Maxim MAX17557EVKIT Operates from a 6.5v to 60v input supply Datasheet

Evaluates: MAX17557 5V
Output-Voltage Application
MAX17557 5V Output Evaluation Kit
General Description
The MAX17557 5V-output evaluation kit (EV kit) provides
a proven design to evaluate the MAX17557 high-voltage,
high-efficiency, synchronous step-down DC-DC controller.
The EV kit provides 5V/10A at the output from a 6.5V to
60V input supply. The switching frequency of the EV kit is
preset to 350kHz for optimum efficiency and component
size. The EV kit features Enable/UVLO Input, resistorprogrammable UVLO threshold, adjustable soft-start time,
open-drain PGOOD output, and overcurrent and overtemperature protection.
Features
●● Operates from a 6.5V to 60V Input Supply
●● 5V Output Voltage
Quick Start
Recommended Equipment
●● MAX17557 5V-output EV kit
●● 6.5V to 60V, 10A DC-input power supply
●● Load capable of sinking 10A
●● Digital voltmeter (DVM)
Procedure
The EV kit is fully assembled and tested. Follow the steps
below to verify the board operation. Caution: Do not turn
on power supply until all connections are completed.
1)
2)
●● Up to 10A Output Current
●● 350kHz Switching Frequency
●● Enable/UVLO Input, Resistor-Programmable UVLO
Threshold
●● Adjustable Soft-Start Time
●● Open-Drain PGOOD Output
●● Overcurrent (OCP) and Overtemperature (OTP)
Protection
●● Proven PCB Layout
●● Fully Assembled and Tested
Ordering Information appears at end of data sheet.
319-100068; Rev 0; 8/17
3)
4)
5)
6)
7)
Set the power supply at a voltage between 6.5V and
60V. Disable the power supply.
Connect the positive terminal of the power supply
to the VIN PCB pad and the negative terminal to the
nearest PGND PCB pad. Connect the positive terminal of the 10A load to the VOUT PCB pad and the
negative terminal to the nearest PGND PCB pad.
Connect the DVM across the VOUT PCB pad and
the nearest PGND PCB pad.
Place the shunt on the jumpers JU1, JU3, and JU4
according to the intended operation (see Tables 1, 2,
and 3 for details).
Turn on the DC power supply.
Enable the load.
Verify that the DVM displays 5V.
Evaluates: MAX17557 5V
Output-Voltage Application
MAX17557 5V Output Evaluation Kit
Detailed Description of Hardware
The MAX17557 5V-output evaluation kit (EV kit) is a
proven design to evaluate the MAX17557 high-voltage,
high-efficiency, synchronous step-down DC-DC controller.
The EV kit provides 5V/10A at the output from a 6.5V to
60V input supply. The switching frequency of the EV kit is
preset to 350kHz for optimum efficiency and component
size. The EV kit features current sensing using either an
external current-sense resistor for accuracy or an inductor DCR for improved system efficiency. Current foldback
limits MOSFET power dissipation under short-circuit conditions. The EV kit includes an EN/UVLO PCB pad and
jumperJU4 to enable the output at a desired input voltage.
A PGOOD PCB pad is available for monitoring when the
converter output is in regulation.
Setting the Input Undervoltage Lockout Level
The EN pin can be open or pulled up to a voltage between
1.25V and 5.5V to turn on the controller. Figure 1 shows the
possible configurations. The EN pin can be used as input
undervoltage lockout detector with a typical hysteresis of
100mV. As shown in Figure 1, the input voltage at which
the controller of the IC turns on, can be set with a resistordivider connected to EN from IN to GND. Select R2 = 10kΩ
and calculate R1 based on the following equation:
R1
= R2 ×
1.25
where VINUVLO is the input voltage at which the controller
should be enabled.
VIN_MIN TO VIN_MAX
4.5V TO 60V
(VIN_UVLO − 1.25)
IN
IN
R1
MAX17557
MAX17557
EN
R2
EN
ENABLE AS INPUT UVLO
ALWAYS-ON CONFIGURATION
VIN_MAX / VIN_MIN ≤ 4.4
4.5V TO 60V
VIN_MIN TO VIN_MAX
IN
IN
R1
MAX17557
MAX17557
EN
>1.25V
D1
4.7V
EN
TURN ON/OFF BY
LOGIC SIGNAL
R2
ENABLE AS INPUT UVLO
VIN_MAX / VIN_MIN ≥ 4.4
Figure 1. Setting the Input Under Voltage Lockout
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Maxim Integrated │ 2
Evaluates: MAX17557 5V
Output-Voltage Application
MAX17557 5V Output Evaluation Kit
Adjusting Output Voltage
The output voltage of the converter is set by connecting a
resistor-divider to FB from the output to GND (Figure 2).
Select R3 using the following equation, based on the offset introduced on the output voltage by the FB leakage.
Let α be the offset introduced on the output voltage:
R3 ≤
VOUT
R3
MAX17557
FB
α
IFB_
R4
where:
α = offset introduced on the output voltage
IFB = FB leakage current (±100nA max)
Figure 2: Adjusting Output Voltage
For example, for VOUT = 5V, α = 0.1% of VOUT (= 5mV).
Frequency Selection (RT)
R3 ≤ 50kΩ
Calculate R4 with the following equation:
R4 =
R1
V
 OUT

 0.8 − 1


Soft-Start Capacitor Selection
Soft-start time is programmed by connecting a capacitor
from the SS pin to GND. An internal 5µA current source
charges the capacitor at the SS pin providing a linear
ramping voltage for output-voltage reference. The softstart time is calculated based on the following equation:
t=
SS C SS ×
0.8V
5µA
The selection of switching frequency is a tradeoff between
efficiency and component size. Low-frequency operation increases efficiency by reducing MOSFET switching losses and gate-drive losses, but requires a larger
inductor and/or capacitor to maintain low output-ripple
voltage. The switching frequency of the device can be
programmed between 100kHz and 2.2MHz using the RT
pin. Connect a resistor from RT to GND to set the regulator’s switching frequency. Leave RT open for the default
350kHz frequency. The following formula can be used to
find the required resistor for a given switching frequency.
=
R RT
19 × 10 3
− 1.7
f SW
where RRT is in kΩ and fSW is in kHz. Leaving the RT pin
open causes the device to operate at the default switching
frequency of 350kHz.
Table 1. JU1: Switching Frequency Selection Jumper
JUMPER
SHUNT POSITION
Not Installed
JU1
1-2
2-3
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R3
RT
MAX17557 SWITCHING
FREQUENCY
Not installed
Unconnected
Default 350kHz
R3 is used
Connected to GND through R3
fSW = (19000) / (RRT + 1.7)
X
Connected to VCCINT
Default 350kHz
Controller does not start
Maxim Integrated │ 3
Evaluates: MAX17557 5V
Output-Voltage Application
MAX17557 5V Output Evaluation Kit
Table 2. JU3: Overcurrent Protection Mode Select
JUMPER
SHUNT POSITION
ILIMSEL
1-2
Connected to VCCINT
Latch-off Mode
2-3
Connected to GND
Foldback Mode
JU3
MODE
Table 3. JU4: Controller Enable (EN/UVLO) Description
JUMPER
SHUNT POSITION
EN
MAX17557 OUTPUT
Not installed
Unconnected
Enabled
1-2
Connected to the input UVLO divider
midpoint.
Enabled, UVLO level is set by the
resistor divider from VIN to GND.
2-3
Connected to GND
Disabled
JU4
MAX17557 EV Kit Performance Report
VIN = 24V, unless otherwise noted,
100
LOAD AND LINE REGULATION
5V OUTPUT
EFFICIENCY vs. LOAD CURRENT
5V OUTPUT
toc01
90
5.11
VIN = 12V
5.10
OUTPUT VOLTAGE(V)
EFFICIENCY(%)
80
VIN = 60V
70
VIN = 48V
60
VIN = 36V
50
VIN = 24V
40
30
0.01
toc02
5.12
VIN = 6.5V
0.1
1
5.08
VIN = 24V
5.07
5.06
VIN = 12V
5.05
5.04
10
VIN = 48V
VIN = 6.5V
5.09
LOAD CURRENT(A)
VIN = 60V
VIN = 36V
0
5
10
LOAD CURRENT (A)
SOFT-START WITH 2.5V
PREBIAS, 5V OUTPUT
SOFT-START/SHUTDOWN FROM
EN/UVLO 5V OUTPUT
toc03
toc04
5V/div
VEN/UVLO
5V/div
VOUT
2V/div
IOUT
10A/div
5V/div
VPGOOD
VEN/UVLO
1V/div
VOUT
5V/div
VPGOOD
2ms/div
1ms/div
CONDITIONS: 10A LOAD CURRENT
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Maxim Integrated │ 4
Evaluates: MAX17557 5V
Output-Voltage Application
MAX17557 5V Output Evaluation Kit
MAX17557 EV Kit Performance Report (continued)
VIN = 24V, unless otherwise noted,
LOAD TRANSIENT RESPONSE
5V OUTPUT
toc05
VOUT
(AC)
100mV/div
IOUT
5A/div
200µs/div
CONDITIONS: LOAD CURRENT STEPPED
FROM 5A TO 10A
5V OUTPUT BODE PLOT
CONDITIONS:10A LOAD CURRENT
LOAD TRANSIENT RESPONSE
5V OUTPUT
toc07
toc06
IOUT
5A/div
400µs/div
CONDITIONS: LOAD CURRENT STEPPED
FROM 0.1A TO 5A
PHASE
PHASE(°)
200mV/div
GAIN (dB)
VOUT
(AC)
GAIN
CROSSOVER
FREQUENCY = 24.5kHz,
PHASE MARGIN = 64.6°
103
104
105
FREQUENCY (Hz)
Component List
SUPPLIER
WEBSITE
Coilcraft, Inc.
www.coilcraft.com
Murata Americas
www.murataamericas.com
Panasonic Corp.
www.panasonic.com
Renesas Electronics
www.renesas.com
Diode Inc.
www.diodes.com
Note: Indicate that you are using the MAX17557 when contacting these component suppliers.
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Maxim Integrated │ 5
Evaluates: MAX17557 5V
Output-Voltage Application
MAX17557 5V Output Evaluation Kit
Ordering Information
PART
TYPE
MAX17557EVKIT#
EVKIT
MAX17557 EV System Bill of Materials
No.
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
Description
0.1µF 10%, 100V ,X7R,Ceramic capacitor (0603)
4.7µF 20%, 80V ,X7R,Ceramic capacitor (1210)
150µF,20%,80V,ELECT,13mm
1µF 10%, 16V ,X7R,Ceramic capacitor (0603)
10µF 10%, 10V ,X7R,Ceramic capacitor (0805)
15000pF,10%,50V,X7R,0402,Ceramic capacitor(0402)
0.47µF,10%,10V,X7R, Ceramic capacitor(0402)
0.1µF,10%,50V,X7R, Ceramic capacitor(0402)
180µF 20%, 6.3V ,X7R,Ceramic capacitor (1210)
10µF 10%, 10V ,X7R,Ceramic capacitor (1210)
1000pF,10%,100V,X7R,0402,Ceramic capacitor(0402)
10nF,10%,50V,X7R,0402,Ceramic capacitor(0402)
120pF,2%,50V,X7R,0402,Ceramic capacitor(0402)
Diode PIV=100V; IF=1A
3-pin header (36-pin header 0.1” centers )
INDUCTOR, 3.3µH, 19.4A
N-CHANNEL POWER MOSFET(LFPAK) PD-(45W); I-(25A);
17
V-(60V)
N-CHANNEL POWER MOSFET(LFPAK) D-(65W); I-(45A); V18
(60V)
Quantity
2
2
1
1
1
1
1
1
1
2
1
1
1
1
1
1
Designator
C1,C2
C3,C4
C5
C6
C7
C8
C9
C10
C11
C13,C14
C15
C18
C19
D1
JU1,JU3,JU4
L1
1
Q1
RENESAS RJK0651DPB-00#J5
1
Q2
RENESAS RJK0653DPB-00#J5
19
RES+,0Ω,1%,0402
8
20
21
22
23
24
25
RES+,2.2Ω,1%,0402
RES+,0.005Ω,1%,1.5W,2010
RES+,7.5KΩ OHM,1%,0402
RES+,100KΩ OHM,1%,0402
RES+,95.3KΩ OHM,1%,0402
RES+,17.8KΩ OHM,1%,0402
Buck Controller
MAX17557ATP+
1
1
1
1
1
1
R1, R4, R7, R9, R12-R14,
R19
R2
R8
R17
R18
R20
R21
1
U1
26
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Part Number
MURATA GRM188R72A104KA35
MURATA GRM32ER71K475ME14
PANASONIC EEV-FK1K151Q
MURATA GRM188R71C105KA12
MURATA GGRM21BR71A106KE51
MURATA GRM155R71H153KA12
MURATA GRM155R61A474KE15
MURATA GRM155R71H104KE14
PANASONIC EEFSE0J181R
MURATA GRM32DR71A106KA01
MURATA GRM155R72A102KA01
MURATA GRM155R71H103JA88
MURATA GRM1555C1H121GA01
DIODES INCORPORATED DFLS1100-7
Sullins: PEC03SAAN
COILCRAFT XAL7070-332ME
MAX17557ATP+
Maxim Integrated │ 6
VIN
EN
R5
OPEN
1
JU4
R6
OPEN
A
OPEN
D1
2
3
C
JU1
7.5K
R17
JU3
1
2
3
R3
1
2
3
OPEN
120PF
C19
C18
0.01UF
VCCINT
1000PF
C15
VCCINT
C8
0.015UF
COMP
5
SGND
TEST2
4
EN
GND
20
ILIMSEL
8
TEST1
RT
SS
3
2
7
1
FB
PGOOD
CSN
CSP
PGND
DL
LX
BST
DH
VCCINT
IN
VCCEXT
PGND
MAX17557
U1
6
10
19
16
9
12
15
11
13
14
17
18
0
R7
C6
1UF
2.2
R2
VOUT
C1
0
R9
C9
0.47UF
D2
C16
R18
0
4
C2
0.1UF
D
G S
VCCINT
PGOOD
C
Q2
R4
100K
OPEN
A
VCCINT
10UF
C7
VCCINT
0.1UF
0
1000PF
C17
Q1
OPEN
4
C3
4.7UF
VIN
4.7UF
C4
G S
D
5
1
L1
3.3UH
R16
OPEN
0
R11
OPEN
R10
R14
1
C5
150UF
+
2
OPEN
1
2
3
VCCINT
EP
21
5
1
2
3
2
R12
PGND
VIN
R13
0.005
R8
C10
0.1UF
C11
180UF
1
+
2
C12
OPEN
1
+
2
VIN
0
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C13
10UF
10UF
C14
VOUT
PGND
R21
17.8K
95.3K
R20
VOUT
5V@10A
R19
0
0
R1
MAX17557 5V Output Evaluation Kit
Evaluates: MAX17557 5V
Output-Voltage Application
MAX17557 EV System Schematic
Maxim Integrated │ 7
Evaluates: MAX17557 5V
Output-Voltage Application
MAX17557 5V Output Evaluation Kit
MAX17557 EV System PCB Layout
1”
1”
MAX17557 EV Kit Silk Top
MAX17557 EV Kit Top
1”
MAX17557 EV Kit L2-GND
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Maxim Integrated │ 8
Evaluates: MAX17557 5V
Output-Voltage Application
MAX17557 5V Output Evaluation Kit
MAX17557 EV System PCB Layout (continued)
1”
MAX17557 EV Kit L3-GND
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1”
MAX17557 EV Kit Bottom
Maxim Integrated │ 9
Evaluates: MAX17557 5V
Output-Voltage Application
MAX17557 5V Output Evaluation Kit
Revision History
REVISION
NUMBER
REVISION
DATE
0
8/17
DESCRIPTION
Initial release
PAGES
CHANGED
—
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