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LT1361/LT1362

Dual and Quad

50MHz, 800V/µs Op Amps

FEATURES

DESCRIPTIO

50MHz Gain Bandwidth

800V/µs Slew Rate

5mA Maximum Supply Current per Amplifier

Unity-Gain Stable

C-Load

Op Amp Drives All Capacitive Loads

9nV/√Hz Input Noise Voltage

1mV Maximum Input Offset Voltage

1µA Maximum Input Bias Current

250nA Maximum Input Offset Current

±13V

Minimum Output Swing into 500Ω

±3.2V

Minimum Output Swing into 150Ω

4.5V/mV Minimum DC Gain, R

=1k

60ns Settling Time to 0.1%, 10V Step

0.2% Differential Gain, A

=2, R

=150Ω

0.3° Differential Phase, A

=2, R

=150Ω

Specified at

±2.5V, ±5V,

and

±15V

The LT1361/LT1362 are dual and quad low power high

speed operational amplifiers with outstanding AC and DC

performance. The amplifiers feature much lower supply

current and higher slew rate than devices with comparable

bandwidth. The circuit topology is a voltage feedback

amplifier with matched high impedance inputs and the

slewing performance of a current feedback amplifier. The

high slew rate and single stage design provide excellent

settling characteristics which make the circuit an ideal

choice for data acquisition systems. Each output drives a

500Ω load to

±13V

with

±15V

supplies and a 150Ω load to

±3.2V

±5V

supplies. The amplifiers are stable with any

capacitive load making them useful in buffer or cable

driving applications.

The LT1361/LT1362 are members of a family of fast, high

performance amplifiers using this unique topology and

employing Linear Technology Corporation’s advanced

bipolar complementary processing. For a single amplifier

version of the LT1361/LT1362 see the LT1360 data sheet.

For higher bandwidth devices with higher supply currents

see the LT1363 through LT1365 data sheets. For lower

supply current amplifiers see the LT1354 to LT1359 data

sheets. Singles, duals, and quads of each amplifier are

available.

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

C-Load is a trademark of Linear Technology Corporation

APPLICATIO S

Wideband Amplifiers

Buffers

Active Filters

Video and RF Amplification

Cable Drivers

Data Acquisition Systems

TYPICAL APPLICATIO

Cable Driver Frequency Response

= –1 Large-Signal Response

GAIN (dB)

–2

±15V

±10V

±2.5V

±5V

OUT

75Ω

–4

–6

1/2

LT1361

–

510Ω

75Ω

–8

FREQUENCY (MHz)

100

1361/1362 TA02

1361/1362 TA01

LT1361/LT1362

ABSOLUTE

MAXIMUM

RATINGS

Total Supply Voltage (V

to V

–

) ............................... 36V

Differential Input Voltage

(Transient Only) (Note 2)...................................

±10V

Input Voltage ............................................................

±V

Output Short-Circuit Duration (Note 3) ............ Indefinite

PACKAGE/ORDER INFORMATION

TOP VIEW

OUT A

–IN A

+IN A

–

N8 PACKAGE

8-LEAD PDIP

–IN B

+IN B

OUT B

ORDER PART

NUMBER

LT1361CN8

JMAX

= 150°C,

= 130°C/ W

TOP VIEW

OUT A

OUT D

13 –IN D

12 +IN D

11 V

–

+IN C

–IN C

OUT C

ORDER PART

NUMBER

LT1362CN

–IN A

+IN A

+IN B

–IN B

OUT B

N PACKAGE

14-LEAD PDIP

JMAX

= 150°C,

= 110°C/ W

Consult factory for Industrial and Military grade parts.

ELECTRICAL CHARACTERISTICS

SYMBOL

PARAMETER

Input Offset Voltage

CONDITIONS

(Note 4)

= 25°C, V

= 0V unless otherwise noted.

SUPPLY

±15V

±5V

±2.5V

±15V

±2.5V

±15V

MIN

TYP

0.3

0.4

0.3

0.9

MAX

1.0

1.2

250

1.0

UNITS

µA

nV/√Hz

pA/√Hz

MΩ

Input Offset Current

Input Bias Current

Input Noise Voltage

Input Noise Current

Input Resistance

Input Capacitance

f = 10kHz

±12V

Differential

W W

(Note 1)

Operating Temperature Range (Note 8) ...–40°C to 85°C

Specified Temperature Range (Note 9) ....–40°C to 85°C

Maximum Junction Temperature (See Below)

Plastic Package ................................................ 150°C

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

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

TOP VIEW

OUT A

–IN A

+IN A

–

S8 PACKAGE

8-LEAD PLASTIC SO

–IN B

+IN B

OUT B

ORDER PART

NUMBER

LT1361CS8

S8 PART MARKING

1361

ORDER PART

NUMBER

LT1362CS

JMAX

= 150°C,

= 190°C/ W

TOP VIEW

OUT A

OUT D

15 –IN D

14 +IN D

13 V

–

+IN C

–IN C

OUT C

–IN A

+IN A

+IN B

–IN B

OUT B

S PACKAGE

16-LEAD PLASTIC SO

JMAX

= 150°C,

= 150°C/ W

±2.5V

±15V

±2.5V

±15V

LT1361/LT1362

ELECTRICAL CHARACTERISTICS

SYMBOL

PARAMETER

Input Voltage Range

CONDITIONS

= 25°C, V

= 0V unless otherwise noted.

SUPPLY

±15V

±5V

±2.5V

±15V

±5V

±2.5V

MIN

12.0

2.5

0.5

TYP

13.4

3.4

1.1

–13.2

–3.2

–0.9

±15V

±5V

±2.5V

±15V

±5V

±2.5V

±15V

±5V

±15V

±5V

±15V

±5V

±15V

±5V

±2.5V

±15V

±5V

±15V

±5V

±15V

±5V

±15V

±5V

±15V

±5V

±15V

±5V

±15V

±5V

±15V

±5V

±15V

±5V

100

4.5

3.0

1.5

2.5

13.5

13.0

3.5

3.2

1.3

600

250

105

9.0

6.5

6.4

4.2

5.2

13.9

13.6

4.0

3.8

1.7

800

350

12.7

18.6

3.1

4.3

5.2

6.4

0.20

0.04

0.02

0.40

0.30

0.07

0.26

1.4

113

4.0

3.8

5.0

4.8

–12.0

–2.5

–0.5

MAX

UNITS

V/mV

±V

V/µs

MHz

Deg

Ω

Input Voltage Range

–

CMRR

Common Mode Rejection Ratio

±12V

±2.5V

±0.5V

±2.5V

±15V

OUT

±12V,

= 1k

OUT

±10V,

= 500Ω

OUT

±2.5V,

= 500Ω

OUT

±2.5V,

= 150Ω

OUT

±1V,

= 500Ω

= 1k, V

±40mV

= 500Ω, V

±40mV

= 500Ω, V

±40mV

= 150Ω, V

±40mV

= 500Ω, V

±40mV

OUT

±13V

OUT

±3.2V

OUT

= 0V, V

±3V

= – 2, (Note 5)

10V Peak, (Note 6)

3V Peak, (Note 6)

f = 200kHz

±15V

±5V

±2.5V

PSRR

VOL

Power Supply Rejection Ratio

Large-Signal Voltage Gain

OUT

Output Swing

OUT

Output Current

Short-Circuit Current

Slew Rate

Full Power Bandwidth

GBW

Gain Bandwidth

, t

Rise Time, Fall Time

Overshoot

Propagation Delay

= 1, 10%-90%, 0.1V

= 1, 0.1V

50% V

to 50% V

OUT

, 0.1V

10V Step, 0.1%, A

= –1

10V Step, 0.01%, A

= –1

5V Step, 0.1%, A

= –1

f = 3.58MHz, A

= 2, R

= 150Ω

f = 3.58MHz, A

= 2, R

= 1k

Settling Time

Differential Gain

Differential Phase

f = 3.58MHz, A

= 2, R

= 150Ω

f = 3.58MHz, A

= 2, R

= 1k

Output Resistance

Channel Separation

Supply Current

= 1, f = 1MHz

OUT

±10V,

= 500Ω

Each Amplifier

LT1361/LT1362

0°C

≤

70°C, V

= 0V unless otherwise noted.

SYMBOL

PARAMETER

Input Offset Voltage

ELECTRICAL CHARACTERISTICS

CONDITIONS

(Note 4)

The

denotes the specifications which apply over the temperature range

SUPPLY

±15V

±5V

±2.5V

±15V

±2.5V

±15V

±2.5V

±15V

MIN

TYP

MAX

1.5

1.7

UNITS

µV/°C

µA

V/mV

±V

V/µs

MHz

Input V

Drift

CMRR

Input Offset Current

Input Bias Current

Common Mode Rejection Ratio

(Note 7)

350

1.5

±12V

±2.5V

±0.5V

±2.5V

±15V

OUT

±12V,

= 1k

OUT

±10V,

= 500Ω

OUT

±2.5V,

= 500Ω

OUT

±2.5V,

= 150Ω

OUT

±1V,

= 500Ω

= 1k, V

±40mV

= 500Ω, V

±40mV

= 500Ω, V

±40mV

= 150Ω, V

±40mV

= 500Ω, V

±40mV

OUT

±12.8V

OUT

±3.1V

OUT

= 0V, V

±3V

= – 2, (Note 5)

f = 200kHz

OUT

±10V,

= 500Ω

Each Amplifier

±15V

±5V

±2.5V

±15V

±5V

±2.5V

±15V

±5V

±2.5V

±15V

±5V

±15V

±5V

±15V

±5V

±15V

±5V

3.6

2.4

1.0

2.0

13.4

12.8

3.4

3.1

1.2

475

185

5.8

5.6

PSRR

VOL

Power Supply Rejection Ratio

Large-Signal Voltage Gain

OUT

Output Swing

OUT

GBW

Output Current

Short-Circuit Current

Slew Rate

Gain Bandwidth

Channel Separation

Supply Current

The

denotes the specifications which apply over the temperature range – 40°C

≤

85°C, V

= 0V unless otherwise noted. (Note 9)

SYMBOL

PARAMETER

Input Offset Voltage

CONDITIONS

(Note 4)

SUPPLY

±15V

±5V

±2.5V

±15V

±2.5V

±15V

±2.5V

±15V

±12V

±2.5V

±0.5V

±2.5V

±15V

OUT

±12V,

= 1k

OUT

±10V,

= 500Ω

OUT

±2.5V,

= 500Ω

OUT

±2.5V,

= 150Ω

OUT

±1V,

= 500Ω

±15V

±5V

±2.5V

±15V

±5V

±2.5V

MIN

TYP

MAX

2.0

2.2

UNITS

µV/°C

µA

V/mV

Input V

Drift

CMRR

Input Offset Current

Input Bias Current

Common Mode Rejection Ratio

(Note 7)

400

1.8

2.5

1.5

0.6

1.3

PSRR

VOL

Power Supply Rejection Ratio

Large-Signal Voltage Gain

LT1361/LT1362

ELECTRICAL CHARACTERISTICS

SYMBOL

OUT

PARAMETER

Output Swing

The

denotes the specifications which apply over the temperature range

– 40°C

≤

85°C, V

= 0V unless otherwise noted. (Note 9)

CONDITIONS

= 1k, V

±40mV

= 500Ω, V

±40mV

= 500Ω, V

±40mV

= 150Ω, V

±40mV

= 500Ω, V

±40mV

OUT

±12.0V

OUT

±3.0V

OUT

= 0V, V

±3V

= – 2, (Note 5)

f = 200kHz

OUT

±10V,

= 500Ω

Each Amplifier

SUPPLY

±15V

±5V

±2.5V

±15V

±5V

±15V

±5V

±15V

±5V

±15V

±5V

MIN

13.4

12.0

3.4

3.0

1.2

450

175

TYP

MAX

UNITS

±V

V/µs

MHz

OUT

GBW

Output Current

Short-Circuit Current

Slew Rate

Gain Bandwidth

Channel Separation

Supply Current

6.0

5.8

Note 1:

Absolute Maximum Ratings are those values beyond which the life

of a device may be impaired.

Note 2:

Differential inputs of

±10V

are appropriate for transient operation

only, such as during slewing. Large, sustained differential inputs will cause

excessive power dissipation and may damage the part. See Input

Considerations in the Applications Information section of this data sheet

for more details.

Note 3:

A heat sink may be required to keep the junction temperature

below absolute maximum when the output is shorted indefinitely.

Note 4:

Input offset voltage is pulse tested and is exclusive of warm-up drift.

Note 5:

Slew rate is measured between

±10V

on the output with

±6V

input

for

±15V

supplies and

±1V

on the output with

±1.75V

input for

±5V

supplies.

Note 6:

Full power bandwidth is calculated from the slew rate

measurement: FPBW = SR/2πV

Note 7:

This parameter is not 100% tested.

Note 8:

The LT1361C/LT1362C are guaranteed functional over the

operating temperature range of –40°C to 85°C.

Note 9:

The LT1361C/LT1362C are guaranteed to meet specified

performance from 0°C to 70°C. The LT1361C/LT1362C 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. For

guaranteed I-grade parts, consult the factory.

TYPICAL PERFORMANCE CHARACTERISTICS

Supply Current vs Supply Voltage

and Temperature

COMMON MODE RANGE (V)

125°C

25°C

–1.5

–2.0

INPUT BIAS CURRENT (µA)

SUPPLY CURRENT (mA)

– 55°C

SUPPLY VOLTAGE (±V)

1361/1362 G01

U W

Input Common Mode Range vs

Supply Voltage

–0.5

–1.0

= 25°C

∆V

< 1mV

0.6

0.5

0.4

0.3

0.2

0.1

Input Bias Current vs

Input Common Mode Voltage

±15V

= 25°C

+ + I

–

= ————



2.0

1.5

1.0

0.5

–

SUPPLY VOLTAGE (±V)

1361/1362 G02

–15

–10

–5

INPUT COMMON MODE VOLTAGE (V)

1361/1362 G03

参数对比

与LT1361CS8#TR相近的元器件有：LT1361CN8、LT1361CS8#PBF、LT1361CS8#TRPBF、LT1361CS8。描述及对比如下：

型号	LT1361CS8#TR	LT1361CN8	LT1361CS8#PBF	LT1361CS8#TRPBF	LT1361CS8
描述	Op Amp Dual High Speed Amplifier ±18V 8-Pin SOIC N T/R	Op Amp Dual High Speed Amplifier ±18V 8-Pin PDIP N	Op Amp Dual High Speed Amplifier ±18V 8-Pin SOIC N Tube	Op Amp Dual High Speed Amplifier ±18V 8-Pin SOIC N T/R	Op Amp Dual High Speed Amplifier ±18V 8-Pin SOIC N
欧盟限制某些有害物质的使用	Not Compliant	Not Compliant	Compliant	Compliant	Not Compliant
ECCN (US)	EAR99	EAR99	EAR99	EAR99	EAR99
Part Status	Unconfirmed	Unconfirmed	Active	Active	Unconfirmed
类型 Type	High Speed Amplifier	High Speed Amplifier	High Speed Amplifier	High Speed Amplifier	High Speed Amplifier
Manufacturer Type	High Speed Amplifier	High Speed Amplifier	High Speed Amplifier	High Speed Amplifier	High Speed Amplifier
Number of Channels per Chip	2	2	2	2	2
Process Technology	BiCOM	BiCOM	BiCOM	BiCOM	BiCOM
Maximum Input Offset Voltage (mV)	1@±5V	1@±5V	1@±5V	1@±5V	1@±5V
Minimum Dual Supply Voltage (V)	±2.5	±2.5	±2.5	±2.5	±2.5
Typical Dual Supply Voltage (V)	±3\|±5\|±9\|±12\|±15	±9\|±5\|±3\|±15\|±12	±3\|±5\|±9\|±12\|±15	±3\|±15\|±5\|±9\|±12	±15\|±3\|±5\|±9\|±12
Maximum Dual Supply Voltage (V)	±18	±18	±18	±18	±18
Maximum Input Offset Current (uA)	0.25@±15V	0.25@±15V	0.25@±15V	0.25@±15V	0.25@±15V
Maximum Input Bias Current (uA)	1@±15V	1@±15V	1@±15V	1@±15V	1@±15V
Maximum Supply Current (mA)	9.6@±5V	9.6@±5V	9.6@±5V	9.6@±5V	9.6@±5V
Typical Output Current (mA)	29@±5V	29@±5V	29@±5V	29@±5V	29@±5V
Power Supply Type	Dual	Dual	Dual	Dual	Dual
Typical Slew Rate (V/us)	350@±5V	350@±5V	350@±5V	350@±5V	350@±5V
Typical Input Noise Voltage Density (nV/rtHz)	9@±15V	9@±15V	9@±15V	9@±15V	9@±15V
Typical Voltage Gain (dB)	76.12	76.12	76.12	76.12	76.12
Typical Noninverting Input Current Noise Density (pA/rtHz)	0.9@±15V	0.9@±15V	0.9@±15V	0.9@±15V	0.9@±15V
Minimum PSRR (dB)	93	93	93	93	93
Minimum CMRR (dB)	79	79	79	79	79
Minimum CMRR Range (dB)	75 to 80	75 to 80	75 to 80	75 to 80	75 to 80
Typical Gain Bandwidth Product (MHz)	37	37	37	37	37
Typical Settling Time (ns)	65	65	65	65	65
Shut Down Support	No	No	No	No	No
Maximum Operating Temperature (°C)	70	70	70	70	70
Supplier Temperature Grade	Commercial	Commercial	Commercial	Commercial	Commercial
Pin Count	8	8	8	8	8
Standard Package Name	SOP	DIP	SOP	SOP	SOP
Supplier Package	SOIC N	PDIP N	SOIC N	SOIC N	SOIC N
Mounting	Surface Mount	Through Hole	Surface Mount	Surface Mount	Surface Mount
Package Height	1.5(Max)	3.3	1.5(Max)	1.5(Max)	1.5(Max)
Package Length	5(Max)	10.16(Max)	5(Max)	5(Max)	5(Max)
Package Width	3.99(Max)	6.48	3.99(Max)	3.99(Max)	3.99(Max)
PCB changed	8	8	8	8	8
Lead Shape	Gull-wing	Through Hole	Gull-wing	Gull-wing	Gull-wing
SVHC	Yes	Yes	-	-	Yes
SVHC Exceeds Threshold	Yes	Yes	-	-	Yes
系列 Packaging	Tape and Reel	-	Tube	Tape and Reel	-
HTS	-	8542.33.00.01	8542.33.00.01	-	8542.33.00.01

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