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LT6600-20

Very Low Noise, Differential

Ampliﬁer and 20MHz Lowpass Filter

FEATURES

DESCRIPTION

The LT

6600-20 combines a fully differential ampliﬁer with a

4th order 20MHz lowpass ﬁlter approximating a Chebyshev

frequency response. Most differential ampliﬁers require

many precision external components to tailor gain and

bandwidth. In contrast, with the LT6600-20, two external

resistors program differential gain, and the ﬁlter’s 20MHz

cutoff frequency and passband ripple are internally set.

The LT6600-20 also provides the necessary level shifting

to set its output common mode voltage to accommodate

the reference voltage requirements of A/Ds.

Using a proprietary internal architecture, the LT6600-20

integrates an antialiasing ﬁlter and a differential ampli-

ﬁer/driver without compromising distortion or low noise

performance. At unity gain the measured in band signal-

to-noise ratio is an impressive 76dB. At higher gains the

input referred noise decreases so the part can process

smaller input differential signals without signiﬁcantly

degrading the output signal-to-noise ratio.

The LT6600-20 also features low voltage operation. The

differential design provides outstanding performance for

a 2V

P-P

signal level while the part operates with a single

3V supply.

The LT6600-20 is packaged in an SO-8 and is pin compat-

ible with stand alone differential ampliﬁers.

Programmable Differential Gain via Two External

Resistors

Adjustable Output Common Mode Voltage

Operates and Speciﬁed with 3V, 5V, ±5V Supplies

0.5dB Ripple 4th Order Lowpass Filter with 20MHz

Cutoff

76dB S/N with 3V Supply and 2V

P-P

Output

Low Distortion, 2V

P-P

, 800Ω Load

2.5MHz: 83dBc 2nd, 88dBc 3rd

20MHz: 63dBc 2nd, 64dBc 3rd

Fully Differential Inputs and Outputs

SO-8 Package

Compatible with Popular Differential Ampliﬁer

Pinouts

APPLICATIONS

High Speed ADC Antialiasing and DAC Smoothing in

Networking or Cellular Base Station Applications

High Speed Test and Measurement Equipment

Medical Imaging

Drop-in Replacement for Differential Ampliﬁers

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

All other trademarks are the property of their respective owners.

TYPICAL APPLICATION

LT6600-20

0.1μF

402Ω 1

0.01μF

402Ω

A/D

LTC1748

AMPLITUDE (dB)

OUT

1μF

GAIN = 402Ω/R

66002 TA01a

An 8192 Point FFT Spectrum

–10

–20

–30

–40

–50

–60

–70

–80

–90

–100

–110

–120

FREQUENCY (MHz)

66002 TA01b

INPUT 5.9MHz

P-P

SAMPLE

= 80MHz

–

MID

OCM

–

49.9Ω

18pF

49.9Ω

–

66002fb

LT6600-20

ABSOLUTE MAXIMUM RATINGS

(Note 1)

PIN CONFIGURATION

TOP VIEW

–

OCM

OUT

MID

–

OUT

–

Total Supply Voltage .................................................11V

Input Current (Note 8)..........................................±10mA

Operating Temperature Range (Note 6).... –40°C to 85°C

Speciﬁed Temperature Range (Note 7) .... –40°C to 85°C

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

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

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

S8 PACKAGE

8-LEAD PLASTIC SO

JMAX

= 150°C,

= 100°C/W

ORDER INFORMATION

LEAD FREE FINISH

LT6600CS8-20#PBF

LT6600IS8-20#PBF

LEAD BASED FINISH

LT6600CS8-20

LT6600IS8-20

TAPE AND REEL

LT6600CS8-20#TRPBF

LT6600IS8-20#TRPBF

TAPE AND REEL

LT6600CS8-20#TR

LT6600IS8-20#TR

PART MARKING

660020

600I20

PART MARKING

660020

600I20

PACKAGE DESCRIPTION

8-Lead Plastic SO

PACKAGE DESCRIPTION

8-Lead Plastic SO

TEMPERATURE RANGE

–40°C to 85°C

TEMPERATURE RANGE

–40°C to 85°C

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

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/

The

denotes the speciﬁcations which apply over the full operating temperature

range, otherwise speciﬁcations are at T

= 25°C. Unless otherwise speciﬁed V

= 5V (V

= 5V, V

–

= 0V), R

= 402Ω, and R

LOAD

= 1k.

PARAMETER

Filter Gain, V

= 3V

CONDITIONS

= 2V

P-P

, f

= DC to 260kHz

= 2V

P-P

, f

= 2MHz (Gain Relative to 260kHz)

= 2V

P-P

, f

= 10MHz (Gain Relative to 260kHz)

= 2V

P-P

, f

= 16MHz (Gain Relative to 260kHz)

= 2V

P-P

, f

= 20MHz (Gain Relative to 260kHz)

= 2V

P-P

, f

= 60MHz (Gain Relative to 260kHz)

= 2V

P-P

, f

= 100MHz (Gain Relative to 260kHz)

Filter Gain, V

= 5V

= 2V

P-P

, f

= DC to 260kHz

= 2V

P-P

, f

= 2MHz (Gain Relative to 260kHz)

= 2V

P-P

, f

= 10MHz (Gain Relative to 260kHz)

= 2V

P-P

, f

= 16MHz (Gain Relative to 260kHz)

= 2V

P-P

, f

= 20MHz (Gain Relative to 260kHz)

= 2V

P-P

, f

= 60MHz (Gain Relative to 260kHz)

= 2V

P-P

, f

= 100MHz (Gain Relative to 260kHz)

Filter Gain, V

= ±5V

= 2V

P-P

, f

= DC to 260kHz

ELECTRICAL CHARACTERISTICS

MIN

–0.4

–0.1

–0.2

–0.1

–0.8

TYP

0.1

0.5

–33

–50

MAX

0.5

0.1

0.5

1.9

–28

0.5

0.1

0.4

1.6

0.6

–28

0.4

UNITS

66002fb

–0.5

–0.1

–0.2

–0.3

–1.3

0.1

0.4

–0.4

–33

–50

–0.6

–0.1

LT6600-20

ELECTRICAL CHARACTERISTICS

PARAMETER

Filter Gain, R

= 100

CONDITIONS

= 0.5V

P-P

, f

= DC to 260kHz, V

= 3V

= 0.5V

P-P

, f

= DC to 260kHz, V

= 5V

= 0.5V

P-P

, f

= DC to 260kHz, V

= 5V

= 250kHz, V

= 2V

P-P

Noise BW = 10kHz to 20MHz

2.5MHz, 2V

P-P

, R

= 800Ω

20MHz, 2V

P-P

, R

= 800Ω

Differential Output Swing

Input Bias Current

Input Referred Differential Offset

Measured Between Pins 4 and 5

Average of Pin 1 and Pin 8

= 402Ω

= 3V

= 5V

= ±5V

= 3V

= 5V

= ±5V

= 3V

= 5V

= ±5V

= 3V

= 5V

= ±5V

= 3V

= 5V

= ±5V

= 5

= 3

OCM

= V

MID

= V

= 5V

= 3V

= 3V, V

= 5

= 3V, V

= 5

= ±5V

2nd Harmonic

3rd Harmonic

2nd Harmonic

3rd Harmonic

= 5V

= 3V

The

denotes the speciﬁcations which apply over the full operating temperature

range, otherwise speciﬁcations are at T

= 25°C. Unless otherwise speciﬁed V

= 5V (V

= 5V, V

–

= 0V), R

= 402Ω, and R

LOAD

= 1k.

MIN

11.6

11.5

11.4

TYP

12.1

12.0

11.9

780

118

3.80

3.75

–95

4.75

4.50

–50

Differential Input = 500mV

P-P

= 100Ω

Differential Input = 2V

P-P

Pin 7 = OPEN

Common Mode Voltage at Pin 2

0.0

–2.5

1.0

1.5

–1.0

–35

–40

–55

2.46

4.35

–15

–10

–5

2.51

1.5

5.7

–3

2.55

7.65

1.5

3.0

1.0

1.5

3.0

2.0

MAX

12.6

12.5

12.4

UNITS

ppm/C

μV

RMS

dBc

P-P DIFF

μA

μV/°C

kΩ

μA

Filter Gain Temperature Coefﬁcient (Note 2)

Noise

Distortion (Note 4)

= 100Ω

Differential Offset Drift

Input Common Mode Voltage (Note 3)

Output Common Mode Voltage (Note 5)

Output Common Mode Offset

(with Respect to Pin 2)

Common Mode Rejection Ratio

Voltage at V

MID

(Pin 7)

MID

Input Resistance

OCM

Bias Current

Power Supply Current

Note 1:

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 2:

This is the temperature coefﬁcient of the internal feedback

resistors assuming a temperature independent external resistor (R

Note 3:

The input common mode voltage is the average of the voltages

applied to the external resistors (R

). Speciﬁcation guaranteed for R

≥

100Ω.

Note 4:

Distortion is measured differentially using a differential stimulus.

The input common mode voltage, the voltage at Pin 2, and the voltage at

Pin 7 are equal to one half of the total power supply voltage.

Note 5:

Output common mode voltage is the average of the voltages at

Pins 4 and 5. The output common mode voltage is equal to the voltage

applied to Pin 2.

Note 6:

The LT6600C-20 is guaranteed functional over the operating

temperature range –40°C to 85°C.

Note 7:

The LT6600C-20 is guaranteed to meet 0°C to 70°C speciﬁcations

and is designed, characterized and expected to meet the extended

temperature limits, but is not tested at –40°C and 85°C. The LT6600I-20 is

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

Note 8:

The inputs are protected by back-to-back diodes. If the differential

input voltage exceeds 1.4V, the input current should be limited to less than

10mA.

66002fb

LT6600-20

TYPICAL PERFORMANCE CHARACTERISTICS

Amplitude Response

–10

–20

GAIN (dB)

–30

–40

–50

–60

–70

–80

= 5V

GAIN = 1

= 25°C

FREQUENCY (MHz)

100

66002 G01

Passband Gain and Phase

–2

–4

–6

–8

–10

–12

–14

–16

–18

0.5

6.5

18.5

24.5

12.5

FREQUENCY (MHz)

PHASE

GAIN

= 5V

GAIN = 1

= 25°C

–40

PHASE (DEG)

–85

–130

–175

–220

–265

–310

–355

30.5

66002 G02

–90

0.1

Passband Gain and Group Delay

–2

–4

GAIN (dB)

–6

–8

–10

–12

–14

–16

–18

0.5

6.5

18.5

24.5

12.5

FREQUENCY (MHz)

GROUP

DELAY

GAIN

= 5V

GAIN = 1

= 25°C

30.5

66002 G03

Passband Gain and Group Delay

GAIN (dB)

–2

–4

–6

0.5

6.5

18.5

24.5

12.5

FREQUENCY (MHz)

GROUP

DELAY

GROUP DELAY (ns)

GAIN

= 5V

GAIN = 4

= 25°C

OUTPUT IMPEDANCE (Ω)

30.5

66002 G04

Output Impedance

100

= 5V

GAIN = 1

= 25°C

GROUP DELAY (ns)

0.1

FREQUENCY (MHz)

100

66002 G05

Common Mode Rejection Ratio

CMRR (dB)

PSRR (dB)

0.1

FREQUENCY (MHz)

100

66002 G06

Power Supply Rejection Ratio

100

0.001

–100

0.01

0.1

FREQUENCY (MHz)

100

66002 G07

Distortion vs Frequency

–40

–50

DISTORTION (dB)

–60

–70

–80

–90

DIFFERENTIAL INPUT,

2ND HARMONIC

DIFFERENTIAL INPUT,

3RD HARMONIC

SINGLE-ENDED INPUT,

2ND HARMONIC

SINGLE-ENDED INPUT,

3RD HARMONIC

INPUT = 1V

P-P

= 5V

GAIN = 1

= 25°C

TO DIFFOUT

= 3V

= 25°C

= 2V

P-P

= 3V

= 800Ω AT

EACH OUTPUT

GAIN = 1

= 25°C

0.1

FREQUENCY (MHz)

100

66002 G08

66002fb

LT6600-20

TYPICAL PERFORMANCE CHARACTERISTICS

Distortion

vs Signal Level, V

= 3V

–40

–50

DISTORTION (dB)

–60

–70

–80

–90

–100

INPUT LEVEL (V

P-P

)

66002 G09

Distortion

vs Signal Level, V

= ±5V

–40

–50

DISTORTION (dB)

–60

–70

–80

–90

–100

2ND HARMONIC,

10MHz INPUT

3RD HARMONIC,

10MHz INPUT

2ND HARMONIC,

1MHz INPUT

3RD HARMONIC,

1MHz INPUT

–40

DISTORTION COMPONENT (dB)

–50

–60

–70

–80

–90

Distortion

vs Input Common Mode Level

2ND HARMONIC,

= 3V

3RD HARMONIC,

= 3V

2ND HARMONIC,

= 5V

3RD HARMONIC,

= 5V

P-P

1MHz INPUT

= 800Ω AT

EACH OUTPUT

GAIN = 1

= 25°C

3RD HARMONIC

= 3V

10MHz INPUT

= 800Ω AT

EACH OUTPUT

GAIN = 1

2ND

= 25°C

HARMONIC

10MHz INPUT

3RD

HARMONIC

1MHz INPUT

2ND HARMONIC

1MHz INPUT

= ±5V

= 800Ω AT

EACH OUTPUT

GAIN = 1

= 25°C

INPUT LEVEL (V

P-P

)

66002 G10

–100

–3

–2

–1

INPUT COMMON MODE VOLTAGE

RELATIVE TO PIN 7 (V)

66002 G11

Distortion

vs Input Common Mode Level

–40

DISTORTION COMPONENT (dB)

–50

–60

–70

–80

–90

500mV

P-P

1MHz INPUT, GAIN = 4,

= 800Ω AT EACH OUTPUT

–3

–2

–1

INPUT COMMON MODE VOLTAGE

RELATIVE TO PIN 7 (V)

66002 G12

2ND HARMONIC,

= 3V

3RD HARMONIC,

= 3V

2ND HARMONIC,

= 5V

3RD HARMONIC,

= 5V

–40

DISTORTION COMPONENT (dB)

–50

–60

–70

–80

–90

–100

–110

Distortion

vs Output Common Mode

2ND HARMONIC,

= 3V

3RD HARMONIC,

= 3V

2ND HARMONIC,

= 5V

3RD HARMONIC,

= 5V

2ND HARMONIC,

= ±5V

3RD HARMONIC,

= ±5V

–100

P-P

1MHz INPUT, GAIN = 1,

= 800Ω AT EACH OUTPUT

–2 –1.5 –1 –0.5 0 0.5 1 1.5

VOLTAGE PIN 2 TO PIN 7 (V)

66002 G13

Total Supply Current

vs Total Supply Voltage

TOTAL SUPPLY CURRENT (mA)

2 3 4 5 6 7 8

TOTAL SUPPLY VOLTAGE (V)

= 85°C

= 25°C

= –40°C

DIFFERENTIAL

INPUT

200mV/DIV

OUT

50mV/DIV

Transient Response, Gain = 1

100ns/DIV

66002 G15

66002 G14

66002fb

参数对比

与LT6600CS8-20#PBF相近的元器件有：LT6600CS8-20#TR、LT6600CS8-20#TRPBF、LT6600IS8-20#PBF、LT6600IS8-20#TRPBF。描述及对比如下：

型号	LT6600CS8-20#PBF	LT6600CS8-20#TR	LT6600CS8-20#TRPBF	LT6600IS8-20#PBF	LT6600IS8-20#TRPBF
描述	增益带宽积（GBP）：- 放大器组数：1 运放类型：Differential 各通道功耗：- 压摆率（SR）：- 电源电压：3V ~ 11V, ±1.5V ~ 5.5V	IC opamp differential 8so	IC OPAMP DIFFERENTIAL 8SO	IC OPAMP DIFFERENTIAL 8SO	IC OPAMP DIFFERENTIAL 8SO
Brand Name	Linear Technology	Linear Technology	Linear Technology	Linear Technology	Linear Technology
是否Rohs认证	符合	不符合	符合	符合	符合
厂商名称	Linear ( ADI )	Linear ( ADI )	Linear ( ADI )	Linear ( ADI )	Linear ( ADI )
零件包装代码	SOIC	SOIC	SOIC	SOIC	SOIC
包装说明	SOP, SOP8,.25	SOP, SOP8,.25	SOP, SOP8,.25	SOP, SOP8,.25	SOP, SOP8,.25
针数	8	8	8	8	8
制造商包装代码	S8	S8	S8	S8	S8
Reach Compliance Code	compliant	_compli	compliant	compliant	compliant
ECCN代码	EAR99	EAR99	EAR99	EAR99	EAR99
放大器类型	OPERATIONAL AMPLIFIER	OPERATIONAL AMPLIFIER	OPERATIONAL AMPLIFIER	OPERATIONAL AMPLIFIER	OPERATIONAL AMPLIFIER
标称共模抑制比	66 dB	66 dB	66 dB	66 dB	66 dB
最大输入失调电压	30000 µV	30000 µV	30000 µV	30000 µV	30000 µV
JESD-30 代码	R-PDSO-G8	R-PDSO-G8	R-PDSO-G8	R-PDSO-G8	R-PDSO-G8
JESD-609代码	e3	e0	e3	e3	e3
长度	4.9025 mm	4.9025 mm	4.9025 mm	4.9025 mm	4.9025 mm
湿度敏感等级	1	1	1	1	1
功能数量	1	1	1	1	1
端子数量	8	8	8	8	8
最高工作温度	70 °C	70 °C	70 °C	85 °C	85 °C
封装主体材料	PLASTIC/EPOXY	PLASTIC/EPOXY	PLASTIC/EPOXY	PLASTIC/EPOXY	PLASTIC/EPOXY
封装代码	SOP	SOP	SOP	SOP	SOP
封装等效代码	SOP8,.25	SOP8,.25	SOP8,.25	SOP8,.25	SOP8,.25
封装形状	RECTANGULAR	RECTANGULAR	RECTANGULAR	RECTANGULAR	RECTANGULAR
封装形式	SMALL OUTLINE	SMALL OUTLINE	SMALL OUTLINE	SMALL OUTLINE	SMALL OUTLINE
峰值回流温度（摄氏度）	260	235	260	260	260
电源	3/5/+-5 V	3/5/+-5 V	3/5/+-5 V	3/5/+-5 V	3/5/+-5 V
认证状态	Not Qualified	Not Qualified	Not Qualified	Not Qualified	Not Qualified
座面最大高度	1.752 mm	1.752 mm	1.752 mm	1.752 mm	1.752 mm
最大压摆率	56 mA	56 mA	56 mA	56 mA	56 mA
供电电压上限	11 V	11 V	11 V	11 V	11 V
标称供电电压 (Vsup)	5 V	5 V	5 V	5 V	5 V
表面贴装	YES	YES	YES	YES	YES
温度等级	COMMERCIAL	COMMERCIAL	COMMERCIAL	INDUSTRIAL	INDUSTRIAL
端子面层	Matte Tin (Sn)	Tin/Lead (Sn/Pb)	Matte Tin (Sn)	Matte Tin (Sn)	Matte Tin (Sn)
端子形式	GULL WING	GULL WING	GULL WING	GULL WING	GULL WING
端子节距	1.27 mm	1.27 mm	1.27 mm	1.27 mm	1.27 mm
端子位置	DUAL	DUAL	DUAL	DUAL	DUAL
处于峰值回流温度下的最长时间	30	20	30	30	30
宽度	3.899 mm	3.899 mm	3.899 mm	3.899 mm	3.899 mm

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