EVBUM2119/D - 482 KB

NCV8851BDBGEVB
NCV8851B Automotive
Grade Synchronous Buck
Controller Evaluation Board
User's Manual
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EVAL BOARD USER’S MANUAL
Description
Key Features
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The NCV8851B Evaluation Board provides a convenient
way to evaluate and integrate a complete high-efficiency
synchronous buck converter design. No additional
components are required, other than dc supplies for the input
voltage and enable pin. The board also can be connected to
an external clock source to synchronize the switching
frequency or for spread spectrum operation. The board is
configured for a 5.0 V output with a 170 kHz switching
frequency and a 4 A current limit, intended for applications
requiring over 3 A of current.
Additionally, modifying the NCV8851B Evaluation
Board for different output voltage, switching frequency or
current limit is straightforward, requiring minimal
component changes.
5.0 V Output Voltage
91% Efficiency at 3 A
4 A Average Current Limit (ACL)
170 kHz Switching Frequency
Average Current Mode Control
Automotive Grade for up to TA = 105°C
Wide Input Voltage Range of 4.5 V to 40 V
Regulates through Load Dump Conditions
1.0 mA Maximum Quiescent Current in Sleep Mode
Programmable Fixed Frequency – 170 kHz to 500 kHz
External Clock Synchronization up to 600 kHz
Easy to Modify for Other Applications
VIN
GND
SYNC
NCV8851B
Output
Inductor
Enable
Output
Capacitor
VOUT
Figure 1. NCV8851B Evaluation Board
© Semiconductor Components Industries, LLC, 2016
February, 2016 − Rev. 2
1
Publication Order Number:
EVBUM2119/D
NCV8851BDBGEVB
Table 1. EVALUATION BOARD TERMINAL DESCRIPTIONS
Terminal
VIN
Function
Positive dc input voltage.
GND
Common dc return.
VOUT
Regulated dc output voltage.
SYNC
Input for external clock synchronization.
EN
Enable input. When disabled, the part enters sleep mode.
Table 2. ABSOLUTE MAXIMUM RATINGS (Voltages are with respect to GND)
Rating
Value
Unit
Dc Supply Voltage (VIN, EN)
Peak Transient Voltage (Load Dump)
−0.3 to 40
45
V
Dc Supply Voltage (SYNC)
−0.3 to 7
V
Junction Temperature (NCV8851B)
−40 to 150
°C
Ambient Temperature (Demo board)
−40 to 105
°C
Stresses exceeding Maximum Ratings may damage the device. Maximum Ratings are stress ratings only. Functional operation above the
Recommended Operating Conditions is not implied. Extended exposure to stresses above the Recommended Operating Conditions may affect
device reliability.
Table 3. ELECTRICAL CHARACTERISTICS (TA = 25°C, 4.5 V v VIN v 40 V, IOUT v 4 A, unless otherwise specified)
Characteristic
Conditions
Typical Value
Unit
Output Voltage
-
5.00
V
Voltage Accuracy
-
4
%
Line Regulation
IOUT = 0 A
0.02
%
Load Regulation
VIN = 13.2 V
0.04
%
VIN = 13.2 V, IOUT = 0 A
170
kHz
VIN = 13.2 V, IOUT = 100 mA, 10-90%
14
ms
SYNC Frequency
-
170 to 600
kHz
Duty Cycle Range
-
5 to 95
%
Average Current Limit
-
4
A
Cycle-by-cycle Overcurrent Protection
-
6.4
A
VIN increasing
4.3
V
VIN = 13.2 V, IOUT = 100 mA
VIN = 13.2 V, IOUT = 1 A
VIN = 13.2 V, IOUT = 4 A
70.7
93.2
90.9
%
Maximum Shutdown Current
-
1.0
mA
Thermal Shutdown
-
180
°C
OUTPUT VOLTAGE
SWITCHING REGULATOR
Switching Frequency
Soft-start Time
CURRENT LIMIT
GENERAL
Input Undervoltage Lockout (UVLO)
Efficiency
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NCV8851BDBGEVB
VIN
VIN
EN
6VOUT
9
12
DBST
11
VIN_IC
+
VIN
BST
3
4
−
CBST
Q1
ROSC
GH
5
20
RS
VSW
ROSC
6
L
Q2
7
SYNC
+
GL
C
VOUT
PGND
1
8
CCOMP
CC2
2
15
CC1
19
RC1
18
−
VIN_CS
CSP
CSN
RF1
VFB
CFB
13
CV2
16
CSOUT
RV1
VCOMP
14
17
10
RF0
CV1
AGND
Figure 2. NCV8851B Application Diagram
Operational Guidelines
1. Connect a dc input voltage, 4.5 V ≤ VBATT ≤ 40 V,
between “VIN” and “GND”.
2. Connect a load impedance between “VOUT” and
“GND”.
3. Connect a dc enable voltage, 4.5 V ≤ EN ≤ VBATT
≤ 20 V, between “EN” and “GND”. If EN must be
tied to a higher voltage, a current limiting resistor
is required (see below).
V
4. Optionally, for external clock synchronization,
connect a pulse source, SYNC, between “SYNC”
and “GND”. The positive amplitude should be
1.0 V ≤ SYNC ≤ 7.0 V and negative amplitude
should be -0.3 V ≤ GND ≤ 0.8 V. SYNC pulse
duty cycle may range from 10% to 90%, and
frequency may range from the programmed
frequency (170 kHz by default) to 600 kHz.
BATT
SYNC
EN
V
OUT
Figure 3. Evaluation Board Connections
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NCV8851BDBGEVB
TYPICAL WAVEFORMS
EN
VSW
VOUT
VOUT
Figure 4. Startup at 170 kHz, 13.2 V to 5 V Output
Figure 5. SWN, VOUT at 170 kHz, 13.2 V to 5 V Output
VSW
VSW
VOUT
VOUT
Figure 6. Minimum Duty Cycle at 170 kHz, 5 V Output
Figure 7. Maximum Duty Cycle at 170 kHz, 5 V Output
SYNC
VSW
VOUT
VSW
Figure 8. SWN, VOUT at 170 kHz, 28 V to 5 V Output
Figure 9. SYNC from 170 to 600 kHz, 13.2 V to 5 V
Output
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NCV8851BDBGEVB
TYPICAL PERFORMANCE
100
VOUT
99.99
%VOUT
(%)
IOUT
99.98
99.97
IOUT (A)
99.96
0
Figure 10. 100 mA to 3.6 A Load Step, 170 kHz, 5 V Output
100
2
3
4
Figure 11. 100 mA to 3.6 A Load Step, 170 kHz,
5 V Output
2.2
100
90
80
1.8
99.8
70
60
1.4
h
50
(%)
(%)
1
PD (W)
40
1.0
99.6
99.4
30
20
10
0.6
99.2
0.2
99
IOUT (A)
0
0
1
2
3
4
5
10
15
20
25
30
35
40
VIN (V)
Figure 12. Efficiency at 170 kHz, 13.2 V to 5 V
Output
Figure 13. Line Regulation at 170 kHz, 13.2 V to 5
V Output
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NCV8851BDBGEVB
SCHEMATIC
Figure 14. NCV8851B Evaluation Board Schematic
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NCV8851BDBGEVB
Table 4. BILL OF MATERIALS
Qty
Ref
Part
Part Description
Manufacturer
Part Number
3
CSW1
0.1mF
0.1mF 50V 10% 0805 X7R ceramic SMD
capacitor
Kemet
C0805C104K5RACTU
CB1
0.1mF
0.1mF 50V 10% 0805 X7R ceramic SMD
capacitor
Kemet
C0805C104K5RACTU
C1
0.1mF
0.1mF 50V 10% 0805 X7R ceramic SMD
capacitor
Kemet
C0805C104K5RACTU
CC1
820pF
820pF 10% 0603 X7R ceramic SMD
capacitor
Murata Electronics
North America
GRM188R71H821KA01D
CV2
820pF
820pF 10% 0603 X7R ceramic SMD
capacitor
Murata Electronics
North America
GRM188R71H821KA01D
1
CC2
100pF
820pF 10% 0603 X7R ceramic SMD
capacitor
Murata Electronics
North America
GCM1885C1H101JA16D
2
CI1
470mF
470mF 63V FK electrolytic SMD
capacitor
Panasonic - ECG
EEVFK1J471M
CI2
470mF
470mF 63V FK electrolytic SMD
capacitor
Panasonic - ECG
EEVFK1J471M
1
CO1
330mF
330mF 10V 20% polymer electrolytic
SMD capacitor
Sanyo Electronic
Components Co.
10TPE330M
1
CV1
2200pF
2200pF 10% 0603 X7R ceramic SMD
capacitor
Panasonic - ECG
ECJ-1VB1H222K
1
C2
1mF
1mF 50V 10% 1206 X7R ceramic SMD
capacitor
Murata Electronics
North America
GCM31MR71H105KA55L
2
C3
1mF
1mF 16V 10% 0603 X7R ceramic SMD
capacitor
Taiyo Yuden
EMK107BJ105KA-TR
C6
1mF
1mF 16V 10% 0603 X7R ceramic SMD
capacitor
Taiyo Yuden
EMK107BJ105KA-TR
DSW1
MBRA160T3
1A, 60 V Schottky SMD rectifier
ON Semiconductor
MBRA160T3G
DB1
MBRA160T3
1A, 60 V Schottky SMD rectifier
ON Semiconductor
MBRA160T3G
JO1
SMB
Vertical PCB mount gold RF connector
jack
Emerson Network
Power Connectivity
Solutions
131-3701-261
2
2
1
1
L1
15mH
15mH SMD power inductor
Wurth
7447709150
2
Q1
NTD5407
40V, 38A N-channel power MOSFET
ON Semiconductor
NTD5407NG
Q2
NTD5407
40V, 38A N-channel power MOSFET
ON Semiconductor
NTD5407NG
1
RC1
60.4k
60.4kW 1% 0.1W 0603 Thick-film SMD
resistor
Yageo Corporation
RC0603FR-0760K4L
1
RC2
4.02k
4.02kW 1% 0.1W 0603 Thick-film SMD
resistor
Yageo Corporation
RC0603FR-074K02L
1
RF0
10.7k
10.7kW 1% 0.1W 0603 Thick-film SMD
resistor
Yageo Corporation
RC0603FR-0710K7L
1
RF1
56.2k
56.2kW 1% 0.1W 0603 Thick-film SMD
resistor
Yageo Corporation
RC0603FR-0756K2L
1
RN1
OPEN
1% 0.1W 0603 Thick-film SMD resistor
1
RO1
51.1k
51.1kW 1% 0.1W 0603 Thick-film SMD
resistor
Yageo Corporation
RC0603FR-0751K1L
2
RSN1
100
100W 1% 0.25W 1206 Thick-film SMD
resistor
Yageo Corporation
RC1206FR-07100RL
RSN2
100
100W 1% 0.25W 1206 Thick-film SMD
resistor
Yageo Corporation
RC1206FR-07100RL
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NCV8851BDBGEVB
Table 4. BILL OF MATERIALS
Qty
Ref
Part
Part Description
Manufacturer
Part Number
1
RS1
25m
25mW 1% 2512 Thick-film SMD current
sense resistor
Vishay/Dale
WSL2512R0250FEA
1
RV1
13.7k
13.7kW 1% 0.1W 0603 Thick-film SMD
resistor
Yageo Corporation
RC0603FR-0713K7L
1
R6
4.7
4.75W 1% 0.1W 0603 Thick-film SMD
resistor
Yageo Corporation
RC0603FR-074R75L
4
TP1
VCC
0.291” X 0.109” Solder terminal turret Ag
over Cu
Mill-Max
Manufacturing
Corporation
2501-2-00-44-00-00-07-0
TP7
VOUT
0.291” X 0.109” Solder terminal turret Ag
over Cu
Mill-Max
Manufacturing
Corporation
2501-2-00-44-00-00-07-0
TP12
PGND
0.291” X 0.109” Solder terminal turret Ag
over Cu
Mill-Max
Manufacturing
Corporation
2501-2-00-44-00-00-07-0
TP13
PGND
0.291” X 0.109” Solder terminal turret Ag
over Cu
Mill-Max
Manufacturing
Corporation
2501-2-00-44-00-00-07-0
TP8
AGND
0.042” Inboard pin
Vector Electronics
K24C
4
1
TP9
AGND
0.042” Inboard pin
Vector Electronics
K24C
TP10
EN
0.042” Inboard pin
Vector Electronics
K24C
TP11
SYNC
0.042” Inboard pin
Vector Electronics
K24C
U1
NCV8851B
Automotive synchronous buck controller
ON Semiconductor
NCV8851BG
EVALUATION BOARD MODIFICATIONS
Connecting EN to a Higher Voltage or VBATT
Changing the switching frequency may impact dynamic
characteristics. Typically, increasing the switching
frequency allows the dynamic response to improve by
further optimization of the compensators; however, it is
advised to analyze dynamic response results of simulation
whenever the switching frequency is modified.
Typically, EN is tied to a logic output or low-voltage
supply. However, EN can be tied to a higher voltage or to
VBATT. In either case, if the supply that EN is tied to is
expected to go above 20 V, a current limiting resistor is
required.
For convenience, RN1 is unpopulated, disconnecting EN
from VBATT (via VIN) by default. To connect EN to VBATT,
populate RN1 with a current limiting resistor. To connect EN
to a separate higher voltage supply from VBATT, place a
current limiting resistor in series with the supply. Consult the
data sheet, NCV8851B/D, for selecting a current limiting
resistor.
Synchronizing to a Higher Frequency
When connecting the SYNC input to a significantly
higher frequency than that set by the program resistor,
dynamic performance could be impaired. Based on
empirical results, it is advised to analyze dynamic response
results of simulation whenever SYNC is more than 33%
higher than the programmed switching frequency.
Programming the Switching Frequency to a Different
Value
Adjusting the Current Limit
The switching frequency is programmed with a resistor,
RO1, from the ROSC pin to GND. By default, the switching
frequency is set to 170 kHz with a 51.1 kW resistor used for
RO1. The frequency can be programmed to a different value
by replacing RO1. Consult the data sheet, NCV8851B/D, for
selecting a different frequency program resistor.
The current limit can be adjusted by using a different sense
resistor for RS1. Consult the data sheet, NCV8851B/D, for
selecting a different current limit.
Changing the sense resistor may impact dynamic
characteristics. It is advised to analyze dynamic response
results of simulation whenever the sense resistor is
modified.
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NCV8851BDBGEVB
Table 5. BOM VARIATIONS
The following list of BOM variations on output voltage and switching frequency have been tested.
3.3 V, 4 A
5 V, 4 A
8 V, 4 A
Part
170kHz
360 kHz
500 kHz
170kHz
360 kHz
500 kHz
170 kHz
360 kHz
500 kHz
Unit
RO1
51.1
23.2
16.2
51.1
23.2
16.2
51.1
23.2
16.2
kW
L1
15
10
10
15
15
10
22
15
15
mH
CO1
330
330
330
330
330
330
330
330
330
mF
RS1
25
25
25
25
25
25
25
25
25
mW
RC1
60.4
60.4
60.4
60.4
60.4
60.4
60.4
60.4
60.4
kW
RC2
4.02
4.02
4.02
4.02
4.02
4.02
4.02
4.02
4.02
kW
CC1
820
820
820
820
820
820
820
820
820
pF
CC2
100
100
100
100
100
100
100
100
100
pF
RV1
13.7
27.4
27.4
13.7
27.4
27.4
13.7
13.7
13.7
kW
RF0
17.4
17.4
8.66
10.7
5.36
3.57
10.0
4.99
3.32
kW
RF1
54.9
54.9
27.4
56.2
28
18.7
90.9
45.3
30.1
kW
CV1
2200
2200
2200
2200
2200
2200
2200
2200
2200
pF
CV2
820
820
820
820
820
820
820
820
820
pF
Selection of components for different operational
configurations than those listed above is beyond the scope
of this document and the data sheet, NCV8851B/D, should
be consulted. Additionally, it is advised to analyze dynamic
response results of simulation whenever variant
components are used.
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NCV8851BDBGEVB
LAYOUT PLOTS
Figure 15. Top Silk Screen
Figure 16. Top Copper
Figure 17. Bottom Copper
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NCV8851BDBGEVB
ON Semiconductor and the
are registered trademarks of Semiconductor Components Industries, LLC (SCILLC) or its subsidiaries in the United States and/or other countries.
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or guarantee regarding the suitability of its products for any particular purpose, nor does SCILLC assume any liability arising out of the application or use of any product or circuit, and
specifically disclaims any and all liability, including without limitation special, consequential or incidental damages. “Typical” parameters which may be provided in SCILLC data sheets
and/or specifications can and do vary in different applications and actual performance may vary over time. All operating parameters, including “Typicals” must be validated for each
customer application by customer’s technical experts. SCILLC does not convey any license under its patent rights nor the rights of others. SCILLC products are not designed, intended,
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