LT6700HDCB-3_技术文档

LT6700/LT6700HV

Micropower, Low Voltage,

Dual Comparator with

400mV Reference

DESCRIPTION

FEATURES

The LT^®6700/LT6700HV combine two micropower, low

voltage comparators with a 400mV reference in a 6-lead

SOT-23ortinyDFNpackage. Operatingwithsuppliesfrom

1.4V up to 18V, these devices draw only 6.5µA, making

them ideal for low voltage system monitoring. Hysteresis

isincludedinthecomparators,easingdesignrequirements

to insure stable output operation.

n

Internal 400mV Reference

n

Total Threshold Error: ±±1.25 Maꢀ at .2ꢁ°

n

Inputs and Outputs Operate to 36V

n

Wide Supply Range: ±14V to ±8V

n

Specified for –22ꢁ° to ±.2ꢁ° Temperature Range

n

Low Quiescent Current: 6.5µA Typ at 5V

n

Internal Hysteresis: 6.5mV Typ

n

Low Input Bias Current: 10nA Max

The comparators each have one input available externally;

the other inputs are connected internally to the reference.

The comparator outputs are open collector and the output

load can be referred to any voltage up to 18V (36V for

LT6700HV), independent of supply voltage. The output

stage sinking capability is guaranteed to be greater than

5mA over temperature.

Over-The-Top^®Input also Includes Ground

n

Open-Collector Outputs Allow Level Translation

n

Choice of Input Polarities: LT6700-1/LT6700-2/

LT6700-3/LT6700HV-1/LT6700HV-2/LT6700HV-3

n

Available in Low Profile (1mm) SOT-23 (ThinSOT™)

and 2mm × 3mm DFN Packages

The three versions of this part differ by the polar-

ity of the available comparator inputs. The LT6700-1/

LT6700HV-1 has one inverting input and one noninvert-

ing input, making it suitable for use as a window com-

parator. The LT6700-2/LT6700HV-2 has two inverting

inputs and the LT6700-3/LT6700HV-3 has two nonin-

verting inputs. All versions are offered in commercial,

industrial and automotive temperature ranges.

APPLICATIONS

n

Battery-Powered System Monitoring

n

Threshold Detectors

n

Window Comparators

n

Relay Driving

n

Industrial Control Systems

n

Handheld Instruments

n

Automotive Monitor and Controls

L, LT, LTC, LTM, Linear Technology, the Linear logo and Over-The-Top are registered

trademarks and ThinSOT and PowerPath are trademarks of Linear Technology Corporation.

All other trademarks are the property of their respective owners.

TYPICAL APPLICATION

Micropower Battery Monitor

°omparator Thresholds

V

BATT

1.4V (MIN)

3V (NOM)

vs Temperature

LT6700-3

406

1M

#1A

#1B

#2A

#2B

COMP B

404

402

400

398

396

394

392

390

+

RISING INPUT

0.1µF

V

> 1.6V

BATT

–

63.4k

+

ALKALINE

AA CELLS

V

S

V

R

= 400mV

REFERENCE

FALLING INPUT

COMP A

TWO TYPICAL PARTS

COMP A AND B

V = 5V

–

+

V

> 2V

BATT

S

–60 –40 –20

0

20 40 60 80 100 120

MONITOR CONSUMES ~10µA

HYSTERESIS IS APPROXIMATELY

2% OF TRIP VOLTAGE

TEMPERATURE (°C)

261k

6700123 TA02

6700123 TA01

6700123fh

For more information www.linear.com/LT6700

1

LT6700/LT6700HV

(Note ±)

ABSOLUTE MAXIMUM RATINGS

Total Supply Voltage (V to GND) ..........................18.5V

Speciﬁed Temperature Range (Note 5)

S

Input Voltage (+IN, –IN)

LT6700CS6/LT6700HVCS6/

LT6700 (Note 3).......................... 18.5V to (GND – 0.3V)

LT6700HV (Note 3) ........................ 40V to (GND – 0.3V)

LT6700 Output Voltage (OUT)..... 18.5V to (GND – 0.3V)

LT6700HV Output Voltage (OUT) ... 40V to (GND – 0.3V)

Output Short-Circuit Duration (Note 2) ............ Indeﬁnite

Input Current (Note 3)..........................................–10mA

Operating Temperature Range (Note 4)

LT6700CDCB-1/-2/-3 .............................. 0°C to 70°C

LT6700IS6/LT6700HVIS6/

LT6700IDCB-1/-2/-3 ............................ –40°C to 85°C

LT6700HS6/LT6700HVHS6/

LT6700HDCB-1/-2/-3 ....................... –40°C to 125°C

LT6700MPDCB/

LT6700PMS6-1/-2/-3......................... –55°C to 125°C

Maximum Junction Temperature

LT6700CS6/LT6700HVCS6/

LT6700CDCB-1/-2/-3 ...........................–40°C to 85°C

LT6700IS6/LT6700HVIS6/

LT6700IDCB-1/-2/-3 ............................ –40°C to 85°C

LT6700HS6/LT6700HVHS6/

LT6700HDCB-1/-2/-3 ........................ –40°C to 125°C

LT6700MPDCB/

LT6700MPS6-1/-2/-3......................... –55°C to 125°C

S6 Package....................................................... 150°C

DCB6 Package .................................................. 150°C

Storage Temperature Range

S6 Package........................................ –65°C to 150°C

DCB6 Package ................................... –65°C to 150°C

Lead Temperature, TSOT-23 (Soldering, 10 sec)... 300°C

PIN CONFIGURATION

LT6700-1

LT6700-2

LT6700HV-2

LT6700-3

LT6700HV-3

LT6700HV-1

TOP VIEW

OUTA 1

GND 2

+INA 3

6 OUTB

5 V

OUTA 1

GND 2

–INA 3

6 OUTB

5 V

OUTA 1

GND 2

+INA 3

6 OUTB

5 V

S

4 –INB

4 +INB

S6 PACKAGE

6-LEAD PLASTIC TSOT-23

S6 PACKAGE

6-LEAD PLASTIC TSOT-23

S6 PACKAGE

6-LEAD PLASTIC TSOT-23

T

= 150°C, θ = 230°C/W

T

= 150°C, θ = 230°C/W

T

= 150°C, θ = 230°C/W

JMAX

JA

JMAX

JA

JMAX

JA

LT6700-1

LT6700-2

LT6700-3

TOP VIEW

6

1

OUTA

+ INA

GND

–INB

OUTA

– INA

GND

–INB

+ INA

GND

+INB

7

5

2

3

2

3

2

3

OUTB

4

V

S

DCB6 PACKAGE

6-LEAD (2mm × 3mm) PLASTIC DFN

DCB6 PACKAGE

6-LEAD (2mm × 3mm) PLASTIC DFN

DCB6 PACKAGE

6-LEAD (2mm × 3mm) PLASTIC DFN

T

= 125°C, θ = 64°C/W

T

= 125°C, θ = 64°C/W

T

= 125°C, θ = 64°C/W

JMAX

JA

JMAX

JA

JMAX JA

SOLDERED EXPOSED PAD (PIN 7)

INTERNALLY CONNECTED TO GND

(PCB CONNECTION OPTIONAL)

SOLDERED EXPOSED PAD (PIN 7)

INTERNALLY CONNECTED TO GND

(PCB CONNECTION OPTIONAL)

SOLDERED EXPOSED PAD (PIN 7)

INTERNALLY CONNECTED TO GND

(PCB CONNECTION OPTIONAL)

6700123fh

2

For more information www.linear.com/LT6700

LT6700/LT6700HV

ORDER INFORMATION

Lead Free Finish

TAPE AND REEL (MINI)

LT6700CS6-1#TRMPBF

LT6700HVCS6-1#TRMPBF

LT6700IS6-1#TRMPBF

LT6700HVIS6-1#TRMPBF

LT6700HS6-1#TRMPBF

LT6700HVHS6-1#TRMPBF

LT6700MPS6-1#TRMPBF

LT6700CS6-2#TRMPBF

LT6700HVCS6-2#TRMPBF

LT6700IS6-2#TRMPBF

LT6700HVIS6-2#TRMPBF

LT6700HS6-2#TRMPBF

LT6700HVHS6-2#TRMPBF

LT6700MPS6-2#TRMPBF

LT6700CS6-3#TRMPBF

LT6700HVCS6-3#TRMPBF

LT6700IS6-3#TRMPBF

LT6700HVIS6-3#TRMPBF

LT6700HS6-3#TRMPBF

LT6700HVHS6-3#TRMPBF

LT6700MPS6-3#TRMPBF

LT6700CDCB-1#TRMPBF

LT6700IDCB-1#TRMPBF

LT6700HDCB-1#TRMPBF

TAPE AND REEL

PART MARKING* PA°KAGE DES°RIPTION

SPE°IFIED TEMPERATURE RANGE

0°C to 70°C

–40°C to 85°C

–40°C to 125°C

–55°C to 125°C

0°C to 70°C

LT6700CS6-1#TRPBF

LT6700HVCS6-1#TRPBF

LT6700IS6-1#TRPBF

LT6700HVIS6-1#TRPBF

LT6700HS6-1#TRPBF

LT6700HVHS6-1#TRPBF

LT6700MPS6-1#TRPBF

LT6700CS6-2#TRPBF

LT6700HVCS6-2#TRPBF

LT6700IS6-2#TRPBF

LT6700HVIS6-2#TRPBF

LT6700HS6-2#TRPBF

LT6700HVHS6-2#TRPBF

LT6700MPS6-2#TRPBF

LT6700CS6-3#TRPBF

LT6700HVCS6-3#TRPBF

LT6700IS6-3#TRPBF

LT6700HVIS6-3#TRPBF

LT6700HS6-3#TRPBF

LT6700HVHS6-3#TRPBF

LT6700MPS6-2 #TRPBF

LT6700CDCB-1#TRPBF

LT6700IDCB-1#TRPBF

LT6700HDCB-1#TRPBF

LTK7

6-Lead Plastic TSOT-23

LTK7

6-Lead Plastic TSOT-23

LTK7

6-Lead Plastic TSOT-23

LTK7

6-Lead Plastic TSOT-23

LTK7

6-Lead Plastic TSOT-23

LTK7

6-Lead Plastic TSOT-23

LTK7

6-Lead Plastic TSOT-23

LTADL

LTADM

LBXW

LDVS

LBXX

LDVT

6-Lead Plastic TSOT-23

6-Lead (2mm × 3mm) Plastic DFN

0°C to 70°C

–40°C to 85°C

–40°C to 125°C

–55°C to 125°C

0°C to 70°C

–40°C to 85°C

–40°C to 125°C

–55°C to 125°C

0°C to 70°C

–40°C to 85°C

–40°C to 125°C

–55°C to 125°C

0°C to 70°C

–40°C to 85°C

–40°C to 125°C

–55°C to 125°C

0°C to 70°C

LT6700MPDCB-1#TRMPBF LT6700MPDCB-1#TR

LT6700CDCB-2#TRMPBF

LT6700IDCB-2#TRMPBF

LT6700HDCB-2#TRMPBF

LT6700CDCB-2#TRPBF

LT6700IDCB-2#TRPBF

LT6700HDCB-2#TRPBF

LT6700MPDCB-2#TRMPBF LT6700MPDCB-2#TR

LT6700CDCB-3#TRMPBF

LT6700IDCB-3#TRMPBF

LT6700HDCB-3#TRMPBF

LT6700CDCB-3#TRPBF

LT6700IDCB-3#TRPBF

LT6700HDCB-3#TRPBF

LBXY

LDVV

–40°C to 85°C

–40°C to 125°C

–55°C to 125°C

LT6700MPDCB-3#TRMPBF LT6700MPDCB-3#TR

TRM = 500 pieces. *Temperature grades are identified by a label on the shipping container.

Consult LTC Marketing for parts specified with wider operating temperature ranges.

Consult LTC Marketing for information on lead based finish parts.

For more information on lead free part marking, go to: http://www.linear.com/leadfree/

For more information on tape and reel specifications, go to: http://www.linear.com/tapeandreel/

6700123fh

For more information www.linear.com/LT6700

3

LT6700/LT6700HV

ELECTRICAL CHARACTERISTICS ^T_A^{= .2ꢁ°, (LT6700-±/LT6700-./LT6700-3) unless otherwise specified1}

SYMBOL

PARAMETER

°ONDITIONS

MIN

TYP

MAX

UNITS

V

Rising Input Threshold Voltage (Note 6) R = 100k, V = 2V Swing

TH(R)

L

O

V = 1.4V

394

395

393

392

400

406

405

407

408

mV

S

V = 5V

S

V = 12V

S

V = 18V

S

V

Falling Input Threshold Voltage (Note 6) R = 100k, V = 2V Swing

TH(F)

L

O

V = 1.4V

386

387

385

384

393.5

401

400

402

403

mV

S

V = 5V

S

V = 12V

S

V = 18V

S

HYS

HYS = V

– V

V = 1.4V, 5V, 12V, 18V, R = 100k, V = 2V Swing

3.5

6.5

9.5

mV

TH(R)

TH(F)

S

L

O

I

Input Bias Current

V = 1.4V, 18V, V = V

S

0.01

4

10

nA

B

S

IN

V = 1.4V, V = 18V

S

IN

V = 1.4V, 18V, V = 0.1V

S

IN

V

Output Low Voltage

10mV Input Overdrive

OL

V = 1.4V, I

= 0.5mA

= 3mA

55

60

70

200

mV

S

OUT

V = 1.6V, I

V = 5V, I

= 5mA

OUT

S

I

t

I

Output Leakage Current

High-to-Low Propagation Delay

Low-to-High Propagation Delay

Output Rise Time

V = 1.4V, 18V, V

= V , V = 40mV Overdrive

0.01

0.8

µA

OFF

S

OUT

S

IN

V = 1.4V, V

= 18V, V = 40mV Overdrive

IN

S

OUT

V = 5V, 10mV Input Overdrive, R = 10k,

18

µs

PD(HL)

S

OL

L

V

= 400mV

V = 5V, 10mV Input Overdrive, R = 10k,

29

PD(LH)

S

OH

L

V

= 0.9 • V

S

V = 5V, 10mV Input Overdrive, R = 10k

2.2

0.22

r

S

L

V = (0.1 to 0.9) • V

O

S

Output Fall Time

V = 5V, 10mV Input Overdrive, R = 10k

S L

f

V = (0.1 to 0.9) • V

O

S

Supply Current

No Load Current

S

V = 1.4V

5.7

6.5

6.9

7.1

10.0

11.0

12.5

13.0

µA

S

V = 5V

S

V = 12V

S

V = 18V

S

The ^ldenotes the speciﬁcations which apply over the temperature range of 0ꢁ° ≤ T_A≤ 70ꢁ°, (LT6700°-±/LT6700°-./LT6700°-3) unless

otherwise speciﬁed (Notes 4, 2)1

SYMBOL

PARAMETER

°ONDITIONS

MIN

TYP

MAX

UNITS

V

TH(R)

Rising Input Threshold Voltage (Note 6) R = 100k, V = 2V Swing

L

O

l

V = 1.4V

391.0

392.5

390.0

389.0

409.0

407.5

410.0

411.0

mV

S

V = 5V

S

V = 12V

S

V = 18V

S

V

TH(F)

Falling Input Threshold Voltage (Note 6) R = 100k, V = 2V Swing

L

O

l

V = 1.4V

383.5

384.5

382.5

381.5

403.5

402.5

404.5

405.5

mV

S

V = 5V

S

V = 12V

S

V = 18V

S

6700123fh

4

For more information www.linear.com/LT6700

LT6700/LT6700HV

ELECTRICAL CHARACTERISTICS

The l denotes the speciﬁcations which apply over the temperature range of 0ꢁ° ≤ T_A≤ 70ꢁ°, (LT6700°-±/LT6700°-./LT6700°-3) unless

otherwise speciﬁed (Notes 4, 2)1

SYMBOL

PARAMETER

HYS = V

°ONDITIONS

V = 1.4V, 5V, 12V, 18V, R = 100k, V = 2V Swing

MIN

TYP

MAX

UNITS

l

HYS

– V

3

11

mV

TH(R)

TH(F)

S

L

O

l

I

B

Input Bias Current

V = 1.4V, 18V, V = V

S

15

nA

S

IN

V = 1.4V, V = 18V

S

IN

V = 1.4V, 18V, V = 0.1V

S

IN

V

Output Low Voltage

10mV Input Overdrive

OL

l

V = 1.4V, I

= 0.5mA

= 3mA

250

mV

S

OUT

V = 1.6V, I

V = 5V, I

= 5mA

OUT

S

l

I

Output Leakage Current

Supply Current

V = 1.4V, 18V, V

= V , V = 40mV Overdrive

1

µA

OFF

S

OUT

S

IN

V = 1.4V, V

= 18V, V = 40mV Overdrive

IN

S

OUT

No Load Current

V = 1.4V

l

13.0

14.0

15.5

16.0

µA

S

V = 5V

S

V = 12V

S

V = 18V

S

The l denotes the speciﬁcations which apply over the temperature range of –40ꢁ° ≤ T_A≤ 82ꢁ°, (LT6700I-±/LT6700I-./LT6700I-3)

unless otherwise speciﬁed (Notes 4, 2)1

SYMBOL

PARAMETER

°ONDITIONS

MIN

TYP

MAX

UNITS

V

Rising Input Threshold Voltage (Note 6) R = 100k, V = 2V Swing

TH(R)

L

O

V = 1.4V

l

390

392

389

388

410

408

411

412

mV

S

V = 5V

S

V = 12V

S

V = 18V

S

V

Falling Input Threshold Voltage (Note 6) R = 100k, V = 2V Swing

TH(F)

L

O

V = 1.4V

l

382.5

383.5

381.5

380.5

404.5

403.5

405.5

406.5

mV

S

V = 5V

S

V = 12V

S

V = 18V

S

HYS

HYS = V

– V

V = 1.4V, 5V, 12V, 18V, R = 100k, V = 2V Swing

l

2

11.5

mV

TH(R)

TH(F)

S

L

O

I

Input Bias Current

V = 1.4V, 18V, V = V

S

l

15

nA

B

S

IN

V = 1.4V, V = 18V

S

IN

V = 1.4V, 18V, V = 0.1V

S

IN

V

Output Low Voltage

10mV Input Overdrive

OL

V = 1.4V, I

= 0.1mA

= 3mA

l

250

mV

S

OUT

V = 1.6V, I

V = 5V, I

= 5mA

OUT

S

I

Output Leakage Current

Supply Current

V = 1.4V, 18V, V

= V , V = 40mV Overdrive

l

1

µA

OFF

S

OUT

S

IN

V = 1.4V, V

= 18V, V = 40mV Overdrive

IN

S

OUT

No Load Current

V = 1.4V

l

14.0

15.0

16.5

17.0

µA

S

V = 5V

S

V = 12V

S

V = 18V

S

6700123fh

For more information www.linear.com/LT6700

5

LT6700/LT6700HV

ELECTRICAL CHARACTERISTICS

The l denotes the speciﬁcations which apply over the temperature range of –40ꢁ° ≤ T_A≤ ±.2ꢁ°, (LT6700H-±/LT6700H-./LT6700H-3)

unless otherwise speciﬁed (Notes 4, 2)1

LT6700H

TYP

SYMBOL

PARAMETER

°ONDITIONS

MIN

MAX

UNITS

V

Rising Input Threshold Voltage (Note 6) R = 100k, V = 2V Swing

TH(R)

TH(F)

L

O

V = 1.4V

l

390

392

389

388

411

410

412

413

mV

S

V = 5V

S

V = 12V

S

V = 18V

S

V

Falling Input Threshold Voltage (Note 6) R = 100k, V = 2V Swing

L

S

O

V = 1.4V

l

381.5

382.5

380.5

379.5

405.5

404.5

406.5

407.5

mV

V = 5V

S

V = 12V

S

V = 18V

S

HYS

HYS = V

– V

V = 1.4V, 5V, 12V, 18V, R = 100k, V = 2V Swing

l

2

13.5

mV

TH(R)

TH(F)

S

L

O

I

Input Bias Current

V = 1.4V, 18V, V = V

S

l

45

50

nA

B

S

IN

V = 1.4V, V = 18V

S

IN

V = 1.4V, 18V, V = 100mV

S

IN

V

OL

Output Low Voltage

10mV Input Overdrive

V = 1.4V, I

= 0.1mA

= 3mA

l

250

mV

S

OUT

V = 1.6V, I

V = 5V, I

= 5mA

OUT

S

I

Output Leakage Current

Supply Current

V = 1.4V, 18V, V

= V , V = 40mV Overdrive

l

1

µA

OFF

S

OUT

S

IN

V = 1.4V, V

= 18V, V = 40mV Overdrive

IN

S

OUT

No Load Current

V = 1.4V

S

l

16.0

17.0

18.5

19.0

µA

S

V = 5V

S

V = 12V

S

V = 18V

S

The ldenotes the speciﬁcations which apply over the temperature range of –22ꢁ° ≤ T_A≤ ±.2ꢁ°, (LT6700MP-±/LT6700MP-./LT6700MP-3)

unless otherwise speciﬁed (Notes 4, 2)1

LT6700H

TYP

SYMBOL

PARAMETER

°ONDITIONS

MIN

MAX

UNITS

V

TH(R)

Rising Input Threshold Voltage (Note 6) R = 100k, V = 2V Swing

L

O

V = 1.4V

l

390

392

389

388

411

410

412

413

mV

S

V = 5V

S

V = 12V

S

V = 18V

S

V

Falling Input Threshold Voltage (Note 6) R = 100k, V = 2V Swing

TH(F)

L

O

V = 1.4V

l

381.5

382.5

380.5

379.5

405.5

404.5

406.5

407.5

mV

S

V = 5V

S

V = 12V

S

V = 18V

S

HYS

HYS = V

– V

V = 1.4V, 5V, 12V, 18V, R = 100k, V = 2V Swing

l

2

13.5

mV

TH(R)

TH(F)

S

L

O

I

Input Bias Current

V = 1.4V, 18V, V = V

S

l

45

50

nA

B

S

IN

V = 1.4V, V = 18V

S

IN

V = 1.4V, 18V, V = 100mV

S

IN

V

OL

Output Low Voltage

10mV Input Overdrive

V = 1.4V, I

= 0.1mA

= 3mA

l

250

mV

S

OUT

V = 1.6V, I

V = 5V, I

= 5mA

OUT

S

6700123fh

6

For more information www.linear.com/LT6700

LT6700/LT6700HV

ELECTRICAL CHARACTERISTICS

The ldenotes the speciﬁcations which apply over the temperature range of –22ꢁ° ≤ T_A≤ ±.2ꢁ°, (LT6700MP-±/LT6700MP-./LT6700MP-3)

unless otherwise speciﬁed (Notes 4, 2)1

LT6700H

TYP

SYMBOL

PARAMETER

°ONDITIONS

V = 1.4V, 18V, V

MIN

MAX

UNITS

I

Output Leakage Current

= V , V = 40mV Overdrive

l

1

µA

OFF

S

OUT

S

IN

V = 18V, V

= 18V, V = 40mV Overdrive

IN

S

OUT

I

S

Supply Current

No Load Current

V = 1.4V

l

16.0

17.0

18.5

19.0

µA

S

V = 5V

S

V = 12V

S

V = 18V

S

T_A= .2ꢁ°, (LT6700HV-±/LT6700HV-./LT6700HV-3) unless otherwise specified1

SYMBOL PARAMETER °ONDITIONS

Rising Input Threshold Voltage (Note 6) R = 100k, V = 2V Swing

MIN

TYP

MAX

UNITS

V

TH(R)

L

O

V = 1.4V

394

395

393

392

400

406

405

407

408

mV

S

V = 5V

S

V = 12V

S

V = 18V

S

V

Falling Input Threshold Voltage (Note 6) R = 100k, V = 2V Swing

TH(F)

L

O

V = 1.4V

386

387

385

384

393.5

401

400

402

403

mV

S

V = 5V

S

V = 12V

S

V = 18V

S

HYS

HYS = V

– V

V = 1.4V, 5V, 12V, 18V, R = 100k, V = 2V Swing

3.5

6.5

9.5

mV

TH(R)

TH(F)

S

L

O

I

Input Bias Current

V = 1.4V, 18V, V = V

S

0.01

4

10

nA

B

S

IN

V = 1.4V, V = 18V, 36V

S

IN

V = 1.4V, 18V, V = 0.1V

S

IN

V

Output Low Voltage

10mV Input Overdrive

OL

V = 1.4V, I

= 0.5mA

= 3mA

55

60

70

200

mV

S

OUT

V = 1.6V, I

V = 5V, I

= 5mA

OUT

S

I

t

I

Output Leakage Current

High-to-Low Propagation Delay

Low-to-High Propagation Delay

Output Rise Time

V = 1.4V, 18V, V

= V , V = 40mV Overdrive

0.01

0.8

µA

OFF

S

OUT

S

IN

V = 18V, V

= 18V, (36V, R = 100k), V = 40mV Overdrive

L IN

S

OUT

V = 5V, 10mV Input Overdrive, R = 10k,

18

µs

PD(HL)

S

OL

L

V

= 400mV

V = 5V, 10mV Input Overdrive, R = 10k,

29

PD(LH)

S

OH

L

V

= 0.9 • V

S

V = 5V, 10mV Input Overdrive, R = 10k

2.2

0.22

r

S

L

V = (0.1 to 0.9) • V

O

S

Output Fall Time

V = 5V, 10mV Input Overdrive, R = 10k

S L

f

V = (0.1 to 0.9) • V

O

S

Supply Current

No Load Current

S

V = 1.4V

5.7

6.5

6.9

7.1

10.0

11.0

12.5

13.0

µA

S

V = 5V

S

V = 12V

S

V = 18V

S

6700123fh

For more information www.linear.com/LT6700

7

LT6700/LT6700HV

ELECTRICAL CHARACTERISTICS

The l denotes the speciﬁcations which apply over the temperature range of 0ꢁ° ≤ T_A≤ 70ꢁ°, (LT6700HV°-±/LT6700HV°-./LT6700HV°-3)

unless otherwise speciﬁed (Notes 4, 2)1

SYMBOL PARAMETER

°ONDITIONS

R = 100k, V = 2V Swing

MIN

TYP MAX UNITS

V

Rising Input Threshold Voltage

(Note 6)

TH(R)

L

O

V = 1.4V

l

391.0

392.5

390.0

389.0

409.0

407.5

410.0

411.0

mV

S

V = 5V

S

V = 12V

S

V = 18V

S

V

TH(F)

Falling Input Threshold Voltage

(Note 6)

R = 100k, V = 2V Swing

L O

V = 1.4V

l

383.5

384.5

382.5

381.5

403.5

402.5

404.5

405.5

mV

S

V = 5V

S

V = 12V

S

V = 18V

S

HYS

HYS = V

– V

V = 1.4V, 5V, 12V, 18V, R = 100k, V = 2V Swing

l

3

11

mV

TH(R)

TH(F)

S

L

O

I

B

Input Bias Current

V = 1.4V, 18V, V = V

S

l

15

nA

S

IN

V = 1.4V, V = 18V, 36V

S

IN

V = 1.4V, 18V, V = 0.1V

S

IN

V

Output Low Voltage

10mV Input Overdrive

OL

V = 1.4V, I

= 0.5mA

= 3mA

l

250

mV

S

OUT

V = 1.6V, I

V = 5V, I

= 5mA

OUT

S

I

Output Leakage Current

Supply Current

V = 1.4V, 18V, V

= V , V = 40mV Overdrive

l

1

µA

OFF

S

OUT

S

IN

V = 18V, V

= 18V, (36V, R = 100k), V = 40mV Overdrive

L IN

S

OUT

No Load Current

V = 1.4V

l

13.0

14.0

15.5

16.0

µA

S

V = 5V

S

V = 12V

S

V = 18V

S

The ldenotes the speciﬁcations which apply over the temperature range of –40ꢁ° ≤ T_A≤ 82ꢁ°, (LT6700HVI-±/LT6700HVI-./LT6700HVI-3)

unless otherwise speciﬁed (Notes 4, 2)1

SYMBOL PARAMETER

°ONDITIONS

MIN TYP MAX UNITS

V

Rising Input Threshold Voltage (Note 6) R = 100k, V = 2V Swing

TH(R)

L

O

V = 1.4V

l

390

392

389

388

410

408

411

412

mV

S

V = 5V

S

V = 12V

S

V = 18V

S

V

TH(F)

Falling Input Threshold Voltage (Note 6) R = 100k, V = 2V Swing

L

O

V = 1.4V

l

382.5

383.5

381.5

380.5

404.5

403.5

405.5

406.5

mV

S

V = 5V

S

V = 12V

S

V = 18V

S

HYS

HYS = V

– V

V = 1.4V, 5V, 12V, 18V, R = 100k, V = 2V Swing

l

2

11.5

mV

TH(R)

TH(F)

S

L

O

I

Input Bias Current

V = 1.4V, 18V, V = V

S

l

15

nA

B

S

IN

V = 1.4V, V = 18V, 36V

S

IN

V = 1.4V, 18V, V = 0.1V

S

IN

V

Output Low Voltage

10mV Input Overdrive

OL

V = 1.4V, I

= 0.1mA

= 3mA

l

250

mV

S

OUT

V = 1.6V, I

V = 5V, I

= 5mA

OUT

S

I

Output Leakage Current

V = 1.4V, 18V, V

= V , V = 40mV Overdrive

l

1

µA

OFF

S

OUT

S

IN

V = 18V, V

= 18V, (36V, R = 100k), V = 40mV Overdrive

L IN

S

OUT

6700123fh

8

For more information www.linear.com/LT6700

LT6700/LT6700HV

ELECTRICAL CHARACTERISTICS

The ldenotes the speciﬁcations which apply over the temperature range of –40ꢁ° ≤ T_A≤ 82ꢁ°, (LT6700HVI-±/LT6700HVI-./LT6700HVI-3)

unless otherwise speciﬁed (Notes 4, 2)1

SYMBOL PARAMETER

Supply Current

°ONDITIONS

MIN TYP MAX UNITS

I

No Load Current

S

V = 1.4V

l

14.0

15.0

16.5

17.0

µA

S

V = 5V

S

V = 12V

S

V = 18V

S

The l denotes the speciﬁcations which apply over the temperature range of –40ꢁ° ≤ T_A≤ ±.2ꢁ°, (LT6700HVH-±/LT6700HVH-./

LT6700HVH-3) unless otherwise speciﬁed (Notes 4, 2)1

LT6700H

TYP

SYMBOL PARAMETER

°ONDITIONS

R = 100k, V = 2V Swing

MIN

MAX UNITS

V

TH(R)

Rising Input Threshold Voltage

(Note 6)

L

O

V = 1.4V

l

390

392

389

388

411

410

412

413

mV

S

V = 5V

S

V = 12V

S

V = 18V

S

V

TH(F)

Falling Input Threshold Voltage

(Note 6)

R = 100k, V = 2V Swing

L O

V = 1.4V

l

381.5

382.5

380.5

379.5

405.5

404.5

406.5

407.5

mV

S

V = 5V

S

V = 12V

S

V = 18V

S

HYS

HYS = V

– V

V = 1.4V, 5V, 12V, 18V, R = 100k, V = 2V Swing

l

2

13.5

mV

TH(R)

TH(F)

S

L

O

I

B

Input Bias Current

V = 1.4V, 18V, V = V

S

l

45

50

nA

S

IN

V = 1.4V, V = 18V, 36V

S

IN

V = 1.4V, 18V, V = 100mV

S

IN

V

OL

Output Low Voltage

10mV Input Overdrive

V = 1.4V, I

= 0.1mA

= 3mA

l

250

mV

S

OUT

V = 1.6V, I

V = 5V, I

= 5mA

OUT

S

I

Output Leakage Current

Supply Current

V = 1.4V, 18V, V

= V , V = 40mV Overdrive

l

1

µA

OFF

S

OUT

S

IN

V = 18V, V

= 18V, (36V, R = 100k), V = 40mV Overdrive

L IN

S

OUT

No Load Current

V = 1.4V

S

l

16.0

17.0

18.5

19.0

µA

S

V = 5V

S

V = 12V

S

V = 18V

S

Note ±: Stresses beyond those listed under Absolute Maximum Ratings

may cause permanent damage to the device. Exposure to any Absolute

Maximum Rating condition for extended periods may affect device

reliability and lifetime.

Note .: A heat sink may be required to keep the junction temperature

below the absolute maximum rating when the output is shorted

indeﬁnitely.

Note 3: The inputs are protected by ESD diodes to the ground. If the input

voltage exceeds –0.3V below ground, the input current should be limited

to less than 10mA.

temperature range of –40°C to 125°C. The LT6700MP-1/-2/-3 is

guaranteed functional over the operating temperature range of –55°C to

125°C.

Note 2: The LT6700C-1/-2/-3/LT6700HVC-1/-2/-3 is guaranteed to

meet the speciﬁed performance from 0°C to 70°C. The LT6700C-1/-2/-

3/LT6700HVC-1/-2/-3 are designed, characterized and expected to meet

speciﬁed performance from –40°C to 85°C but are not tested or QA

sampled at these temperatures. The LT6700I-1/-2/-3/LT6700HVI-1/-2/-3

is guaranteed to meet speciﬁed performance from –40°C to 85°C. The

LT6700H-1/-2/-3/LT6700HVH-1/-2/-3 is guaranteed to meet speciﬁed

performance from –40°C to 125°C.The LT6700MP-1/-2/-3 is guaranteed to

meet speciﬁed performance from –55°C to 125°C.

Note 4: The LT6700C-1/-2/-3/LT6700HVC-1/-2/-3, and

LT6700I-1/-2/-3/LT6700HVI-1/-2/-3 are guaranteed functional over the

operating temperature range of –40°C to 85°C. The LT6700H-1/-2/-3/

LT6700HVH-1/-2/-3 is guaranteed functional over the operating

Note 6: V deﬁnes the threshold voltage of the comparators and

TH

combines the effect of offset and reference accuracy.

6700123fh

For more information www.linear.com/LT6700

9

LT6700/LT6700HV

PIN FUNCTIONS

V

S

LT6700-2

LT6700HV-2

LT6700-3

LT6700HV-3

LT6700-1

LT6700HV-1

COMP B

–INB

–

+INB

+

–

–INB

–

+

OUTB

+

V

S

V

S

V

S

400mV

REFERENCE

400mV

REFERENCE

400mV

REFERENCE

COMP A

–

+

–

OUTA

+

+INA

+

+INA

–INA

–

6700123 PF01

6700123 PF03

6700123 PF02

GND

OUTA: Open-Collector Output of Comparator Section A.

Thispinprovidesdriveforupto40mAofloadcurrent. Off-

state voltage may be as high as 18V (36V for LT6700HV)

INB: External Input for Comparator Section B. The volt-

age on this pin can range from –0.3V to 18V (36V for

LT6700HV) with respect to GND regardless of V used.

S

above GND, regardless of V used.

The input is noninverting for the LT6700-3/LT6700HV-3,

andinvertingfortheLT6700-1/LT6700HV-1andLT6700-2/

LT6700HV-2. The other section B comparator input is

internally connected to the 400mV reference.

S

GND: Ground. This pin is also the low side return of the

internal 400mV reference.

INA: External Input for Comparator Section A. The volt-

V : Comparator Core Supply Voltage. The parts are char-

S

age on this pin can range from –0.3V to 18V (36V for

acterized for operation with 1.4V ≤ V ≤ 18V with respect

S

LT6700HV) with respect to GND regardless of V used.

S

to GND.

The input is noninverting for the LT6700-1/LT6700HV-1

andLT6700-3/LT6700HV-3,andinvertingfortheLT6700-2/

LT6700HV-2. The other section A comparator input is

internally connected to the 400mV reference.

OUTB: Open-Collector Output of Comparator Section B.

Thispinprovidesdriveforupto40mAofloadcurrent. Off-

state voltage may be as high as 18V (36V for LT6700HV)

above GND, regardless of V used.

S

6700123fh

10

For more information www.linear.com/LT6700

LT6700/LT6700HV

TYPICAL PERFORMANCE CHARACTERISTICS

Distribution of Rising Input

Threshold Voltage

Distribution of Falling Input

Threshold Voltage

Distribution of Hysteresis

20

18

16

14

12

10

8

18

16

14

12

10

8

V

T

= 5V

= 25°C

V

T

= 5V

= 25°C

V

T

= 5V

= 25°C

S

A

18

16

14

12

10

8

A

6

4

2

0

4

4.8

5.6

6.4

7.2

8

8.8

394

396

398

400

402

404

406

388

390

392

394

396

398

400

HYSTERESIS (mV)

RISING INPUT THRESHOLD VOLTAGE (mV)

FALLING INPUT THRESHOLD VOLTAGE (mV)

6700123 G03

6700123 G01

6700123 G02

Rising Input Threshold Voltage

vs Temperature

Rising Input Threshold Voltage

vs Temperature

Rising Input Threshold Voltage

vs Supply Voltage

403.0

402.5

402.0

401.5

401.0

400.5

400.0

399.5

399.0

404

403

402

401

400

399

398

397

396

403.0

402.5

402.0

401.5

401.0

400.5

400.0

399.5

399.0

V

= 1.4V

= 5V

= 12V

= 18V

T

= 25°C

= 85°C

= 125°C

= –55°C

FOUR TYPICAL PARTS

= 5V

S

A

V

S

#1

#2

#3

#4

0

20 40 60 80

100 120

–60 –40 –20

0

20 40 60 80

8

10 12

–60 –40 –20

100 120

2

4

6

14 16 18

TEMPERATURE (°C)

SUPPLY VOLTAGE (V)

6700123 G05

6700123 G04

6700123 G06

Hysteresis vs Temperature

Hysteresis vs Supply Voltage

10

9

10

9

10

9

V

= 1.4V

= 5V

= 12V

= 18V

T

= 25°C

= 85°C

T

= 125°C

= –55°C

FOUR TYPICAL PARTS

S

A

V

= 5V

S

#1

#2

#3

#4

8

7

6

5

4

3

2

0

20 40 60 80

100 120

–60 –40 –20

0

20 40 60 80

8

10 12

–60 –40 –20

100 120

2

4

6

14 16 18

TEMPERATURE (°C)

SUPPLY VOLTAGE (V)

6700123 G08

6700123 G07

6700123 G09

6700123fh

For more information www.linear.com/LT6700

11

LT6700/LT6700HV

TYPICAL PERFORMANCE CHARACTERISTICS

Quiescent Supply °urrent

vs Supply Voltage

Minimum Supply Voltage

Start-Up Supply °urrent

50

40

30

20

10

0

1

0

10

9

T

= 25°C

= 85°C

= 125°C

= –55°C

T

= 25°C

= 85°C

T

= 125°C

= –55°C

A

NO LOAD CURRENT

–1

–2

–3

–4

–5

8

7

6

T

= 25°C

= 85°C

= 125°C

= –55°C

A

5

4

0

0.2 0.4 0.6 0.8 1.0 1.2 1.4

SUPPLY VOLTAGE (V)

6700123 G12

0.9

1.1

1.3

1.5

1.7

1.9

7.4 9.4 11.4

1.4 3.4 5.4 13.4 15.4 17.4

SUPPLY VOLTAGE (V)

6700123 G10

6700123 G11

Supply °urrent

vs Output Sink °urrent

Supply °urrent

vs Output Sink °urrent

Supply °urrent

vs Output Sink °urrent

1000

100

10

1000

100

10

1000

100

10

T

= –40°C

T

A

= 25°C

V

T

= 85°C

V

A

V

= 1.4V

= 5V

= 1.4V

= 5V

= 12V

= 18V

= 1.4V

= 5V

= 12V

= 18V

S

V

S

V

S

V

S

V

S

V

S

V

S

V

S

V

S

= 12V

= 18V

V

S

1

0.001

0.01

0.1

1

10

100

0.001

0.01

0.1

1

10

100

0.001

0.01

0.1

1

10

100

OUTPUT SINK CURRENT (mA)

6700123 G13

6700123 G14

6700123 G15

Below Ground Input Bias °urrent

Low Level Input Bias °urrent

High Level Input Bias °urrent

3

2

10000

1000

100

10

1

V

= 18V

CURRENT IS POSITIVE GOING

INTO THE DEVICE

CURRENT IS GOING INTO THE DEVICE

S

–0.3V < V < 0V

IB

T

= 25°C

= 85°C

= 125°C

= –55°C

A

1

0

–1

–2

–3

–4

–5

–6

–7

0.1

V

= 18V

IB

S

0V < V < 1V

V

= 18V

> 1V

S

IB

0.01

0.001

T

= 25°C

A

= 85°C

T

= 25°C

= 85°C

= 125°C

A

= 125°C

= –55°C

CURRENT IS GOING OUT OF THE DEVICE

–0.2 –0.1

INPUT VOLTAGE (V)

1

0.5 0.8 0.9

0.6 0.7

1

3

5

7

9

11 13 15 17

0

0.4

–0.3

0

0.1 0.2 0.3

INPUT VOLTAGE (V)

6700123 G16

6700123 G18

6700123 G17

6700123fh

12

For more information www.linear.com/LT6700

LT6700/LT6700HV

TYPICAL PERFORMANCE CHARACTERISTICS

Output Saturation Voltage

vs Output Sink °urrent

Output Saturation Voltage

vs Output Sink °urrent

Output Saturation Voltage

vs Output Sink °urrent

1000

100

10

1000

100

10

T

= –40°C

T

A

= 25°C

V

T

= 85°C

V

A

V

= 1.4V

= 5V

= 1.4V

= 5V

= 12V

= 18V

= 1.4V

= 5V

= 12V

= 18V

S

V

S

V

S

V

S

V

S

V

S

V

S

V

S

V

S

= 12V

= 18V

V

S

100

10

1

0.001

0.01

0.1

1

10

100

0.001

0.01

0.1

1

10

100

0.001

0.01

0.1

1

10

100

OUTPUT SINK CURRENT (mA)

6700123 G19

6700123 G20

6700123 G21

Output Short-°ircuit °urrent

Output Leakage °urrent

10

1

80

70

60

50

40

30

20

10

0

80

70

60

50

40

30

20

10

0

T

= 25°C

A

V

S

V

S

V

S

V

S

= 1.4V

= 5V

= 12V

= 18V

0.1

0.01

V

= 5V

S

T

= 25°C

= 85°C

= 125°C

= –55°C

A

T

V

= 5V

S

T

= 25°C

= 85°C

= 125°C

= –55°C

A

T

0.001

8

10 12

8

10 12

0

2

4

6

14 16 18

0

2

4

6

14 16 18

0

2

4

6

8

10 12 14 16 18

OUTPUT VOLTAGE (V)

6700123 G24

6700123 G22

6700123 G23

Propagation Delay

vs Input Overdrive

Rise and Fall Times

vs Output Pull-Up Resistor

Noninverting and Inverting

°omparator Propagation Delay

100

10

60

50

40

30

20

10

0

V

C

T

= 5V

= 20pF

= 25°C

LH NONINV

HL NONINV

LH INV

T

= 25°C

S

L

A

V

O(NINV)

5V/DIV

DC

HL INV

V

O(INV)

5V/DIV

DC

RISE

FALL

1

V

IN

10mV/DIV

AC

0.1

0.01

6700123 G27

V

= 15V

20µs/DIV

S

A

T

= 25°C

R

V

= 10k CONNNECTED TO V

LOAD

S

= 10mV OVER THE INPUT

0.1

1

10

100

1000

IN(OVERDRIVE)

0

20

40

60

80

100

VOLTAGE THRESHOLDS

OUTPUT PULL-UP RESISTOR (kΩ)

INPUT OVERDRIVE (mV)

6700123 G26

6700123 G25

6700123fh

For more information www.linear.com/LT6700

13

LT6700/LT6700HV

APPLICATIONS INFORMATION

The LT6700-1/LT6700-2/LT6700-3/LT6700HV-1/

LT6700HV-2/LT6700HV-3 devices are a family of dual

micropower comparators with a built-in 400mV refer-

ence. Features include wide supply voltage range (1.4V to

18V), Over-The-Top input and output range, 2% accurate

rising input threshold voltage and 6.5mV typical built-in

hysteresis. The comparator’s open-collector outputs can

sink up to 40mA typical.

below ground will not cause comparator malfunction or

damage (provided the current is limited to 10mA), but

the accuracy of the reference cannot be guaranteed, in

which case the output state of the alternate comparator

may be affected.

°omparator Outputs

The comparator outputs are open collector and capable

of sinking 40mA typical. Load currents are directed out

the GND pin of the part. The output off-state voltage may

range between –0.3V and 18V (36V for LT6700HV) with

respect to ground, regardless of the supply voltage used.

When the output high state bias voltage is above 18V, a

100k minimum pull-up resistor is required and total load

capacitor must be less than 100nF. If the output high state

is above 18V, caution must be taken to prevent a short

from the output directly to the bias voltage, even if the

outputisintheoffstate.Aswithanyopen-collectordevice,

the outputs may be tied together to implement wire-AND

logic functions.

Internal Reference

Each of the comparator sections has one input available

externally, with the three versions of the part differing by

the polarity of those available inputs (i.e., inverting or

noninverting).Theothercomparatorinputsareconnected

internallytothe400mVreference.Therisinginputthreshold

voltage of the comparators is designed to be equal to that

of the reference (i.e., ≈400mV). The reference voltage is

established with respect to the device GND connection.

Hysteresis

Eachcomparatorhasbuilt-in6.5mV(typical)hysteresisto

simplify designs, ensure stable operation in the presence

of noise at the inputs, and to reject supply rail noise that

might be induced by state change load transients. The

hysteresisisdesignedsuchthatthefallinginputthreshold

voltage is nominally 393.5mV. External positive feedback

circuitry can be employed with noninverting comparator

inputs to increase effective hysteresis if desired, but such

circuitry will provide an apparent effect on both the rising

and falling input thresholds (the actual internal thresholds

remain unaffected).

Power Supplies

Thecomparatorfamilycorecircuitryoperatesfromasingle

1.4V to 18V supply. A minimum 0.1µF bypass capacitor

is required between the V

pin and GND. When an output

S

load is connected to the supply rail near the part and the

output is sinking more than 5mA, a 1µF bypass capaci-

tor is recommended. The voltage reference built into the

LT6700 can be susceptible to high noise on the supply

line, particularly noise that is less than 50kHz and larger

than 20mV . In order to reduce the probability of a false

P-P

comparator output in the presence of high supply noise,

an RC filter should be used to reduce the noise. This filter

can be created simply by adding a series R between the

°omparator Inputs

A comparator input can swing from ground to 18V (36V

for LT6700HV), regardless of the supply voltage used. The

typical input current for inputs well above threshold (i.e.,

>800mV)isafewpAleakingintoaninput.Withdecreasing

input voltage, a small bias current begins to be drawn out

of the input, reaching a few nA when at ground potential.

The input may be forced 100mV below ground without

causing an improper output, though some additional bias

current will begin to flow from the parasitic ESD input pro-

tection diode. Inputs driven further negative than 100mV

systemsupplyandtheLT6700V pin,usingthedecoupling

capacitortocreatealowpassresponse.Itisrecommended

that the filter have a time constant:

S

t

RC

> V /100

N

Where V is the peak-peak supply noise in millivolts and

N

t

RC

is milliseconds.

This filter will also increase the start-up time of the LT6700

byreducingtherateatwhichthesupplycanchange.When

6700123fh

14

For more information www.linear.com/LT6700

LT6700/LT6700HV

APPLICATIONS INFORMATION

using a supply filter, the start-up time of the LT6700 will

increase to:

the nominal resistor values are selected as follows:

R1 ≤ 400k (this sets the divider current >> I of inputs)

B

t

= (0.17ms + 0.25 • t ) • ΔV

RC S

START

R2 = R1 • (1.02 • V /V – 1)

H

L

Where t

and t are in milliseconds and ΔV is the

RC S

START

R3 = R1 • (2.54 • V – 1.02 • V /V )

H

L

change in supply in volts. The low supply current of the

LT6700 should not cause significant voltage drop due to

a 2k maximum series R.

The worst-case variance of the trip-points is related to

the specified threshold limits of the LT6700/LT6700HV

device and the basic tolerance of divider resistors used.

Fleꢀible Window °omparator

For resistor tolerance R

(e.g. 0.01 for 1%), the worst-

TOL

case trip-point voltage (either V or V ) deviations can be

H

L

Using the LT6700-1/LT6700HV-1 as shown in the circuits

of Figure 1, the wire-AND configuration permits high

accuracy window functions to be implemented with a

simple 3-resistor voltage divider network. The section A

predicted as follows (italicized values are taken from the

data sheet, expressed in volts):

Max dev V

= V

• {2 • R • [(V

– 0.4)

TRIP↑

TRIPnom

] + 1.25 • (V

TOL

– V

TRIPnom

)}

comparator provides the V trip-point and the section B

L

/ V

TRIPnom

TH(R)max

TH(R)min

comparator provides the V trip-point, with the built-in

H

MaxdevV

= V

• {2 • R •[(V

–0.39)

TRIPnom

TRIP↓

TRIPnom

] + 1.27 • (V

TOL

– V

hysteresis providing about 1.7% recovery level at each

trip point to prevent output chatter.

/ V

)}

TRIPnom

TH(F)max

TH(F)min

For designs that are to be optimized to detect departure

from a window limit, the nominal resistor divider values

are selected as follows (refer to the resistor designators

shown on the first circuit of Figure 1):

Generating an Eꢀternal Reference Signal

In some applications, it would be advantageous to have

access to a signal that is directly related to the internal

400mV reference, even though the reference itself is not

availableexternally.Thiscanbeaccomplishedtoareason-

able degree by using an inverting comparator section as

a “bang-bang” servo, establishing a nominal voltage, on

an integration capacitor, that is scaled to the reference.

This method is used in Figure 2, where the reference level

has been doubled to drive a resistor bridge. The section

B output cycles on and off to swing the section B input

between its hysteresis trip points as the load capacitor

R1 ≤ 400k (this sets the divider current >> I of inputs)

B

R2 = R1 • (0.98 • V /V – 1)

H

L

R3 = R1 • (2.5 • V – 0.98 • V /V )

H

L

To create window functions optimized for detecting entry

into a window (i.e., where the output is to indicate a “com-

ing into spec” condition, aswith the examples in Figure 1),

3.3V Supply Monitor

5V Supply Monitor

3.3V

5V

V

H

L

R3

V

OUT

487k

301k

V

S

33k

+INA OUTA

LT6700-1

+INA OUTA

6.04k LT6700-1

–INB OUTB

0.1µF

R2

6.04k

V

S

V

OUT

–INB OUTB

GND

HIGH = (3.1V < V < 3.5V)

S

HIGH = (4.7V < V < 5.3V)

S

R1

40.2k

GND

40.2k

HYSTERESIS ZONES

APPROXIMATELY

2% OF TRIP VOLTAGE

6700123 F01

Figure ±1 Simple Window °omparator

6700123fh

For more information www.linear.com/LT6700

15

LT6700/LT6700HV

APPLICATIONS INFORMATION

0.1µF

LT6700HVlendsitselfnicelytoformingacharge-balancing

PWMfunction. ThecircuitshowninFigure3formsaPWM

that is intended to transmit an isolated representation of a

voltage difference, rather like an isolated instrumentation

amplifier. The section B comparator is used to generate a

2VreferencesupplylevelfortheCMOSNOTgate(inverter),

whichservesastheprecisionswitchelementforthecharge

balancer. The heart of the charge balancer is the section A

comparator, which is detecting slight charge or discharge

states on the 0.22µF “integration” capacitor as it remains

balanced at ≈400mV by feedback through the NOT gate.

1.4V TO 18V

(I ≈ 10µA)

S

2 • V

REF

R

T

499k

220k 220k*

T < T

SET

V

S

+INA OUTA

SET

LT6700-1

10k

–INB OUTB

GND

R

TH

3.3µF

6700123 F02

R

= 1M (e.g., YSI 44015, 1.00MΩ AT 25°C)

TH

= R AT T

SET

TH

SET

The input sense voltage, V , is converted to an imbal-

IN

*RESISTANCE MAY REQUIRE OPTIMIZATION FOR OPERATION

OVER INTENDED R AND V

HYSTERESIS ZONE ≈0.4°C

RANGES

ance current that the NOT gate duty cycle is continually

TH

SUPPLY

correcting for, thus the digital waveform at the section A

Figure .1 Micropower Thermostat/Temperature Alarm

comparator output is a PWM representation of V with

IN

respect to the 2V “full scale.” In this particular circuit, the

charges and discharges in a shallow, controlled fashion.

The multiplied reference signal also contains ripple that is

the hysteresis multiplied by the same factor, so additional

filtering is performed at the sense node of the bridge to

prevent comparator chatter in the section A comparator,

which is performing the actual conditional decision for

the circuit.

PWMinformationdrivestheLEDofanopto-coupler,allow-

ing the V information to be coupled across a dielectric

IN

barrier. As an additional option to the circuit, the feedback

loopcanbebrokenandasecondopto-coupleremployedto

provide the charge balance management. This configura-

tion allows for clocking the comparator output (externally

to this circuit) and providing synchronous feedback such

that a simple Δ∑ voltage-to-frequency conversion can be

formedifdesired.Approximately11-bitaccuracyandnoise

performance was observed in a one second integration

period for duty factors from 1% to 99%.

Instrumentation Grade Pulse Width Modulator (PWM)

Comparators with hysteresis are frequently employed

to make simple oscillator structures, and the LT6700/

3V/5V

3V NOM (I < 3mA)

S

10k

+

Lithium

COIN CELL

0.1µF

750Ω

PWM OUT

10k**

(OR ΔΣ SENSE)

1

2

6

470Ω

5 • V

= 2V

REF

MOC-207

22µF

412k*

10k 10k

V

NC7S14

309k*

S

309k*

††

5

+INA OUTA

LT6700-1

10k

0.1µF

3V/5V

750**

†

+

–INB OUTB

GND

V

IN

0.22µF

100k* 100k*

0V TO 2V

6

1

–

MOC-207**

6700123 F03

*1% METAL FILM

5

2

**DELETE FOR PWM MODE

†

ΔΣ

SAMPLE

IN

CONNECT FOR PWM MODE

††

OPTIMIZED FOR 2kHz ΔΣ SAMPLING, f

≈ 0.6kHz

PWM(MAX)

Figure 31 Isolated PWM or ∆∑ °onverter

6700123fh

16

For more information www.linear.com/LT6700

LT6700/LT6700HV

PACKAGE INFORMATION

D°B Package

6-Lead Plastic DFN (.mm × 3mm)

(Reference LTC DWG # 05-08-1715 Rev A)

0.70 0.05

1.65 0.05

3.55 0.05

(2 SIDES)

2.15 0.05

PACKAGE

OUTLINE

0.25 0.05

0.50 BSC

1.35 0.05

(2 SIDES)

RECOMMENDED SOLDER PAD PITCH AND DIMENSIONS

R = 0.115

TYP

2.00 0.10

(2 SIDES)

0.40 0.10

R = 0.05

TYP

4

6

3.00 0.10 1.65 0.10

(2 SIDES)

PIN 1 BAR

TOP MARK

(SEE NOTE 6)

PIN 1 NOTCH

R0.20 OR 0.25

× 45° CHAMFER

(DCB6) DFN 0405

3

1

0.25 0.05

0.50 BSC

0.75 0.05

0.200 REF

1.35 0.10

(2 SIDES)

BOTTOM VIEW—EXPOSED PAD

0.00 – 0.05

NOTE:

1. DRAWING TO BE MADE A JEDEC PACKAGE OUTLINE M0-229 VARIATION OF (TBD)

2. DRAWING NOT TO SCALE

3. ALL DIMENSIONS ARE IN MILLIMETERS

4. DIMENSIONS OF EXPOSED PAD ON BOTTOM OF PACKAGE DO NOT INCLUDE

MOLD FLASH. MOLD FLASH, IF PRESENT, SHALL NOT EXCEED 0.15mm ON ANY SIDE

5. EXPOSED PAD SHALL BE SOLDER PLATED

6. SHADED AREA IS ONLY A REFERENCE FOR PIN 1 LOCATION ON THE

TOP AND BOTTOM OF PACKAGE

6700123fh

For more information www.linear.com/LT6700

17

LT6700/LT6700HV

PACKAGE INFORMATION

S6 Package

6-Lead Plastic TSOT-.3

(Reference LTC DWG # 05-08-1636)

2.90 BSC

(NOTE 4)

0.62

MAX

0.95

REF

1.22 REF

1.4 MIN

1.50 – 1.75

2.80 BSC

3.85 MAX 2.62 REF

(NOTE 4)

PIN ONE ID

RECOMMENDED SOLDER PAD LAYOUT

PER IPC CALCULATOR

0.30 – 0.45

6 PLCS (NOTE 3)

0.95 BSC

0.80 – 0.90

0.20 BSC

DATUM ‘A’

0.01 – 0.10

1.00 MAX

0.30 – 0.50 REF

1.90 BSC

0.09 – 0.20

(NOTE 3)

S6 TSOT-23 0302 REV B

NOTE:

1. DIMENSIONS ARE IN MILLIMETERS

2. DRAWING NOT TO SCALE

3. DIMENSIONS ARE INCLUSIVE OF PLATING

4. DIMENSIONS ARE EXCLUSIVE OF MOLD FLASH AND METAL BURR

5. MOLD FLASH SHALL NOT EXCEED 0.254mm

6. JEDEC PACKAGE REFERENCE IS MO-193

6700123fh

18

For more information www.linear.com/LT6700

LT6700/LT6700HV

REVISION HISTORY ^{(Revision history begins at Rev G)}

REV

DATE

DES°RIPTION

PAGE NUMBER

G

5/10

Power Supplies section updated

Modified part number header for clarity

Web hyperlinks added

14

1 to 20

1-20

2, 3

H

6/13

Addition of MP grade in SOT23 package

6700123fh

Information furnished by Linear Technology Corporation is believed to be accurate and reliable.

However, no responsibility is assumed for its use. Linear Technology Corporation makes no representa-

For more information www.linear.com/LT6700

19

tion that the interconnection of its circuits as described herein will not infringe on existing patent rights.

LT6700/LT6700HV

TYPICAL APPLICATIONS

PowerPath™ °ontroller

B0520LW

V

SUPPLY

“WART” INPUT

3.3V NOM

1.6V MIN

3V NOM

Si2301DS

10k

1k

100k

1M

R1

+

ALKALINE

AA CELLS

V

S

+INA OUTA

V > 3.1V

WART

LT6700-3

+INB OUTB

GND

V

> 2V

BATT

R2

1µF

150k 249k

6700123 TA04

R1 = 400k/(V

R2 = 400k/(V

AT LOW – 0.4)

AT MAX – 0.4)

BATT

HYSTERESIS ZONES APPROXIMATELY 2% OF TRIP VOLTAGE

PowerPath IS A TRADEMARK OF LINEAR TECHNOLOGY CORPORATION

48V Status Monitor

+

33k

22V

CMPZ5251B

1.74M

7.87k

V

L

3V/5V

H

V

S

LED OFF

+INA OUTA

V

OUT

V

LT6700-1

27k

33k

IN

V

OUT

–INB OUTB

GND

LED ON

LOW = (39V < V < 70V)

IN

1

6

V

IN

HYSTERESIS ZONES

APPROXIMATELY

2% OF TRIP VOLTAGE

0.1µF

MOC-207

10k

2

5

5.1V

CMPZ5231B

6700123 TA03

–

RELATED PARTS

PART NUMBER

LT1017/LT1018

LTC1441/LTC1442

LTC1998

DES°RIPTION

Micropower Dual Comparator

°OMMENTS

1.1V (Min) Supply Voltage, 1.4mV (Max) Input Offset

1.182 1% Reference, 10mV (Max) Input Offset

Micropower Dual Comparator with 1% Reference

Micropower Comparator for Battery Monitoring

Micropower Comparator with 400mV Reference

2.5µA Typ Supply Current, Adjustable Threshold and Hysteresis

1.4V to 18V Supply Current, 6.5µA Supply Current

LT6703

6700123fh

LT 0613 REV H • PRINTED IN USA

20 ^{LinearTechnology Corporation}

For more information www.linear.com/LT6700

(408)432-1900 FAX: (408) 434-0507 www.linear.com/LT6700

1630 McCarthy Blvd., Milpitas, CA 95035-7417

●

 LINEAR TECHNOLOGY CORPORATION 2003


型号：	LT6700HDCB-3
厂家：	Linear
描述：	Micropower, Low Voltage, Dual Comparator with 400mV Reference 微功耗，低电压，双通道比较具有400mV基准
文件：	总20页 (文件大小：412K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

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