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LTC1043

Dual Precision

Instrumentation Switched Capacitor

Building Block

DESCRIPTIO

The LTC

1043 is a monolithic, charge-balanced, dual

switched capacitor instrumentation building block. A pair

of switches alternately connects an external capacitor to

an input voltage and then connects the charged capacitor

across an output port. The internal switches have a

break-before-make action. An internal clock is provided

and its frequency can be adjusted with an external

capacitor. The LTC1043 can also be driven with an external

CMOS clock.

The LTC1043, when used with low clock frequencies,

provides ultra precision DC functions without requiring

precise external components. Such functions are

differential voltage to single-ended conversion, voltage

inversion, voltage multiplication and division by 2, 3, 4, 5,

etc. The LTC1043 can also be used for precise V–F and

F–V circuits without trimming, and it is also a building

block for switched capacitor filters, oscillators and

modulators.

The LTC1043 is manufactured using Linear Technology’s

enhanced LTCMOS

silicon gate process.

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

LTCMOS is a trademark of Linear Technology Corporation.

FEATURES

■

Instrumentation Front End with 120dB CMRR

Precise, Charge-Balanced Switching

Operates from 3V to 18V

Internal or External Clock

Operates up to 5MHz Clock Rate

Low Power

Two Independent Sections with One Clock

APPLICATIO S

■

Precision Instrumentation Amplifiers

Ultra Precision Voltage Inverters, Multipliers

and Dividers

V–F and F–V Converters

Sample-and-Hold

Switched Capacitor Filters

TYPICAL APPLICATIO

Instrumentation Amplifier

140

1µF

DIFFERENTIAL

INPUT

1µF

0.01µF

LTC1043 • TA01

= C

= 1µF

–

OUT

CMRR (dB)

120

100

1/2 LTC1013

–5V

1µF

(EXTERNAL)

1/2 LTC1043

CMRR > 120dB AT DC

CMRR > 120dB AT 60Hz

DUAL SUPPLY OR SINGLE 5V

GAIN = 1 + R2/R1

≈

150µV

∆

≈

2µV/°C

∆

COMMON MODE INPUT VOLTAGE INCLUDES THE SUPPLIES

10k

100k

FREQUENCY OF COMMON MODE SIGNAL

LTC1043 • TA02

–5V

CMRR vs Frequency

1043fa

LTC1043

ABSOLUTE

(Note 1)

AXI U

RATI GS

PACKAGE/ORDER I FOR ATIO

TOP VIEW

B+

B–

S2B

S1B

S1A

S2A

18 S3B

17 V

–

16 C

OSC

15 S4B

14 S4A

13 S3A

12 C

A–

11 C

A+

10 SH

Supply Voltage ........................................................ 18V

Input Voltage at Any Pin .......... –0.3V

≤

+ 0.3V

Operating Temperature Range

LTC1043C ................................... –40°C

≤

85°C

LTC1043M

(OBSOLETE).............–

55°C

≤

125°C

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

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

ORDER PART

NUMBER

LTC1043CN

LTC1043CSW

SW PACKAGE

18-LEAD PLASTIC SO

JMAX

= 100°C,

= 100°C/W

PACKAGE (N)

JMAX

= 150°C,

= 85°C/W PACKAGE (SW)

D PACKAGE

18-LEAD SIDE BRAZED (HERMETIC)

N PACKAGE

18-LEAD PDIP

LTC1043MD

OBSOLETE PACKAGE

Consider the N18 Package as an Alternate Source

LTC1043 • POI01

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

ELECTRICAL CHARACTERISTICS

range, otherwise specifications are at T

= 25°C. V

–40°C

≤

85°C, unless otherwise noted.

SYMBOL PARAMETER

Power Supply Current

CONDITIONS

The

●

denotes specifications which apply over the full operating temperature

–

= 0V, LTC1043M operates from –55°C

≤

125°C; LTC1043C operates from

= 10V, V

LTC1043M

MIN TYP MAX

0.25

●

LTC1043C

MIN TYP MAX

0.25

0.4

240

400

185

120

0.4

0.7

0.65

100

400

700

100

UNITS

Ω

kΩ

kHz

µA

MHz

Pin 16 Connected High or Low

OSC

(Pin 16 to V

–

) = 100pF

●

0.4

0.7

0.65

100

500

400

700

100

0.4

240

●

OSC

OFF Leakage Current

ON Resistance

Internal Oscillator Frequency

Any Switch, Test Circuit 1 (Note 2)

●

Test Circuit 2, V

= 7V, 1 =

±0.5mA

= 10V, V

–

= 0V

Test Circuit 2, V

= 3.1V, 1 =

±0.5mA

= 5V, V

–

= 0V

OSC

(Pin 16 to V

–

) = 0pF

OSC

(Pin 16 to V

–

) = 100pF

Test Circuit 3

Pin 16 at V

or V

–

400

●

185

OSC

Pin Source or Sink Current

Break-Before-Make Time

Clock to Switching Delay

OSC

Pin Externally Driven

OSC

Pin Externally Driven with CMOS Levels

= 5V, V

–

= –5V, –5V < V

< 5V

DC to 400Hz

120

CMRR

Max External CLK Frequency

Common Mode Rejection Ratio

Note 1:

Absolute Maximum Ratings are those values beyond which the life

of a device may be impaired.

Note 2:

OFF leakage current is guaranteed but not tested at 25°C.

1043fa

W W

LTC1043

TYPICAL PERFOR A CE CHARACTERISTICS

Power Supply Current vs

Power Supply Voltage

1.6

= –55°C

OSC

= 0pF

1.4

OSC

= 0.0047pF

SUPPLY CURRENT (mA)

1.2

1.0

0.8

(Ω)

= 25°C

OSC

= 0pF

OSC

= 0.0047pF

= 125°C

OSC

= 0pF

0.6

OSC

= 0.0047pF

0.4

0.2

8 10 12 14 16 18 20

SUPPLY

(V)

LTC1043 • TPC01

vs V

260

240

220 V

200

(Ω)

180

160

140

120

100

10 12 14 16 18 20

(V)

LTC1043 • TPC04

(PEAK)

I = 100µA

V+ = 15V

V – = 0V

= 25°C

I = 100µA

I = mA

500

400

300

200

100

(Ω)

Oscillator Frequency, f

OSC

vs C

OSC

= 25°C

100k

200

175

OSC

(kHz)

V+ = 10V, V – = 0V

V+ = 5V, V – = 0V

V+ = 15V, V – = 0V

OSCILLATOR FREQUENCY

NORMALIZED TO f

OSC

AT 5V SUPPLY

OSC

(Hz)

10k

100

OSC

(pF)

10k

U W

LTC1043 • TPC07

(Test Circuits 2 through 4)

vs V

550

500

450 V

400

350

300

250

200

150

100

(V)

LTC1043 • TPC02

vs V

V+ = 5V

V – = 0V

= 25°C

280

260

240 V

220

200

180

160

140

120

100

5 6

(V)

I = 100µA

I = mA

(PEAK)

I = 100µA

V+ = 10V

V – = 0V

= 25°C

(PEAK)

I = 100µA

I = mA

LTC1043 • TPC03

(Peak) vs Power Supply

Voltage

1000

900

800

700

600

≈

3.2V

≈

≤

V+ +

≤18V

V – = 0V

= 25°C

= 1.6V

(PEAK)

I = 100µA

1100

1000

900

800

700

600

500

400

300

200

100

(Peak) vs Power Supply

Voltage and Temperature

(PEAK)

I = 100µA

= 125°C

≈

11V

= 70°C

= –55°C

8 10 12 14 16 18 20

SUPPLY

(V)

LTC1043 • TPC06

≈

15.1V

8 10 12 14 16 18 20

SUPPLY

(V)

LTC1043 • TPC05

Oscillator Frequency, f

OSC

vs Supply Voltage

250

225

= 25°C

2.0

1.8

1.6

1.4

1.2

0.8

0.6

0.4

0.2

Normalized Oscillator Frequency,

OSC

vs Supply Voltage

0pF < C

OSC

< 0.01µF

= 25°C

OSC

= 0pF

150

125

100

8 10 12 14 16 18 20

SUPPLY

(V)

LTC1043 • TPC08

OSC

= 100pF

8 10 12 14 16 18 20

SUPPLY

(V)

LTC1043 • TPC09

1043fa

LTC1043

TYPICAL PERFOR A CE CHARACTERISTICS

Oscillator Frequency, f

OSC

vs Ambient Temperature, T

350

325

300

275

OSC

(kHz)

250

225

200

175

150

125

= 5V, V

–

= 0V

–

PIN 16 SOURCE OR SINK CURRENT (µA)

OSC

= 0pF

NOV

(ns)

= 10V, V

–

= 0V

V = 15V, V = 0V

100

75 100

–50 –25

AMBIENT TEMPERATURE (°C)

LTC1043 • TPC10

BLOCK DIAGRA

U W

125

(Test Circuits 2 through 4)

Break-Before-Make Time, t

NOV

vs Supply Voltage

= 25°C

OSC

Pin I

SINK

, I

SOURCE

vs Supply Voltage

100

SINK,

= –55°C

SINK,

= 25°C

SOURCE,

= –55°C

SOURCE,

= 25°C

SINK,

= 125°C

SOURCE,

= 125°C

8 10 12 14 16 18 20

SUPPLY

(V)

LTC1043 • TPC12

LTC1043 • TPC11

S1A

S2A

11 C

A+

12 C

A–

S3A

CHARGE

BALANCING

CIRCUITRY

S4A

S1B

S2B

2 C

B+

3 C

B–

S3B

CHARGE

BALANCING

CIRCUITRY

S4B

NON-OVERLAPPING

CLOCK

–

OSC

–

OSCILLATOR

THE CHARGE BALANCING CIRCUITRY SAMPLES THE VOLTAGE

AT S3 WITH RESPECT TO S4 (PIN 16 HIGH) AND INJECTS A

SMALL CHARGE AT THE C

PIN (PIN 16 LOW).

THIS BOOSTS THE CMRR WHEN THE LTC1043 IS USED AS AN

INSTRUMENTATION AMPLIFIER FRONT END.

FOR MINIMUM CHARGE INJECTION IN OTHER TYPES OF

APPLICATIONS, S3A AND S3B SHOULD BE GROUNDED

THE SWITCHES ARE TIMED AS SHOWN WITH PIN 16 HIGH

LTC1043 • BD01

1043fa

LTC1043

TEST CIRCUITS

Test Circuit 1. Leakage Current Test

(7, 13, 6, 18)

(8, 14, 5, 15)

NOTE: TO OPEN SWITCHES,

S1 AND S3

SHOULD BE CONNECTED

TO V –. TO OPEN S2, S4,

OSC

PIN SHOULD BE

TO V+ C

OSC

LTC1043 • TC01

Test Circuit 2. R

Test

(7, 13, 6, 18)

(8, 14, 5, 15)

0V TO 10V

(11, 12, 2, 3)

VIN

(11, 12, 2, 3)

100µA to 1mA

CURRENT SOURCE

LTC1043 • TC02

Test Circuit 3. Oscillator Frequency, f

OSC

Test Circuit 4. CMRR Test

OUT

(TEST PIN) 2

V+

V–

OSC

LTC1043

1µF

CAPACITORS ARE

NOT ELECTROLYTIC

LTC1043 • TC03

–

≤

CMRR = 20 LOG

( )

OUT

LTC1043 • TC04

NOTE: FOR OPTIMUM CMRR, THE C

OSC

SHOULD

BE LARGER THAN 0.0047µF, AND

THE SAMPLING CAPACITOR ACROSS

PINS 11 AND 12 SHOULD BE PLACED

OVER A SHIELD TIED TO PIN 10

APPLICATIO S I FOR ATIO

Common Mode Rejection Ratio (CMRR)

The LTC1043, when used as a differential to single-ended

converter rejects common mode signals and preserves

differential voltages (Figure 1). Unlike other techniques,

the LTC1043’s CMRR does not degrade with increasing

common mode voltage frequency. During the sampling

mode, the impedance of Pins 2, 3 (and 11, 12) should be

reasonably balanced, otherwise, common mode signals

will appear differentially. The value of the CMRR depends

on the value of the sampling and holding capacitors

, C

) and on the sampling frequency. Since the

common mode voltages are not sampled, the

common mode signal frequency can well exceed the

sampling frequency without experiencing aliasing

phenomena. The CMRR of Figure 1 is measured by

1/2 LTC1043

U U

–

, C

ARE MYLAR OR POLYSTRENE

LTC1043 • AI01

Figure 1. Differential to Single-Ended Converter

1043fa

参数对比

与LTC1043CSW相近的元器件有：LTC1043CN#PBF、LTC1043CSW#PBF、LTC1043CSW#TR、LTC1043CSW#TRPBF。描述及对比如下：

型号	LTC1043CSW	LTC1043CN#PBF	LTC1043CSW#PBF	LTC1043CSW#TR	LTC1043CSW#TRPBF
描述	INST Amp Dual ±9V/18V 18-Pin SOIC W	INST Amp Dual ±9V/18V 18-Pin PDIP N Tube	INST Amp Dual ±9V/18V 18-Pin SOIC W Tube	INST Amp Dual ±9V/18V 18-Pin SOIC W T/R	INST Amp Dual ±9V/18V 18-Pin SOIC W T/R
欧盟限制某些有害物质的使用	Not Compliant	Compliant	Compliant	Not Compliant	Compliant
ECCN (US)	EAR99	EAR99	EAR99	EAR99	EAR99
Part Status	Unconfirmed	Active	Active	Unconfirmed	Active
HTS	8542.39.00.01	8542.33.00.01	8542.33.00.01	8542.33.00.01	8542.33.00.01
Number of Channels per Chip	2	2	2	2	2
Minimum CMRR (dB)	120(Typ)	120(Typ)	120(Typ)	120(Typ)	120(Typ)
Minimum CMRR Range (dB)	120(Typ)	120(Typ)	120(Typ)	120(Typ)	120(Typ)
Maximum Operating Supply Voltage (V)	±9\|18	±9\|18	±9\|18	±9\|18	18\|±9
Maximum Supply Voltage Range (V)	18 to 20	18 to 20	18 to 20	18 to 20	18 to 20
Minimum Single Supply Voltage (V)	3	3	3	3	3
Typical Single Supply Voltage (V)	5\|9\|12\|15	5\|9\|12\|15	5\|9\|12\|15	5\|9\|12\|15	5\|9\|12\|15
Maximum Single Supply Voltage (V)	18	18	18	18	18
Minimum Dual Supply Voltage (V)	±1.5	±1.5	±1.5	±1.5	±1.5
Typical Dual Supply Voltage (V)	±3\|±5	±3\|±5	±3\|±5	±3\|±5	±5\|±3
Maximum Dual Supply Voltage (V)	±9	±9	±9	±9	±9
Maximum Supply Current (mA)	0.65@10V	0.65@10V	0.65@10V	0.65@10V	0.65@10V
Typical Output Current (mA)	0.04@10V	0.04@10V	0.04@10V	0.04@10V	0.04@10V
Power Supply Type	Single\|Dual	Single\|Dual	Single\|Dual	Single\|Dual	Single\|Dual
Minimum Operating Temperature (°C)	-40	-40	-40	-40	-40
Maximum Operating Temperature (°C)	85	85	85	85	85
Pin Count	18	18	18	18	18
Standard Package Name	SOP	DIP	SOP	SOP	SOP
Supplier Package	SOIC W	PDIP N	SOIC W	SOIC W	SOIC W
Mounting	Surface Mount	Through Hole	Surface Mount	Surface Mount	Surface Mount
Package Height	2.34(Max)	3.3	2.34(Max)	2.34(Max)	2.34(Max)
Package Length	11.76(Max)	23.37(Max)	11.76(Max)	11.76(Max)	11.76(Max)
Package Width	7.6(Max)	6.48	7.6(Max)	7.6(Max)	7.6(Max)
PCB changed	18	18	18	18	18
Lead Shape	Gull-wing	Through Hole	Gull-wing	Gull-wing	Gull-wing
系列 Packaging	-	Tube	Tube	Tape and Reel	Tape and Reel