MAX16990EVKIT [MAXIM]
3V to 36V, 10A DC power supply;型号: | MAX16990EVKIT |
厂家: | MAXIM INTEGRATED PRODUCTS |
描述: | 3V to 36V, 10A DC power supply |
文件: | 总10页 (文件大小:462K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
Evaluate: MAX16990/MAX16992
MAX16990/MAX16992
Evaluation Kits
General Description
Quick Start
The MAX16990/MAX16992 evaluation kits (EV kits)
are fully assembled and tested PCBs that contain a
16W DC-DC converter for front-end preboost automotive
applications. The devices integrate a low-side FET driver
and current-mode control-loop circuitry for output-voltage
regulation, making them ideal for automotive boost or
SEPIC converters. The MAX16990 integrated driver
switches at 400kHz, while the MAX16992 integrated
driver switches at 2.2MHz using the default configuration.
The MAX16990 can be synchronized with an external
clock source within the 100kHz to 1MHz range, and the
MAX16992 within the 1MHz to 2.5MHz range.
Required Equipment
•
•
•
•
MAX16990 or MAX16992 EV kit
3V to 36V, 10A DC power supply
Digital voltmeter (DVM)
2A load
Output Testing
Each EV kit is fully assembled and tested. Follow the
steps below to verify board operation. Caution: Do not
turn on the power supply until all connections are
completed.
The EV kits operate from a DC supply voltage of 4.5V
(3V in bootstrapped mode) up to 36V. The EV kits can
withstand a 42V load-dump condition for up to 400ms.
Each EV kit demonstrates the device features, such
as dynamic adjustable output voltage, external clock
synchronization, two-phase operation configurability,
cycle-by-cycle current limit, hiccup mode, and thermal
shutdown. The boost converter regulates 8V and can
supply a current up to 2A. Each EV kit includes an exter-
nal p-MOSFET (P1) that can be used to disconnect the
boost output from the load in a fault condition. The EV
kits also demonstrate a reference MAX16990 design for
automotive applications.
1) Verify that a shunt is installed on pins 1-2 on jumper
JU1 (device enabled).
2) Verify that a shunt is installed on jumper JU3 (FB
internal reference).
3) Verify that a shunt is installed on pins 1-2 (normal
mode) or 2-3 (bootstrapped mode) on jumper JU2.
4) Connect the power supply to the VBAT PCB pad and
the power supply’s ground to the PGND PCB pad.
5) Connect DVM across the VOUT and AGND test point.
6) Turn on the power supply and set it to 4.5V.
7) Measure the voltage from the VOUT PCB pad to
AGND and verify that it is 8V.
Features
8) Apply the 2A load on the VOUT or SWITCHED VOUT
PCB pad.
● 4.5V (3V in Bootstrapped Mode) Up to 36V Input
Voltage Range
● 8V Up to 2A Output
● Demonstrates External Clock Synchronization
● Demonstrates SUP UVLO
Ordering Information appears at end of data sheet.
● Demonstrates Cycle-by-Cycle Current Limit and
Hiccup Mode
● Thermal-Shutdown Protection
● PGOOD Flag
● Demonstrates Dynamic Adjustable Output
● Switched Output Option
● Demonstrates Two Phases of Operation
● Proven PCB Layout and Thermal Design
● Fully Assembled and Tested
19-6788; Rev 0; 9/13
Evaluate: MAX16990/MAX16992
MAX16990/MAX16992
Evaluation Kits
fault condition. The EV kits also demonstrate a reference
MAX16990 design for automotive applications.
Detailed Description of Hardware
The MAX16990/MAX16992 EV kits are fully assembled
and tested PCBs that contain a 16W DC-DC converter for
front-end preboost automotive applications. The devices
integrate a low-side FET driver and current-mode control-
loop circuitry for output-voltage regulation, making them
ideal for automotive boost or SEPIC converters. The
MAX16990 integrated driver switches at 400kHz, while
the MAX16992 integrated driver switches at 2.2MHz
using the default configuration. The MAX16990 can be
synchronized with an external clock source within the
100kHz to 1MHz range, and the MAX16992 within the
1MHz to 2.5MHz range.
Enable
The EV kits feature an enable input that can be used to
enable and disable the device and place it in shutdown
mode. To enable the EV kits whenever power is applied
to VIN and PGND, place the jumper on pins 1-2 on jumper
JU1.
To enable the EV kit from an external enable signal, leave
jumper JU1 disconnected. In this configuration, apply a
logic signal on the ENABLE input pad on the EV kit. The
enable (EN) input should not be left unconnected.
Refer to the EN pin description in the MAX16990/
MAX16992 IC data sheet for additional information. See
Table 1 for jumper JU1 settings.
The EV kits operate from a DC supply voltage of 4.5V (3V
in bootstrapped mode) up to 36V. The EV kits can with-
stand a 42V load-dump condition for up to 400ms. Each
EV kit demonstrates the device features such as dynamic
adjustable output voltage, external clock synchronization,
two-phase operation configurability, cycle-by-cycle cur-
rent limit, hiccup mode, and thermal shutdown. The boost
converter regulates 8V and can supply a current up to 2A.
The EV kits include an external p-MOSFET (P1) that can
be used to disconnect the boost output from the load in a
Bootstrap Mode
For applications where the input voltage goes below 4.5V,
use the device in bootstrapped mode, placing the jumper
on pins 2-3 on JU2. In bootstrapped configuration, the
device is supplied by the output of the boost regulator itself
and does not trigger the UVLO, even if the input voltage
goes down to 3V. See Table 2 for jumper JU2 settings.
Table 1. Enable (JU1)
SHUNT POSITION
EN PIN
Connected to SUP
EV KIT OPERATION
Enabled
1-2*
2-3
Connected to AGND
Disabled
Unconnected
Connected to an external controller
External controller enabled
*Default position.
Table 2. Bootstrap Mode (JU2)
SHUNT POSITION
SUP PIN
EV KIT OPERATION
Normal
1-2*
2-3
Connected to SUP
Connected to VOUT
Bootstrapped
*Default position.
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Evaluate: MAX16990/MAX16992
MAX16990/MAX16992
Evaluation Kits
Slave EV kit:
Output-Voltage Adjustment
The output voltage of the device can be dynamically
adjusted, feeding an analog voltage to the REFIN pin.
The external voltage applied to the REFIN pin is used as
FB reference. Remove jumper JU3 to apply an external
voltage to the REFIN pin. With the JU3 jumper installed,
REFIN is shorted to PVL and an internal 1V FB reference
is used for loop regulation. See Table 3 for jumper JU3
settings.
1) Remove R2 and R1.
2) Remove C2, C3, and R5.
3)ꢀ InstallꢀR11ꢀ(0Ω).
Make the following connections:
1) Connect the PGND PCB pad on the master to the
PGND PCB pad on the slave.
2) Connect the AGND PCB pad on the master to the
AGND PCB pad on the slave.
External Clock Synchronization
The device can be synchronized using an external clock
applied to the FSET/SYNC pin. A falling clock edge on
FSET/SYNC turns on the external MOSFET by driving
DRV high after a short delay. The MAX16990 can be
synchronized with an external clock source within the
100kHz to 1MHz range, and the MAX16992 within the
1MHz to 2.5MHz range.
3) Connect the VBAT PCB pad on the master to the
VBAT PCB pad on the slave.
4) Connect the VOUT PCB pad on the master to the
VOUT PCB pad on the slave.
5) Connect the COMP PCB pin on the master to the
COMP pin on the slave through a BNC cable.
6) Connect the SYNCO PCB pin on the master to the
FSET/SYNC pin on the slave.
Two-Phase Configuration
To configure the device in two phases, use two EV kits
and follow the instructions below:
Master EV kit:
1)ꢀ InstallꢀR8ꢀ(1kΩ).
Table 3. Output-Voltage Adjustment (JU3)
SHUNT POSITION
Installed
REFIN PIN
Connected to PVL
Open
EV KIT OPERATION
Internal 1V reference
Not Installed
External voltage reference
*Default position.
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Evaluate: MAX16990/MAX16992
MAX16990/MAX16992
Evaluation Kits
Component Lists
MAX16990 EV Kit
DESIGNATION QTY
DESCRIPTION
Black test point
DESIGNATION QTY
DESCRIPTION
AGND
C1, C7
1
2
3-pin headers, 2.54mm
Sullins PEC36SAAN
JU1, JU2
JU3
2
1
47µF ±10%, 16V X5R ceramic
capacitors (1210)
Murata GRM32ER61C476K
2-pin header, 2.54mm
Sullins PEC36SAAN
4.7µH, 6A inductor
(7mm x 6.9mm)
Würth 744311470
0.068µF ±10%, 16V X7R ceramic
capacitor (0603)
Murata GRM188R71C683K
L1
N1
1
1
2
1
C2
C3
1
1
1
2
1
60V, 10A n-channel MOSFET
(SO8)
Fairchild FDS5670
150pF ±5%, 50V C0G ceramic
capacitor (0603)
Murata GRM1885C1H151J
60V, 115mA, n-channel MOSFETs
(SOT23)
Fairchild 2N7002
47µF, 50V aluminum electrolytic
capacitor (SMD)
Panasonic EEE-1HA470XP
N2, N3
P1
C4
55V, 80A p-channel MOSFET
(D2PAK)
STMicroelectronics STB80PF55
1µF ±10%, 50V X7R ceramic
capacitors (0805)
Murata GRM21BR71H105K
C5, C11
C6
R1
R2
1
1
90.9kΩꢀ±1%ꢀresistorꢀ(0603)
13kΩꢀ±1%ꢀresistorꢀ(0603)
2.2µF ±10%, 10V X7R ceramic
capacitor (0603)
Murata GRM188R71A225K
0.022Ω,ꢀ0.5Wꢀ±1%ꢀcurrent-senseꢀ
resistor (1812)
Panasonic ERJ-L12KF22MU
R3
1
1000pF ±10%, 50V X7R ceramic
capacitor (0603)
C8
C9, C10
C12
1
0
1
Murata GRM188R71H102K
R4
R5
R6
R7
1
1
1
1
1kΩꢀ±1%ꢀresistorꢀ(0603)
6.81kΩꢀ±1%ꢀresistorꢀ(0603)
10kΩꢀ±5%ꢀresistorꢀ(0603)
68.1kΩꢀ±1%ꢀresistorꢀ(0603)
Not installed, ceramic capacitors
(0603)
0.1µF ±10%, 16V X7R ceramic
capacitor (0603)
Murata GRM188R71C104K
R8, R11,
R14, R15
0
Not installed, resistors (0603)
SMA female vertical-mount PCB
Johnson 142-0701-201
COMP
D1
1
1
R9, R12
R10
2
1
1
0Ωꢀ±5%ꢀresistorsꢀ(0603)
4.7kΩꢀ±5%ꢀresistorꢀ(0603)
1kΩꢀ±5%ꢀresistorꢀ(0603)
40V, 5A Schottky diode (SMC)
ON Semi MBRS540T3G
R13
Automotive current-mode boost
controller (12 TQFN-EP*)
Maxim MAX16990ATCE/V+
7.5A, 45V Schottky diode
(D2PAK)
ON Semi MBRB1545CTG
U1
0
1
D2
1
2
—
PCB: MAX16990 EVKIT
18V zener diodes (SOT523)
Diodes Inc. BZX84C18T-7-F
D4, D5
*EP = Exposed pad.
EN, FB,
FSET/SYNC,
PGOOD, PVL,
REFIN, SUP,
SYNCO
8
Red test points
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Evaluate: MAX16990/MAX16992
MAX16990/MAX16992
Evaluation Kits
Component Lists (continued)
MAX16992 EV Kit**
DESIGNATION
QTY
DESCRIPTION
DESIGNATION
QTY
DESCRIPTION
C1, C8
0
Not installed, capacitors
R7
1
12.1kΩꢀ±1%ꢀresistorꢀ(0603)
6200pF ±5%, 50V X7R ceramic
capacitor (0603)
AVX 06035C622JAT2A
Automotive current-mode boost
controller (12 TQFN-EP*)
Maxim MAX16992ATCE/V+
C2
C7
L1
1
1
1
U1
0
1
—
PCB: MAX16990 EVKIT
47µF ±10%, 16V X5R ceramic
capacitor (1210)
Murata GRM32ER61C476K
*EP = Exposed pad.
**Components not listed are the same as for the MAX16990
EV kit.
0.47µH, 18A inductor
(7mm x 6.9mm)
Würth 744314047
Component Suppliers
SUPPLIER
WEBSITE
www.diodes.com
Diodes Incorporated
Murata Americas
www.murataamericas.com
www.onsemi.com
ON Semiconductor
Panasonic Corp.
www.panasonic.com
www.us.st.com
STMicroelectronics
Vishay
www.vishay.com
Würth Electronik GmbH & Co. KG
www.we-online.com
Note: Indicate that you are using the MAX16990 or MAX16992 when contacting these component suppliers.
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Evaluate: MAX16990/MAX16992
MAX16990/MAX16992
Evaluation Kits
Figure 1. MAX16990 EV Kit Schematic
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Evaluate: MAX16990/MAX16992
MAX16990/MAX16992
Evaluation Kits
1.0”
1.0”
Figure 2. MAX16990 EV Kit Component Placement Guide—
Component Side
Figure 3. MAX16990 EV Kit PCB Layout—Component Side
1.0”
Figure 4. MAX16990 EV Kit PCB Layout—PGND Layer 2
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Evaluate: MAX16990/MAX16992
MAX16990/MAX16992
Evaluation Kits
1.0”
1.0”
Figure 6. MAX16990 EV Kit PCB Layout—AGND and PGND
Solder Side
Figure 5. MAX16990 EV Kit PCB Layout—PVL Layer 3
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Evaluate: MAX16990/MAX16992
MAX16990/MAX16992
Evaluation Kits
Ordering Information
PART
TYPE
EV Kit
EV Kit
MAX16990EVKIT#
MAX16992EVKIT#
#Denotes RoHS compliant.
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Evaluate: MAX16990/MAX16992
MAX16990/MAX16992
Evaluation Kits
Revision History
REVISION REVISION
PAGES
CHANGED
DESCRIPTION
NUMBER
DATE
0
9/13
Initial release
—
For pricing, delivery, and ordering information, please contact Maxim Direct at 1-888-629-4642, or visit Maxim Integrated’s website at www.maximintegrated.com.
Maxim Integrated cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim Integrated product. No circuit patent licenses
are implied. Maxim Integrated reserves the right to change the circuitry and specifications without notice at any time.
©
Maxim Integrated and the Maxim Integrated logo are trademarks of Maxim Integrated Products, Inc.
2013 Maxim Integrated Products, Inc.
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