MAX15049EVKIT [MAXIM]

Optional 4.5V to 5.5V Input-Voltage Operation;


型号：	MAX15049EVKIT
厂家：	MAXIM INTEGRATED PRODUCTS
描述：	Optional 4.5V to 5.5V Input-Voltage Operation
文件：	总7页 (文件大小：837K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

19-5149; Rev 0; 1/10

MAX15049 Evaluation Kit

General Description

Features

S Triple-Output Power Supply

VOUT1 (3.3V, 3A)

The MAX15049 evaluation kit (EV kit) is a fully assembled

and tested PCB that demonstrates the capabilities of

the MAX15049. The MAX15049 is a high-performance,

triple-output synchronous buck controller with sequenc-

ing capability. The EV kit requires a 5V to 16V (12V, typ)

DC input-voltage range for normal operation.

VOUT2 (1.8V, 3A)

VOUT3 (1.2V, 6A)

S 5.5V to 16V Input-Voltage Operation (Design

Optimized for 12V Input)

The MAX15049 EV kit outputs are configured for 3.3V,

1.8V, and 1.2V. They provide a load current of 3A, 3A,

and 6A, respectively. The EV kit’s switching frequency

is set to 500kHz, but can be programmed up to 1.2MHz

by replacing a resistor. The EV kit comes configured

for sequencing (MAX15049) and is capable of prebias

startup. The EV kit can also be used to evaluate the

MAX15048 for tracking applications by changing a few

components. The PGOOD logic signal output pad is

provided for circuit monitoring.

S Optional 4.5V to 5.5V Input-Voltage Operation

S 500kHz Switching Frequency per Converter

S Programmable Switching Frequency Up to 1.2MHz

S Sequencing Operation (Tracking Possible with

Component Changes)

S PGOOD Power Monitoring

S Small 1.5in x 1in Circuit Footprint

S 92.8% Peak Efficiency for OUT1

S Fully Assembled and Tested

The MAX15049 EV kit comes with a MAX15049ETJ+

installed. To evaluate the MAX15048, contact the factory

for samples of the pin-compatible MAX15048ETJ+.

Ordering Information

PART

TYPE

MAX15049EVKIT+

EV Kit

+Denotes lead(Pb)-free and RoHS compliant.

Component List

DESIGNATION

QTY

DESCRIPTION

DESIGNATION

QTY

DESCRIPTION

22FF Q20%, 16V X5R ceramic

capacitors (1206)

Murata GRM31CR61C226M

22pF Q5%, 50V C0G ceramic

capacitors (0402)

Murata GRM1555C1H220J

C1, C8, C9,

C18, C19, C38

C12, C23, C30

1FF Q10%, 16V X5R ceramic

capacitor (0603)

Murata GRM188R61C105K

1500pF Q10%, 50V X7R

ceramic capacitors (0402)

Murata GRM155R71H152K

C13, C21, C32

C14, C24

Not installed, ceramic

capacitors (0402)

C5, C7, C15,

C17, C25, C26,

C35

0.1FF Q10%, 16V X5R ceramic

capacitors (0402)

Murata GRM155R61A104K

100FF Q20%, 6.3V X5R ceramic

capacitors (1210)

Murata GRM32ER60J107M

C27, C28

10FF Q10%, 16V X5R ceramic

capacitors (0805)

Murata GRM21BR61C106K

C6, C16

C10, C20

C11, C22

220pF Q10%, 10V X7R ceramic

capacitor (0402)

Murata GRM155R61A103K

C29

C31

0.1FF Q10%, 16V X7R ceramic

capacitors (0603)

Murata GRM188R71C104K

680pF Q10%, 50V X7R ceramic

capacitor (0402)

Murata GRM155R71H681K

330pF Q5% 50V C0G ceramic

capacitors (0402)

Murata GRM1555C1H331J

_______________________________________________________________ Maxim Integrated Products

For pricing, delivery, and ordering information, please contact Maxim Direct at 1-888-629-4642,

or visit Maxim’s website at www.maxim-ic.com.

MAX15049 Evaluation Kit

Component List (continued)

DESIGNATION

QTY

DESCRIPTION

DESIGNATION

R1, R7, R13

R2, R8, R19

QTY

DESCRIPTION

0I Q5% resistors (0402)

Not installed, resistors (0402)

1FF Q10%, 6.3V X5R ceramic

capacitor (0402)

C33

Murata GRM155R60J105K

R3, R9, R16,

R18

24.9kI Q1% resistors (0402)

2.2FF Q20%, 6.3V X5R ceramic

capacitor (0402)

Murata GRM155R60J225M

C34

R4, R10, R17

15kI Q1% resistors (0402)

1kI Q1% resistors (0402)

5.49kI Q1% resistor (0402)

12.4kI Q1% resistor (0402)

20I Q5% resistor (0402)

499I Q1% resistor (0402)

2.2I Q5% resistor (0402)

39.2kI Q1% resistor (0402)

20kI Q5% resistor (0402)

10kI Q1% resistors (0402)

4.99kI Q1% resistor (0402)

2.49kI Q1% resistor (0402)

59kI Q1% resistor (0402)

Not installed, resistor (0603)

R5, R11

1000pF Q10%, 50V X7R

ceramic capacitors (0402)

Murata GRM155R71H102K

C36, C37, C39

R12

R14

R15

EN1, EN2, EN3,

PGOOD, REG,

SGND

R20

1-pin headers

R21

R22

JU1

Not installed, 2-pin header

R23, R24, R28

R25

3.3FH, 7A, 26mI inductors

Vishay IHLP2525CZER3R3M07

L1, L2

R26

1FH, 14.1A, 7.1mI inductor

TDK SPM6530T-1R0M120

R27

R29

30V dual n-channel

N1, N2

PowerTrench MOSFETs (MLP)

Fairchild FDMC8200

Triple-output buck controller

(32 TQFN–EP*)

Maxim MAX15049ETJ+

9.1A/11A, 30V dual n-channel

MOSFET (SO8)

International Rectifier

IRF7907PbF

PCB: MAX15049 EVALUATION

KIT+

—

*EP = Exposed pad.

Component Suppliers

SUPPLIER

Fairchild Semiconductor

International Rectifier

Murata Electronics North America, Inc.

TDK Corp.

PHONE

WEBSITE

www.fairchildsemi.com

www.irf.com

888-522-5372

310-322-3331

770-436-1300

847-803-6100

402-563-6866

www.murata-northamerica.com

www.component.tdk.com

www.vishay.com

Vishay

Note: Indicate that you are using the MAX15049 when contacting these component suppliers.

______________________________________________________________________________________

MAX15049 Evaluation Kit

Quick Start

Required Equipment

Detailed Description of Hardware

The MAX15049 EV kit is a fully assembled and tested

PCB that demonstrates the MAX15049, which inte-

grates three high-performance PWM switching step-

down DC-DC controllers. The EV kit circuit operates over

the input-voltage range of 4.7V to 16V. The three outputs

are configured for 3.3V, 1.8V, and 1.2V and can provide

3A, 3A, and 6A, respectively. The EV kit outputs operate

in sequencing mode during startup and the three outputs

operate 120 degrees out of phase. The EV kit outputs

can start into prebiased loads. The EV kit switching fre-

quency is set to 500kHz with resistor R21. The switching

frequency can be programmed from 200kHz to 1.2MHz

by replacing this resistor. The EV kit has a PGOOD out-

put pad to indicate that all outputs have reached their

steady-state values. The EV kit PCB is designed in four

layers and 2oz copper for optimum performance.

•ꢀ MAX15049ꢀEVꢀkit

•ꢀ 12V,ꢀ10Aꢀpowerꢀsupply

•ꢀ Fourꢀvoltmeters

Procedure

The MAX15049 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.

1) Verify that U1 is installed on the bottom side of the

PCB.

2) Connect the positive terminal of voltmeter 1 (VM1)

to the OUT1 pad. Connect the negative terminal of

VM1 to the GND1 pad.

3) Connect the positive terminal of voltmeter 2 (VM2)

to the OUT2 pad. Connect the negative terminal of

VM2 to the GND2 pad.

Input Source

The MAX15049 EV kit is configured for normal operation

with an input power source of 4.7V to 16V and design

optimized for a 12V input voltage. The upper input-

voltage limit can be raised to 23V by replacing capaci-

tors C1, C2, C6, C16, and C38 with higher voltage-rated

capacitors. The EV kit circuit requires a minimum 4.7V

input voltage to start the power MOSFET switching.

4) Connect the positive terminal of voltmeter 3 (VM3)

to the OUT3 pad. Connect the negative terminal of

VM3 to the GND3 pad.

5) Connect the positive terminal of voltmeter 4 (VM4)

to PGOOD (TP8) and the negative terminal to the

PGND pad.

MAX15049 Bias Input

The MAX15049 EV kit features an option to select the

bias input for the MAX15049 when configuring the EV kit

to operate with an input source less than 4.7V. Jumper

JU1 shorts the input-voltage source for the MAX15049 to

the controller REG pin. Without JU1 installed, the input-

voltage range in this configuration is 4.7V to 16V.

6) Set the power supply to 12V and disable the output.

7) Connect the positive terminal of the power supply

to the VIN pad. Connect the negative terminal of the

power supply to the PGND pad.

8) Turn on the power supply.

9) Verify that the VOUT1, VOUT2, and VOUT3 outputs

measure 3.3V, 1.8V, and 1.2V, respectively.

When operating the MAX15049 EV kit with a supply

between 4.5V to 5.5V, install jumper JU1.

10) Verify that PGOOD measures approximately 5V.

11) The EV kit is now ready for load testing. Use the

respective OUT_ connector load points for high-

current load testing.

Table 1. MAX15049 Bias Input Configuration (JU1)

SHUNT POSITION

MAX15049 IN PIN

Connected to REG

Connected to VIN

MAX15049 EV KIT INPUT RANGE (V)

Installed

4.5 to 5.5

4.7 to 16

Not installed

_______________________________________________________________________________________

MAX15049 Evaluation Kit

Triple Outputs

The MAX15049 EV kit’s three outputs are configured to

different voltages. The bottom side of the PCB contains

the IC and the feedback and compensation compo-

nents. The top side of the PCB contains the input/output

capacitors, inductors, and FETs. OUT1 is configured to

3.3V with resistors R3 and R6 and can supply up to 3A.

OUT2 is configured to 1.8V with resistors R9 and R12

and can supply up to 3A. OUT3 is configured to 1.2V

with resistors R16 and R18 and can supply up to 6A.

The output voltage for each output can be reconfigured

between 0.6V and 3.3V by replacing the respective feed-

back resistors. Refer to the Type III: Compensation When

Switching Frequency

The MAX15049 PWM switching frequency is set to appro-

ximately 500kHz with resistor R21 (39.2kI). Replace

resistor R21 with a new resistor value to progam the

switching frequency between 200kHz and 1.2MHz. Use

the following equation to choose the appropriate resistor

value to reconfigure the switching frequency (f ):

kHz = 12.8×R21 kΩ

(

)

(

)

Evaluating the MAX15048 (Tracking)

The MAX15049 EV kit comes configured for sequencing.

The EV kit can also evaluate the MAX15048 for tracking

applications. The MAX15049 IC must be replaced with

the MAX15048. It also requires modification at EN2

(pin 9) and EN3 (pin 24) for tracking operation with

the MAX15048. Refer to the MAX15048 Coincident/

Ratiometric Tracking (EN_) section in the MAX15048/

MAX15049 IC data sheet to calculate the proper values

for resistors R23–R26 and R29.

< ƒ

section in the MAX15048/MAX15049

ZERO, ESR

IC data sheet for instructions on selecting new resis-

tor values for the respective outputs. Also, refer to the

Inductor Selection and Input-Capacitor Selection sec-

tions in the IC data sheet to verify other component

replacements for proper operation when changing the

output voltage.

Current Limit

PGOOD Status Output

The MAX15049 EV kit provides a PGOOD logic output to

indicate the regulation state of OUT1, OUT2, and OUT3.

A logic-low at TP8 (PGOOD test point) indicates that one

of the output voltages has dropped below 92% of its

regulation voltage.

The MAX15049 EV kit uses the low-side MOSFET DC

on resistance (R

) for valley current sensing. The

current-limit threshold is 69mV internally set inside

the MAX15049. The MAX15049 compares the voltage

DSON

across the low-side MOSFET (R

) with the internal

DSON

threshold to incorporate the current limit. OUT1 and

OUT2 use the FDMC8200 FET with a low-side R of

Individual EN_ Input

The MAX15049 EV kit provides an individual enable test

point for each output. The EV kit comes configured for

sequencing and connections so the enable test points

are not needed. To disable sequencing and externally

control each output, remove the sequencing compo-

nents (R23–R28) and apply a voltage on the EN_ test

point.

DSON

9.5mI(typ) and 13.5mI(max). The current-limit thresh-

old is 69mV (typ) and the output current limit calculated

is approximately 6A. The IRF7907 FET has similar char-

acteristics with a 9.1mI(typ) and 13.7mI(max) R

DSON

and therefore, a similar current limit.

______________________________________________________________________________________

MAX15049 Evaluation Kit

Figure 1. MAX15049 EV Kit Schematic

_______________________________________________________________________________________

MAX15049 Evaluation Kit

1.0”

Figure 2. MAX15049 EV Kit Component Placement Guide—

Component Side

Figure 3. MAX15049 EV Kit PCB Layout—Component Side

1.0”

Figure 4. MAX15049 EV Kit PCB Layout—Layer 2 (Ground

Layer)

______________________________________________________________________________________

MAX15049 Evaluation Kit

1.0”

Figure 5. MAX15049 EV Kit PCB Layout—Layer 3

(Power Layer)

Figure 6. MAX15049 EV Kit PCB Layout—Solder Side

1.0”

Figure 7. MAX15049 EV Kit Component Placement Guide—

Solder Side

Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are implied.

Maxim reserves the right to change the circuitry and specifications without notice at any time.

Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600

2010 Maxim Integrated Products

Maxim is a registered trademark of Maxim Integrated Products, Inc.

MAX15049EVKIT [MAXIM]

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