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LTC1553L

5-Bit Programmable

Synchronous Switching

Regulator Controller for

Pentium

II Processor

FEATURES

DESCRIPTION

The LTC

1553L is a high power, high efficiency switching

regulator controller optimized for a 5V input to 1.8V-3.5V

output applications. It features a digitally programmable

output voltage, a precision internal reference and an internal

feedback system that provides output accuracy of

±1.5%

room temperature and typically

±2%

over-temperature, load

current and line voltage shifts. The LTC1553L uses a syn-

chronous switching architecture with two external N-channel

output devices, providing high efficiency and eliminating the

need for a high power, high cost P-channel device. Addition-

ally, it senses the output current across the on-resistance of

the upper N-channel FET, providing an adjustable current

limit without an external low value sense resistor.

The LTC1553L free-runs at 300kHz and can be synchronized

to a faster external clock if desired. It includes all the inputs

and outputs required to implement a power supply conform-

ing to the

Intel Pentium

II Processor VRM 8.2 DC/DC

Converter Specification.

, LTC and LT are registered trademarks of Linear Technology Corporation.

Pentium is a registered trademark of Intel Corporation.

5-Bit Digitally Programmable 1.8V to 3.5V Fixed

Output Voltage

Provides All Features Required by the

Intel

Pentium

II Processor VRM 8.2 DC/DC

Converter Specification

Flags for Power Good, Over-Temperature and

Overvoltage Fault

19A Output Current Capability from a 5V Supply

Dual N-Channel MOSFET Synchronous Driver

Initial Output Accuracy:

±1.5%

Excellent Output Accuracy:

±2%

Typ Over Line,

Load and Temperature Variations

High Efficiency: Over 95% Possible

Adjustable Current Limit Without External Sense

Resistors

Fast Transient Response

Available in 2O-Lead SSOP and SW Packages

APPLICATIONS

Power Supply for Pentium II, SPARC, ALPHA and

PA-RISC Microprocessors

High Power 5V to 1.8V-3.5V Regulators

TYPICAL APPLICATION

0.1µF

5.6k

MAX

10µF

2.7k

12V

0.1µF

10µF

PWRGD

PENTIUM II

SYSTEM

20Ω

Q1*

†

2µH

18A

OUT

††

330µF

OUT

1.8V TO

3.5V

14A

FAULT

VID0 TO VID4

OUTEN

COMP

150pF

8.2k

0.01µF

SGND

GND

SENSE

LTC1553L

0.1µF

*SILICONIX SUD50N03-10

**SANYO 10MV1200GX

†

COILTRONICS CTX02-13198 OR

PANASONIC 12TS-2R5SP

††

AVX TPSE337M006R0100

Figure 1. 5V to 1.8V-3.5V Supply Application

1200µF

Q2*

1553L F01

LTC1553L

ABSOLUTE

MAXIMUM

RATINGS

(Note 1)

PACKAGE/ORDER INFORMATION

TOP VIEW

GND

SGND

SENSE

MAX

20 G1

19 OUTEN

18 VID0

17 VID1

16 VID2

15 VID3

14 VID4

13 PWRGD

12 FAULT

11 OT

Supply Voltage

........................................................................ 7V

................................................................... 14V

Input Voltage

(Note 2) ............................................ PV

+ 0.3V

MAX

........................................................ – 0.3V to 9V

All Other Inputs ......................... – 0.3V to V

+ 0.3V

Digital Output Voltage ................................. – 0.3V to 9V

Input Current (Notes 2, 3) .......................... – 100mA

Operating Temperature Range ..................... 0°C to 70°C

Storage Temperature Range ................. – 65°C to 150°C

Lead Temperature (Soldering, 10 sec.)................. 300°C

ORDER PART

NUMBER

LTC1553LCG

LTC1553LCSW

COMP 10

G PACKAGE

SW PACKAGE

20-LEAD PLASTIC SSOP 20-LEAD PLASTIC SO

JMAX

= 125°C,

= 100°C/ W (G)

JMAX

= 125°C,

= 100°C/ W (SW)

Consult factory for Industrial and Military grade parts.

ELECTRICAL CHARACTERISTICS

SYMBOL

OUT

PARAMETER

Supply Voltage

Supply Voltage for G1, G2

Internal Feedback Voltage

1.8V Initial Output Voltage

2.8V Initial Output Voltage

3.5V Initial Output Voltage

1.8V Initial Output Voltage

2.8V Initial Output Voltage

3.5V Initial Output Voltage

Output Load Regulation

Output Line Regulation

Positive Power Good Trip Point

Negative Power Good Trip Point

FAULT Trip Point

Operating Supply Current

Shutdown Supply Current

Supply Current

Internal Oscillator Frequency

COMP

at Minimum Duty Cycle

COMP

at Maximum Duty Cycle

Error Amplifier Open-Loop DC Gain

Error Amplifier Transconductance

Error Amplifier –3dB Bandwidth

(Note 4)

CONDITIONS

= 5V, PV

= 12V, T

= 25°C, unless otherwise noted. (Note 3)

MIN

TYP

MAX

13.2

UNITS

4.5

1.260

With Respect to Rated Output Voltage (Figure 2)

– 27 (– 1.5%)

– 42 (– 1.5%)

– 52 (– 1.5%)

– 36 (– 2%)

– 56 (– 2%)

– 70 (– 2%)

–5

±1

27 (+ 1.5%)

42 (+ 1.5%)

52 (+ 1.5%)

36 (+ 2%)

56 (+ 2%)

70 (+ 2%)

∆V

OUT

PWRGD

FAULT

PVCC

OSC

SAWL

SAWH

ERR

mERR

ERR

OUT

= 0 to 14A (Note 4) (Figure 2)

= 4.75V to 5.25V, I

OUT

= 0 (Note 4)(Figure 2)

% Above Output Voltage (Figure 2)

% Below Output Voltage (Figure 2)

% Above Output Voltage (Figure 2)

OUTEN = V

= 5V (Note 5)(Figure 3)

OUTEN = 0, VID0 to VID4 Floating (Figure 3)

= 12V, OUTEN = V

(Note 6) (Figure 3)

= 12V, OUTEN = 0, VID0 to VID4 Floating

(Figure 4)

(Note 4)

(Note 7)

COMP = Open (Note 4)

–7

–5

800

130

1200

250

300

1.8

2.8

350

0.9

1.6

400

2.3

millimho

kHz

W W

µA

kHz

LTC1553L

ELECTRICAL CHARACTERISTICS

SYMBOL

IMAX

SSIL

SSHIL

PWRGD

PWRBAD

FAULT

OTDD

SHDN

, t

NOL

MAX

SINK

PARAMETER

MAX

Sink Current

Soft Start Source Current

Maximum Soft Start Sink Current

Under Current Limit

Soft Start Sink Current Under Hard

Current Limit

Hard Current Limit Hold Time

Power Good Response Time↑

Power Good Response Time↓

FAULT Response Time

OT Response Time

Over-Temperature Trip Point

Over-Temperature Driver Disable

Shutdown

Driver Rise and Fall Time

Driver Nonoverlap Time

Maximum G1 Duty Cycle

VID0 to VID4 Input High Voltage

VID0 to VID4 Input Low Voltage

VID0 to VID4 Internal Pull-Up

Resistance

Digital Output Sink Current

CONDITIONS

IMAX

= V

= 5V, PV

= 12V, T

= 25°C, unless otherwise noted. (Note 3)

MIN

TYP

180

– 11

500

MAX

220

–8

150

UNITS

µA

µs

150

– 15

= 0V, V

IMAX

= 0V, V

IFB

= V

SENSE

= V

OUT

, V

IMAX

= V

, V

IFB

= 0V

(Notes 8, 9), V

= V

SENSE

= 0V, V

IMAX

= V

, V

IFB

= 0V

SENSE

= 0V, V

IMAX

= 4V, V

IFB

↓

from 5V (Note 4)

SENSE

↑

from 0V to Rated V

OUT

SENSE

↓

from Rated V

OUT

to 0V

SENSE

↑

from Rated V

OUT

to V

OUTEN↓, VID0 to VID4 = 0 (Note 10) (Figure 3)

(Figure 4)

0.5

200

1.9

1.6

500

1.7

1000

2.12

1.8

0.8

150

0.8

µs

kΩ

100

The

denotes specifications which apply over the full operating

temperature range.

Note 1:

Absolute Maximum Ratings are those values beyond which the life

of a device may be impaired.

Note 2:

When I

is taken below GND, it will be clamped by an internal

diode. This pin can handle input currents greater than 100mA below GND

without latchup. In the positive direction, it is not clamped to V

or PV

Note 3:

All currents into device pins are positive; all currents out of the

device pins are negative. All voltages are referenced to ground unless

otherwise specified.

Note 4:

This parameter is guaranteed by correlation and is not tested

directly.

Note 5:

The LTC1553L goes into the shutdown mode if VID0 to VID4 are

floating. Due to the internal pull-up resistors, there will be an additional

0.25mA/pin if any of the VID0 to VID4 pins are pulled low.

Note 6:

Supply current in normal operation is dominated by the current

needed to charge and discharge the external FET gates. This will vary with

the LTC1553L operating frequency, supply voltage and the external FETs

used.

Note 7:

The open-loop DC gain and transconductance from the SENSE pin to

COMP pin will be (G

ERR

)(1.260/3.3) and (g

mERR

)(1.260/3.3) respectively.

Note 8:

The current limiting amplifier can sink but cannot source current.

Under normal (not current limited) operation, the output current will be zero.

Note 9:

Under typical soft current limit, the net soft start discharge current

will be 60µA (I

SSIL

) + [–11µA(I

)]

≅

50µA. The soft start sink-to-source

current ratio is designed to be 5.5:1.

Note 10:

When VID0 to VID4 are all HIGH, the LTC1553L will be forced to

shut down internally. The OUTEN trip voltages are guaranteed by design for

all other input codes.

LTC1553L

TYPICAL PERFORMANCE CHARACTERISTICS

Typical 2.8V V

OUT

Distribution

140

120

TOTAL SAMPLE SIZE = 1500

NUMBER OF UNITS

100

OUTPUT VOLTAGE (V)

EFFICIENCY (%)

25°C

2.775

100°C

2.785

2.815

2.795 2.805

OUTPUT VOLTAGE (V)

Line Regulation

2.825

2.820

2.815

REFER TO TYPICAL APPLICATION

CIRCUIT FIGURE 1

OUTPUT = NO LOAD

= 25°C

2.840

OVER-TEMPERATURE TRIP POINT (V)

OUTPUT VOLTAGE (V)

2.810

2.805

2.800

2.795

2.790

2.785

2.780

2.775

4.75

4.85

5.05

5.15

4.95

INPUT VOLTAGE (V)

5.25

1553L G04

OUTPUT VOLTAGE (V)

1.78

1.76

1.74

1.72

1.70

1.68

1.66

1.64

1.62

1.60

–50 –25

TEMPERATURE (°C)

100

125

2.1

1.9

1.7

1.5

1.3

1.1

0.9

– 50 –25

ERROR AMPLIFIER OPEN-LOOP DC GAIN (dB)

1.80

OVER-TEMPERATURE DRIVER DISABLE (V)

ERROR AMPLIFIER TRANSCONDUCTANCE (millimho)

Over-Temperature Driver Disable

vs Temperature

U W

1553L G01

1553L G07

Efficiency vs Load Current

100

2.825

Load Regulation

2.825

REFER TO TYPICAL APPLICATION

2.820 CIRCUIT FIGURE 1

V = 5V, PV

= 12V, T

= 25°C

2.815

2.810

2.805

2.800

2.795

2.790

2.785

2.780

2.775

0 1 2 3 4 5 6 7 8 9 10 11 12 13 14

OUTPUT CURRENT (A)

1533L G03

REFER TO TYPICAL APPLICATION

CIRCUIT FIGURE 1

= 5V, PV

= 12V, V

OUT

= 2.8V,

OUT

= 330µF

7, L

= 2µH

A: Q1 = 1

SUD50N03-10

Q2 = 1

SUD50N03-10

B: Q1 = 2

SUD50N03-10

Q2 = 1

SUD50N03-10

NO FAN

Q1 IS MOUNTED ON 1IN

COPPER AREA

0.3

LOAD CURRENT (A)

1533L G02

Output Temperature Drift

2.860

2.850

2.830

2.820

2.810

2.800

2.790

2.780

2.770

2.660

2.750

2.740

– 50 – 25

TEMPERATURE (°C)

100

125

2.12

2.10

2.08

2.06

2.04

2.02

2.00

1.98

1.96

1.94

1.92

Over-Temperature Trip Point

vs Temperature

1.90

– 50 – 25

TEMPERATURE (°C)

100

125

1553L G05

1553L G06

Error Amplifier Transconductance

vs Temperature

2.3

Error Amplifier Open-Loop

DC Gain vs Temperature

TEMPERATURE (°C)

100

125

–50

–25

TEMPERATURE (°C)

100

125

1553L G08

1553L G09

LTC1553L

TYPICAL PERFORMANCE CHARACTERISTICS

Oscillator Frequency

vs Temperature

350

340

220

210

MAX

SINK CURRENT (µA)

200

190

180

170

160

150

–50

SOFT START SOURCE CURRENT (µA)

OSCILLATOR FREQUENCY (kHz)

330

320

310

300

290

280

270

260

250

–50 –25

TEMPERATURE (°C)

100

125

Maximum G1 Duty Cycle

vs Temperature

1.2

– 50 – 25

TEMPERATURE (°C)

100

125

5500pF

7700pF

G1, G2 CAPACITANCE = 1100pF

2200pF

3300pF

OPERATING SUPPLY CURRENT (mA)

SHUTDOWN SUPPLY CURRENT (mA)

OSCILLATOR FREQUENCY = 300kHz

MAXIMUM G1 DUTY CYCLE (%)

Supply Current

vs Gate Capacitance

SUPPLY CURRENT (mA)

= 12V

= 25°C

2000

6000

GATE CAPACITANCE (pF)

4000

8000

1553L G16

OUTPUT VOLTAGE (V)

U W

1553L G10

MAX

Sink Current

vs Temperature

–8

–9

–10

–11

–12

–13

–14

Soft Start Source Current

vs Temperature

–25

TEMPERATURE (°C)

100

125

–15

– 50 – 25

TEMPERATURE (°C)

100

125

1553L G11

1553L G12

Operating Supply Current

vs Temperature

250

= 5V

OSC

= 300kHz

225

200

175

150

125

100

1.1

1.0

0.9

0.8

0.7

0.6

0.5

– 50 –25

Shutdown Supply Current

vs Temperature

TEMPERATURE (°C)

100

125

– 50 – 25

TEMPERATURE (°C)

100

125

1553L G13

1553L G14

1553L G15

Output Over Current Protection

3.0

2.5

2.0

1.5

Q1 CASE = 90°C, V

OUT

= 2.8V

Q1 = 2

MTD20N03HDL

Q2 = 1

MTD20N03HDL

IMAX

= 2.7k, R

IFB

= 20Ω,

SS CAP = 0.01µF

Transient Response

50mV/DIV

5A/DIV

1.0

SHORT-CIRCUIT

CURRENT

0.5

8 10 12 14

OUTPUT CURRENT (A)

1553L G18

100µs/DIV

1553L G17

型号	LTC1553LCG#TRPBF	LTC1553LCSW	LTC1553LCG	LTC1553LCSW#TR	LTC1553LCSW#TRPBF	LTC1553LCSW#PBF
描述	开关稳压器 5-Bit Prog. Syn DC/DC Converter	Switching Voltage Regulators LTC1553L - 5-Bit Programmable Synchronous Switching Regulator Controller for Pentium- II Processor	Switching Voltage Regulators LTC1553L - 5-Bit Programmable Synchronous Switching Regulator Controller for Pentium- II Processor	Switching Voltage Regulators LTC1553L - 5-Bit Programmable Synchronous Switching Regulator Controller for Pentium- II Processor	开关稳压器 5-Bit Prog. Syn DC/DC Converter	开关稳压器 5-Bit Prog. Syn DC/DC Converter
厂商名称	ADI(亚德诺半导体)	ADI(亚德诺半导体)	ADI(亚德诺半导体)	-	ADI(亚德诺半导体)	ADI(亚德诺半导体)
最大输入电压	6 V	6 V	6 V	-	6 V	6 V
最小输入电压	4.5 V	4.5 V	4.5 V	-	4.5 V	4.5 V

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