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19-3336; Rev 2; 6/10

KIT

ATION

EVALU

AVAILA

16µA I

, 1.2A PWM

Step-Down DC-DC Converters

General Description

Features

Up to 97% Efficiency

95% Efficiency at 1mA Load Current

Low 16µA Quiescent Current

1MHz PWM Switching

Tiny 3.3µH Inductor

Selectable 3.3V, 2.5V, 1.8V, 1.5V, 1.3V, 1.2V, 1.0V,

and Adjustable Output

1.2A Guaranteed Output Current

(MAX1556/MAX1556A)

Voltage Positioning Optimizes Load-Transient

Response

Low 27µA Quiescent Current in Dropout

Low 0.1µA Shutdown Current

No External Schottky Diode Required

Analog Soft-Start with Zero Overshoot Current

Small, 10-Pin, 3mm x 3mm TDFN Package

MAX1556/MAX1556A/MAX1557

The MAX1556/MAX1556A/MAX1557 are low-operating-

current (16µA), fixed-frequency step-down regulators.

High efficiency, low-quiescent operating current, low

dropout, and minimal (27µA) quiescent current in

dropout make these converters ideal for powering

portable devices from 1-cell Li-ion or 3-cell alkaline/NiMH

batteries. The MAX1556 delivers up to 1.2A; has pin-

selectable 1.8V, 2.5V, and 3.3V outputs; and is also

adjustable. The MAX1557 delivers up to 600mA; has pin-

selectable 1V, 1.3V, and 1.5V outputs; and is also

adjustable.

The MAX1556/MAX1556A/MAX1557 contain a low-on-

resistance internal MOSFET switch and synchronous

rectifier to maximize efficiency and dropout perfor-

mance while minimizing external component count. A

proprietary topology offers the benefits of a high fixed-

frequency operation while still providing excellent effi-

ciency at both light and full loads. A 1MHz PWM

switching frequency keeps components small. Both

devices also feature an adjustable soft-start to minimize

battery transient loading.

The MAX1556/MAX1556A/MAX1557 are available in a

tiny 10-pin TDFN (3mm x 3mm) package.

Ordering Information

PART

MAX1556ETB+

MAX1556AETB+

MAX1557ETB+

TEMP RANGE

PIN-PACKAGE

TOP

MARK

ACQ

AUJ

ACR

Applications

PDAs and Palmtop Computers

Cell Phones and Smart Phones

Digital Cameras and Camcorders

Portable MP3 and DVD Players

Hand-Held Instruments

-40°C to +85°C 10 TDFN-EP*

*EP

= Exposed paddle.

+Denotes

a lead(Pb)-free/RoHS-compliant package.

Typical Operating Circuit

INPUT

2.6V TO 5.5V

OUTPUT

0.75V TO V

INP

TOP VIEW

Pin Configuration

VOLTAGE

SELECT

OFF

MAX1556

MAX1556A

MAX1557

PGND

OUT

GND

OUT

SHDN

TDFN

INP

MAX1556

MAX1556A

MAX1557

PGND

SHDN

GND

________________________________________________________________

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.

16µA I

, 1.2A PWM DC-DC

Step-Down Converters

MAX1556/MAX1556A/MAX1557

ABSOLUTE MAXIMUM RATINGS

IN, INP, OUT, D2,

SHDN

to GND ..........................-0.3V to +6.0V

SS, D1 to GND .............................................-0.3V to (V

+ 0.3V)

PGND to GND .......................................................-0.3V to +0.3V

LX Current (Note 1)...........................................................±2.25A

Output Short-Circuit Duration.....................................Continuous

Continuous Power Dissipation (T

= +70°C)

10-Pin TDFN (derate 24.4mW/°C above +70°C) .......1951mW

Operating Temperature Range ...........................-40°C to +85°C

Junction Temperature ......................................................+150°C

Storage Temperature Range .............................-65°C to +150°C

Lead Temperature (soldering, 10s) .................................+300°C

Soldering Temperature (reflow) .......................................+260°C

Note 1:

LX has internal clamp diodes to GND and IN. Applications that forward bias these diodes should take care not to exceed

the IC’s package power-dissipation limits.

Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional

operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to

absolute maximum rating conditions for extended periods may affect device reliability.

ELECTRICAL CHARACTERISTICS

= V

INP

= V

SHDN

= 3.6V, T

= - 40°C to +85°C. Typical values are at T

= +25°C, unless otherwise noted.) (Note 1)

PARAMETER

Input Voltage

Undervoltage-Lockout Threshold

Quiescent Supply Current

Shutdown Supply Current

Output Voltage Range

No load

300mA load

= 0°C to +85°C

(Note 2)

Output Accuracy

= -40°C to +85°C

(Note 2)

MAX1556/MAX1556A

MAX1557

D1 = D2 = GND

MAX1556/MAX1557

D1 = D2 = GND,

OUT

= 0.75V at

300mA (typ),

= 0°C to +85°C

MAX1556/MAX1557

D1 = D2 = GND,

OUT

= 0.75V

at 300mA (typ),

= -40°C to +85°C

MAX1556/MAX1557

= +25°C

= +85°C

No load

300mA load

600mA load

1200mA load, MAX1556 only

No load

300mA load

600mA load

1200mA load, MAX1556 only

-0.50

-1.2

-1.75

-3.25

-1.25

-1.75

-2.75

-4.25

600mA load

1200mA load, MAX1556

1200mA load, MAX1556A

No load

300mA load

600mA load

1200mA load, MAX1556

Maximum Output Current

-0.75

-1.5

-2.25

-4.0

1200

600

0.01

+0.75

-0.75

-2.25

4.5

+1.75

+1.2

+0.25

-1.25

+2.25

+1.50

+0.25

-1.00

0.1

µA

rising and falling, 35mV hysteresis (typ)

No switching, D1 = D2 = GND

Dropout

SHDN

= GND

= +25°C

= +85°C

0.75

-0.25

-0.75

-1.5

-2.75

+0.75

-0.75

-2.25

+2.25

+1.5

+0.50

-1.0

CONDITIONS

MIN

2.6

2.20

2.35

0.1

+1.75

+0.75

-1.25

TYP

MAX

5.5

2.55

UNITS

µA

OUT Bias Current

For preset output voltages

FB Threshold Accuracy

_______________________________________________________________________________________

16µA I

, 1.2A PWM DC-DC

Step-Down Converters

ELECTRICAL CHARACTERISTICS (continued)

= V

INP

= V

SHDN

= 3.6V, T

= - 40°C to +85°C. Typical values are at T

= +25°C, unless otherwise noted.) (Note 1)

PARAMETER

MAX1556,

D1 = IN, D2 = GND;

MAX1556A

D1 = D2 = IN

MAX1557,

D1 = IN, D2 = GND

MAX1556/MAX1556A

p-Channel On-Resistance

MAX1557

n-Channel On-Resistance

p-Channel Current-Limit

Threshold

n-Channel Zero Crossing

Threshold

RMS LX Output Current

LX Leakage Current

Maximum Duty Cycle

Minimum Duty Cycle

Internal Oscillator Frequency

SS Output Impedance

SS Discharge Resistance

Thermal-Shutdown Threshold

Thermal-Shutdown Hysteresis

LOGIC INPUTS (D1, D2,

SHDN)

Input-Voltage High

Input-Voltage Low

Input Leakage

= +25°C

= +85°C

0.1

2.6V

≤

5.5V

1.4

0.4

µA

∆V

/ I

for I

= 2µA

SHDN

= GND, 1mA sink current

0.9

130

200

+160

MAX1556/MAX1556A

MAX1557

= 5.5V, LX =

GND or IN

= +25°C

= +85°C

100

1.1

300

200

0.1

= 3.6V

= 2.6V

MAX1556/MAX1556A

MAX1557

1.5

0.8

CONDITIONS

= 2.6V to 3.6V

= 3.6V to 5.5V

= 2.6V to 3.6V

= 3.6V to 5.5V

= 3.6V

= 2.6V

= 3.6V

= 2.6V

MIN

TYP

-0.37

0.33

-0.1

0.09

0.19

0.23

0.35

0.42

0.27

0.33

1.8

1.0

2.1

1.2

1.8

1.0

0.48

Ω

RMS

µA

MHz

kΩ

Ω

°C

0.7

0.35

Ω

MAX

UNITS

MAX1556/MAX1556A/MAX1557

Line Regulation

Note 1:

All units are 100% production tested at T

= +25°C. Limits over the operating range are guaranteed by design.

Note 2:

For the MAX1556, 3.3V output accuracy is specified with a 4.2V input.

_______________________________________________________________________________________

16µA I

, 1.2A PWM DC-DC

Step-Down Converters

MAX1556/MAX1556A/MAX1557

Typical Operating Characteristics

= V

INP

= 3.6V, D1 = D2 =

SHDN

= IN, Circuits of Figures 2 and 3, T

= +25°C, unless otherwise noted.)

EFFICIENCY vs. LOAD CURRENT

WITH 3.3V OUTPUT

MAX1556/7 toc01

EFFICIENCY vs. LOAD CURRENT

WITH 2.5V OUTPUT

MAX1556/7 toc02

EFFICIENCY vs. LOAD CURRENT

WITH 1.8V OUTPUT

MAX1556/7 toc03

100

= 4.2V

EFFICIENCY (%)

0.1

100

1000

= 3.6V

= 5V

100

EFFICIENCY (%)

= 5V

= 3.6V

= 3V

= 2.6V

100

EFFICIENCY (%)

= 2.6V

= 5V

= 3.6V

= 3V

10,000

0.1

100

1000

10,000

0.1

100

1000

10,000

LOAD CURRENT (mA)

EFFICIENCY vs. LOAD CURRENT

WITH 1.0V OUTPUT (MAX1557)

MAX1556/7 toc04

OUTPUT VOLTAGE

vs. LOAD CURRENT

MAX1556/7 toc05

OUTPUT VOLTAGE vs. INPUT VOLTAGE

WITH 600mA LOAD

1.788

1.787

OUTPUT VOLTAGE (V)

1.786

1.785

1.784

1.783

1.782

1.781

1.780

1.779

= +85°C

= +25°C

= -40°C

MAX1556/7 toc06

100

EFFICIENCY (%)

= 3.6V

0.1

100

= 3V

= 2.6V

= 5V

1.84

1.83

1.82

OUTPUT VOLTAGE (V)

1.81

1.80

1.79

1.78

1.77

1.76

1.75

1.74

= +85°C

= +25°C

= -45°C

1.789

1000

200

400

600

800

1000

1200

2.5

3.0

3.5

4.0

4.5

5.0

5.5

LOAD CURRENT (mA)

INPUT VOLTAGE (V)

OUTPUT VOLTAGE vs. INPUT VOLTAGE

WITH NO LOAD

MAX1556/7 toc07

SUPPLY CURRENT vs. INPUT VOLTAGE

MAX1556/7 toc08

HEAVY-LOAD SWITCHING WAVEFORMS

MAX1556/7 toc09

1.812

1.811

1.810

OUTPUT VOLTAGE (V)

1.809

1.808

1.807

1.806

1.805

1.804

1.803

2.5

3.0

3.5

4.0

4.5

5.0

= +85°C

= -40°C

= +25°C

SUPPLY CURRENT (µA)

LOAD

= 750mA

OUT

AC-COUPLED

10mV/div

2V/div

500mA/div

400ns

INPUT VOLTAGE (V)

5.5

INPUT VOLTAGE (V)

_______________________________________________________________________________________

16µA I

, 1.2A PWM DC-DC

Step-Down Converters

Typical Operating Characteristics (continued)

= V

INP

= 3.6V, D1 = D2 =

SHDN

= IN, Circuits of Figures 2 and 3, T

= +25°C, unless otherwise noted.)

EXTERNAL FEEDBACK

SWITCHING WAVEFORMS

MAX1556/7 toc10b

MAX1556/MAX1556A/MAX1557

LIGHT-LOAD SWITCHING WAVEFORMS

MAX1556/7 toc10

SOFT-START/SHUTDOWN WAVEFORMS

MAX1556/7 toc11

OUT

20mV/div

AC-COUPLED

2V/div

SHDN

OUT

5V/div

1V/div

= 470pF

LOAD

= 4Ω

2V/div

200mA/div

= 5V, V

OUT

= 3.3V, I

OUT

= 500mA

4µs/div

2µs/div

200mA/div

100µs/div

500mA/div

SOFT-START RAMP TIME vs. C

MAX1556/7 toc12

LOAD TRANSIENT

MAX1556/7 toc13

SOFT-START RAMP TIME (ms)

OUT

50mV/div

AC-COUPLED

500mA/div

OUT

OUTMIN

= 20mA

0.1

500

1000

1500

2000

2500

20µs/div

(pF)

LOAD TRANSIENT

MAX1556/7 toc14

LINE TRANSIENT

MAX1556/7 toc15

BODE PLOT

GAIN (dB)

-10

-20

-30

-40

-50

-60

0.1

OUT

= 22µF, R

LOAD

= 4Ω

FREQUENCY (kHz)

100

0dB

PHASE MARGIN = 53°

MAX1556/7 toc16

240

210

180

PHASE (DEGREES)

150

120

-30

OUT

50mV/div

AC-COUPLED

3.5V

OUT

500mA/div

OUT

OUTMIN

= 180mA

20µs/div

40µs/div

10mV/div

AC-COUPLED

200mA/div

-60

1000

_______________________________________________________________________________________

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以前Mobileye公司合伙创始人兼首席技术官Amnon Shashua坦率地表示：“当人们提到自主驾驶汽车呼之欲出时，其实他们并不知道说的是啥。” 不过，Shashua并非悲观主义者。作为一位企业主管，Shashua表示，“我们不是在等待科学革命，那要等上50年。我们只是在等待一场技术革命。” 开放问题那么，有哪些开放问题仍然需要技术革命来回答呢？现在是时候区分“科研项目”...[详细]
虚拟电池技术将帮助电动汽车将重量锐减25磅

马萨诸塞州安多弗讯—，选择将汽车换成纯电动汽车 (BEV) 的消费者，希望能用大型锂离子电池组为电机供电。此外，他们也可能会惊奇地发现，常规12伏 (12V)电池在处理许多燃油汽车所需的相同功能。这个有些出乎意料的发现，可以解释为汽车制造商正在努力克服一个重大的设计难题：缺乏一个协调的可扩展供电方案，不仅可为电机，而且能为12V长期以来支持的所有汽车子系统供电。电源需求急剧增加加...[详细]
中兴新支点嵌入式操作系统出货2亿套

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消息称谷歌Tensor G5芯片基于台积电3nm制程，已成功进入流片阶段

7 月 1 日消息，台媒《工商时报》近日报道称，预计用于谷歌明年旗舰智能手机的 Tensor G5 芯片将基于台积电 3nm 制程，已成功进入流片阶段。 ▲ 谷歌 Tensor SoC 流片是芯片正式量产前的关键阶段，用小规模的芯片试产检验芯片设计是否正确。对于首次完全自研手机 SoC 的谷歌而言，如果顺利通过流片，那离 Tensor G5 的成功就近了一大步。 Tensor G5 的全自研...[详细]
中移动与苹果谈判无进展 iPhone入华推迟

　　苹果iPhone进入中国内地还需要等待。中国移动总裁王建宙上周五表示，双方的谈判仍在进行，目前并没有达成一致。　　“目前我们还没有任何结论性的东西，也没有任何其他发展。”王建宙表示，谈判签有保密协议，不便对外透露细节。 iPhone自推出后便风靡全球，但是迟迟没有进军中国内地市场，主要是苹果坚持的分成模式难以被中国移动接受。不过今年6月份，中国移动宣称引进苹果iPhone的最...[详细]