pulsed current drawn by the SKY87608. Low Equivalent Series
Resistance/Equivalent Series Inductance (ESR/ESL) X7R and
X5R ceramic capacitors are ideal for this function. To minimize
the stray inductance, the capacitor should be placed as closely
as possible to the high-side MOSFET. This keeps the high
12.3×12.3×8
Wurth Elektronik
Sumida
Wurth Elektronik
frequency content of the input current localized, minimizing EMI
and input voltage ripple. The proper placement of the input
capacitor can be seen in the Evaluation Board layout (see the
"Layout Considerations" section of this Data Sheet).
A laboratory test set-up typically consists of two long wires
running from the bench power supply to the Evaluation Board
input voltage pins. The inductance of these wires, along with
the low-ESR ceramic input capacitor, can create a high-Q
network that may affect the regulator’s performance. This
problem often becomes apparent in the form of excessive
ringing in the output voltage during load transients. Errors in the
loop phase and gain measurements can also result.
Since the inductance of a short PCB trace feeding the input
voltage is significantly lower than the power leads from the
bench power supply, most applications do not exhibit this
problem.
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PRELIMINARY DATA SHEET • SKY87608 28V, 3A NON-SYNCHRONOUS STEP-DOWN CONVERTER
In applications where the lead inductance of the input power
source cannot be reduced to a level that does not affect the
regulator performance, a high-ESR tantalum or aluminum
electrolytic should be placed in parallel with the low ESR/ESL
ceramic capacitor. This reduces the input impedance and
dampens the high-Q network, stabilizing the input supply.
Output Capacitor
The output capacitor impacts stability, limits the output ripple
voltage, and maintains the output voltage during large load
transitions. The SKY87608 is designed to work with any type of
output capacitor since the controller features externally
adjustable compensation (see the "Stability Considerations" and
"Compensation Component Selection" sections of this Data
Sheet).
The output ripple voltage magnitude is determined by the output
capacitor's ability to filter the inductor ripple current. The ripple
voltage has two components, capacitive and ESR induced ripple
voltage:
The capacitive ripple and ESR ripple are phase shifted from
each other, but depending on the type of output capacitor
chemistry, one of them typically dominates.
After a load step occurs, the output capacitor must support the
difference between the load requirement and inductor current.
Once the average inductor current increases to the DC load
level, the output voltage recovers. Therefore, based on
limitations in the ability to discharge the inductor, a minimum
output voltage deviation may be determined by the following
equation:
Where, VSOAR is the output voltage overshoot and undershoot
deviation. Bandwidth and gain limitations (depending on output
capacitor and compensation component selection) may result in
larger output voltage deviations.
The ceramic output capacitor provides low ESR and low ESL,
resulting in low output ripple dominated by the capacitive ripple
voltage (ΔVOUT(CAP)). However, due to the lower capacitance
value, the load transient response is significantly worse.
Therefore, ceramic output capacitors are generally
recommended only for designs with soft load transients (slow
di/dt and/or small load steps).
Tantalum and electrolytic capacitors provide a high-capacitance,
low-cost solution. The bulk capacitance provides minimal
output voltage drop/soar after load transients occur.
Stability Considerations
The SKY87608 uses a current-mode architecture, which relies
on the output capacitor and a series resistor-capacitor network
on the COMP pin for stability. COMP is the output of the
transconductance error amplifier, so the RC network creates a
pole-zero pair used to control the gain and bandwidth of the
control loop.
The DC loop gain (ADC) is set by the voltage gain of the internal
transconductance amplifier (AEA = gM(EA) × ROUT = 3000 V/V),
the compensation gain (ACC = 1 V/V), and the current-sense
gain (ACS = 1 V/V):
Where VFB is the 0.9 V feedback voltage, VOUT is the output
voltage determined by the feedback resistors, RDS(ON) is the
“on” resistance of the high-side N-channel MOSFET, and RLOAD
is the output load resistance (RLOAD = VOUT /IOUT).
Since the output impedance is a function of the load current and
output voltage, the equation may be rewritten independent of
the VOUT term:
Additionally, the high-side “on” resistance RDS(ON) is inversely
proportional to the maximum output current (IOUT) due to the
peak current limit. This effectively limits the typical value of ADC
to a value of 360 V/V (51 dB).
The control loop has two dominant poles: one created by the
output capacitor (COUT) and load resistance, and the other
formed by the total compensation capacitance (CCC1 + CCC2)
and the error amplifier transconductance (gM(EA) = 570 μA/V):
However, the system also has two zeros in the control loop: one
created by the series compensation resistor (RCOMP) and
capacitor (CCC1), and the other formed by the output capacitor
and its parasitic series resistance (ESR):
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PRELIMINARY DATA SHEET • SKY87608 28V, 3A NON-SYNCHRONOUS STEP-DOWN CONVERTER
The ESR zero is highly dependent on the type of output
capacitors being used (ceramic vs tantalum), and may not occur
before crossover. If the ESR zero occurs low enough, the
compensation zero formed by RCOMP may be placed at
crossover to avoid stability problems.
However, if both zeros are required below crossover, a third
pole is needed to maintain stability. This third pole can be
added by including another compensation capacitor (CCC2 in
Figure 1) in parallel with the main series RC network:
• RSEN is the high side current sensing resistor, RSEN = RDS(HS)
in this case.
There is already a 90° phase shift at very low frequencies, ωP1.
Compensating the 2nd pole ωP2 with 1st zero ωZ1, the unity gain
frequency can be simplified as:
Set the unity gain frequency far away from the switching
frequency to avoid any switching noise in the voltage loop,
fT = fSW/20.
If CCC2 << CCC1, the third pole is simplified to:
To safely avoid the Nyquist pole (half the switching frequency),
the crossover frequency should occur between 1/20th and 1/5th
of the switching frequency. Lower crossover frequencies result
in slower transient response speed, while higher crossover
frequencies could result in instability, as shown in Figure 27.
The ESR zero ωZ2 is used to cancel the high frequency pole ωP3.
gm = 570 μA/V, gm × ROUT(EA) = 3000 V/V, RSEN = 100 mΩ,
COUT = 22 μF, and RESR = 10 mΩ.
For VOUT = 3.3 V, RCOMP = 2 kΩ, CCC1= 10 nF, and
CCC2 = 100 pF.
For VOUT = 5 V, RCOMP = 3 kΩ, CCC1= 10 nF, and CCC2 = 56 pF.
For VOUT = 15 V, RCOMP = 9.1 kΩ, CCC1= 10 nF, and
CCC2 = 22 pF.
Table 7 gives the recommended compensation value for
different output voltages.
Table 7. Recommended Compensation Values
VOUT (V)
RCOMP (kΩ)
CCC1 (nf)
CCC2 (pf)
1.5
1.0
10
270
3.3
2
10
100
5
3
10
56
10
6.2
10
33
12
7.5
10
33
15
9.1
10
22
Compensation Component Selection
18
10
10
22
This is peak current mode control. An R-C series network (or
type II) compensation is applied at the transconductance
amplifier output (COMP).
20
12
10
22
Figure 27. Compensation Components
• ROUT(EA) is the output impedance of the transconductance
error amplifier.
• N is the scaling factor of output current, ISEN = IOUT/N (N = 1
in this case).
The type of output capacitor determines how the compensation
components should be selected. With large tantalum and
electrolytic capacitors, the output capacitor pole dominates the
control loop design. Alternatively, small low-ESR ceramic
capacitors rely on the compensation capacitor to generate the
dominant pole.
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PRELIMINARY DATA SHEET • SKY87608 28V, 3A NON-SYNCHRONOUS STEP-DOWN CONVERTER
Bootstrap Capacitor Selection
To fully turn on the high side N-channel MOSFET, a bootstrap
capacitor is connected between the BST pin and the LX pin.
During the off time, the switching node is pulled to ground and
the bootstrap capacitor charges up to approximately 5 V
through an internal diode (see Figure 25). The bootstrap
capacitor should be a 22 nF to 100 nF ceramic capacitor with a
10 V or greater voltage rating.
Diode Selection
To achieve maximum efficiency, a low-VF Schottky diode is
recommended.
Where ΔIL is the peak-to-peak value of inductor current. Select
a diode with a DC rated current equal to the current RMS of the
diode with an adequate margin for safe use.
Table 8 lists a few recommended Schottky diodes.
Thermal Calculations
There are three types of losses associated with the SKY87608
step-down converter: switching losses, conduction losses, and
quiescent current losses. The conduction losses are associated
with the RDS(ON) characteristics of the internal high-side
MOSFET. The switching losses are dominated by the gate
charge and parasitic capacitance of the high-side MOSFET.
Under full load conditions, the total power loss within the
SKY87608 may be estimated by:
where IQ is the step-down converter quiescent current, and tSW
is the turn-on/off time of the MOSFET used to estimate the full
load step-down converter switching losses. Since on time,
quiescent current, and switching losses all vary with input
voltage, the total power losses within the SKY87608 should be
investigated over the complete input voltage range.
The maximum junction temperature can be derived from the
θJA for the SOP-8L-EP package, which is 41 °C/W.
Layout Considerations
The following guidelines should be used to help ensure a proper
layout.
1. Connect the input capacitor as close as possible to the drain
of the high-side N-channel MOSFET and the anode of the
Schottky diode (and/or source of the low-side N-channel
MOSFET). Keep this loop compact to reduce the switching
noise.
2. Connect COUT and L1 as close as possible. The connection
of L1 to the LX pin should be as short as possible and made
at the source of the high-side N-channel MOSFET for
current-sense accuracy.
3. Separate the feedback trace or FB pin from any power trace
and connect as close as possible to the load point. Sensing
along a high-current load trace degrades DC load regulation.
4. Minimize the resistance of the trace from the load return to
PGND. This helps to minimize any error in DC regulation due
to differences in the potential of the internal signal ground
and the power ground.
5. Connect PGND to the exposed pad to enhance thermal
impedance.
Evaluation Board Description
The SKY87608 Evaluation Board schematic diagram is provided
in Figure 28. The PCB layer detail is shown in Figures 29 and 30.
Component values for the SKY87608 Evaluation Board are listed
in Table 9.
Package Information
Package dimensions and tape & reel dimensions are shown in
Figures 31 and 32.
Table 8. SKY87608 Schottky Diode Selection
VR (V)
VF (V)
IF (A)
Package
Manufacturer
B340A
Part Number
40
0.5 @ 3 A
3
SMA
VISHAY
SS34
40
0.46 @ 3 A
3
SMC
Fairchild
MBRS540
40
0.5 @ 5 A
5
SMC
ON
CMSH5-40
40
0.55 @ 5 A
5
SMC
Central
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PRELIMINARY DATA SHEET • SKY87608 28V, 3A NON-SYNCHRONOUS STEP-DOWN CONVERTER
Figure 28: SKY87608 Standard Application Circuit Schematic
Figure 29: SKY87608 Evaluation Board Top Side Layout
Figure 30: SKY87608 Evaluation Board Bottom Side Layout
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PRELIMINARY DATA SHEET • SKY87608 28V, 3A NON-SYNCHRONOUS STEP-DOWN CONVERTER
Table 9. SKY87608 Standard Application Circuit Bill of Materials (BOM)
Component
Part Number
Description
Manufacturer
U1
SKY87608-11-577LF
Step-down converter
Murata
C1
GRM188R71C103K
Capacitor, ceramic, 10 nF, 0603 X7R, 16 V, 10%
Murata
C2
GRM1885C1H560J
Capacitor, ceramic, 56 pF, 0603 C0G, 50 V, 5%
Murata
C5,C8
GRM188R61H105KAALD
Capacitor, ceramic, 1 µF, 0603 X5R, 50 V, 10%
Murata
C6, C7, C10, C11
GRM32ER7YA106K
Capacitor, ceramic, 10 µF, 1210 X7R, 35 V, 10%
Murata
CBST
GRM188R71C104K
Capacitor, ceramic, 0.1 µF, 0603 X7R, 16 V, 10%
Murata
C12
Not populated
CFF
R1
RC0603FR-073KL
Resistor,3 kΩ, 1/10 W, 1%, 0603 SMD
Yageo
R4
RC0603FR-0791KL
Resistor, 91 kΩ, 1/10 W, 1%, 0603 SMD
Yageo
R5
RC0603FR-0720KL
Resistor, 20 kΩ, 1/10 W, 1%, 0603 SMD
Yageo
R6
RC0603FR-07100KL
Resistor, 100 kΩ, 1/10 W, 1%, 0603 SMD
Yageo
D1
B340A
Diode, 40 V, 3 A, SMA
Vishay
L1
7447715006
Inductor, 6.8 µH, 4.7 A
Wurth Elektronik
Figure 31. SKY87608 8-pin SOP-8L-EP Package Dimensions
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PRELIMINARY DATA SHEET • SKY87608 28V, 3A NON-SYNCHRONOUS STEP-DOWN CONVERTER
Figure 32. SKY87608 Tape and Reel Dimensions
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PRELIMINARY DATA SHEET • SKY87608 28V, 3A NON-SYNCHRONOUS STEP-DOWN CONVERTER
Ordering Information
Model Name
SKY87608 Step Down DC-DC Converter
Manufacturing Part Number (Note 1)
SKY87608-11-577LF
Evaluation Board Part Number
SKY87608-11-577LF-EVB
Note 1: Sample stock is generally held on the part number listed in BOLD.
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