AMMP-5618-BLK [AVAGO]

6-20 GHz General Purpose Amplifier; 6-20 GHz的通用放大器


型号：	AMMP-5618-BLK
厂家：	AVAGO TECHNOLOGIES LIMITED
描述：	6-20 GHz General Purpose Amplifier 6-20 GHz的通用放大器射频和微波射频放大器微波放大器
文件：	总9页 (文件大小：234K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

AMMP-5618

6–20 GHz General Purpose Amplifier

Data Sheet

Description

Features

Avago’s AMMP-5618 is a high power, medium gain • 5 x 5 mm surface mount package

amplifier that operates from 6 GHz to 20 GHz. The

amplifier is designed to be an easy-to-use component

•

Broad band performance 6–20 GHz

for any surface mount PCB application. In • High +19 dBm output power

communication systems, it can be used as a LO buffer,

or as a transmit driver amplifier. During typical

• Medium 13 dB typical gain

operation with a single 5V supply, each gain stage is • 50Ω input and output match

biased for Class-A operation for optimal power output

with minimal distortion. The amplifier has integrated

• Single 5V (107 mA) supply bias

50Ω I/O match, DC blocking, self-bias and choke to

eliminate complex tuning and assembly processes

Applications

typically required by hybrid (discrete-FET) amplifiers.

• Microwave radio systems

The package is fully SMT compatible with backside

grounding and I/O to simplify assembly.

• Satellite VSAT, DBS up/down link

• LMDS & Pt-Pt mmW long haul

Note: These devices are ESD sensitive. The following

precautions are strongly recommended. Ensure that • Broadband wireless access (including 802.16 and 802.20

an ESD approved carrier is used when dice are

transported from one destination to another. Personal

grounding is to be worn at all times when handling

these devices.

WiMax)

• WLL and MMDS loops

• Commercial grade military

Absolute Maximum Ratings^[1]

Symbol

Parameters/Conditions

Units Min. Max.

V_d

Positive Drain Voltage

Drain Current

I_d

dBm

°C

150

RFin

RFout

P_in

CW Input Power

T_ch

Operating Channel Temperature

Storage Case Temperature

+150

+300

T_stg

T_max

Note:

°C

-65

Max. Assembly Temp (60 sec max) °C

1. Operation in excess of any one of these conditions may result in

permanent damage to this device.

Attention:

Observe precautions for handling electrostatic

sensitive devices.

ESD Machine Model (Class A)

ESD Human Body Model (Class 0)

Refer to Avago Application Note A004R: Electrostatic Discharge

Damage and Control.

AMMP-5618 DC Specifications/Physical Properties^[1]

Symbol

Parameters and Test Conditions

Units

Min.

Typ.

Max.

I_d

Drain Supply Current (under any RF power drive and temperature) (V_d=5.0V)

107

140

θ_ch-b

Notes:

Thermal Resistance^[2](Backside temperature, T_b= 25°C)

°C/W

1. Ambient operational temperature T_A= 25°C unless otherwise noted.

2. Channel-to-backside Thermal Resistance (T_channel(T_c) = 34°C) as measured using infrared microscopy. Thermal Resistance at backside temperature (T_b)

= 25°C calculated from measured data.

RF Specifications^[3,4,6](T_A= 25°C, V_d= 5.0V, I_d(Q)=107 mA, Z_o=50 Ω)

Symbol

Parameters and Test Conditions

Units

Typ.

Sigma

Gain

Small-signal Gain^[5]

0.4

0.2

0.9

1.2

Noise Figure into 50Ω^[5]

4.4

P_-1dB

OIP3

Output Power at 1 dB Gain Compression

dBm

+19

+30

Third Order Intercept Point;

∆f = 100 MHz; Pin = -20 dBm

RLin

Input Return Loss

Output Return Loss

Reverse Isolation

-12

-40

0.7

0.6

1.2

RLout

Isol

Notes:

3. Small/Large -signal data measured in a fully de-embedded test fixture form T_A= 25°C.

4. Pre-assembly into package performance verified 100% on-wafer per AMMC-5618 published specifications

5. This final package part performance is verified by a functional test correlated to actual performance at one or more frequencies

6. Specifications are derived from measurements in a 50Ω test environment. Aspects of the amplifier performance may be improved over a more narrow

bandwidth by application of additional conjugate, linearity, or low noise (Γopt) matching.

AMMP-5618 Typical Performance (T_A= 25°C, V_d= 5V, I_d= 107 mA, Z_in= Z_out= 50Ω unless otherwise stated)

Note: These measurements are in 50Ω test environment. Aspects of the amplifier performance may be improved over a narrower

bandwidth by application of additional conjugate, linearity or low noise (Γopt) matching.

-10

-20

-30

-40

-50

-5

-10

-15

-20

-25

-30

10 12 14 16 18 20 22

FREQUENCY (GHz)

10 12 14 16 18 20 22

FREQUENCY (GHz)

10 12 14 16 18 20 22

FREQUENCY (GHz)

Figure 1. Gain.

Figure 2. Isolation.

Figure 3. Input Return Loss.

-5

-10

-15

-20

-25

-30

OP1dB

OIP3

10 12 14 16 18 20 22

FREQUENCY (GHz)

18 20

FREQUENCY (GHz)

Figure 4. Output Return Loss.

Figure 5. Noise Figure.

Figure 6. Typical Power, OP-1dB and OIP3.

-10

-20

-30

-40

-50

-60

25°C

-40°C

+85°C

25°C

-40°C

+85°C

-5

-10

-15

-20

25°C

-40°C

+85°C

-5

10 12 14 16 18 20 22

FREQUENCY (GHz)

10 12 14 16 18 20 22

FREQUENCY (GHz)

10 12 14 16 18 20 22

FREQUENCY (GHz)

Figure 7. Gain Over Temperature.

Figure 8. Isolation Over Temperature.

Figure 9. Input RL Over Temperature.

AMMP-5618 Typical Performance (T_A= 25°C, V_d= 5V, I_d= 107 mA, Z_in= Z_out= 50Ω unless otherwise stated)

Note: These measurements are in 50Ω test environment. Aspects of the amplifier performance may be improved over a narrower

bandwidth by application of additional conjugate, linearity or low noise (Γopt) matching.

-5

108

106

104

102

100

25°C

-40°C

+85°C

25°C

-40°C

+85°C

-10

-15

-20

-25

-30

25°C

-40°C

+85°C

10 12 14 16 18 20 22

FREQUENCY (GHz)

18 20

3.5

4.5

FREQUENCY (GHz)

Vdd (V)

Figure 10. Output Return Loss Over

Temperature.

Figure 11. NF Over Temperature.

Figure 12. Bias Current Over Temperature.

-10

-20

-30

-40

-50

-60

-5

-10

-15

-20

10 12 14 16 18 20

FREQUENCY (GHz)

10 12 14 16 18 20

FREQUENCY (GHz)

10 12 14 16 18 20 22

FREQUENCY (GHz)

Figure 14. Isolation Over Vdd.

Figure 15. Input RL Over Vdd.

Figure 13. Gain Over Vdd.

-5

-10

-15

-20

-25

-30

-35

10 12 14 16 18 20

FREQUENCY (GHz)

18 20

FREQUENCY (GHz)

Figure 16. Output Return Loss Over Vdd.

Figure 17. Output Power Over Vdd.

Figure 18. OIP3 Over Vdd.

AMMP-5618 Typical Scattering Parameters^[1](T_A= 25°C, V_d= 5V, Z_O= 50Ω)

Freq.

GHz

S₁₁

S₂₁

S₁₂

Mag

S₂₂

Mag Phase

Phase

Mag Phase

2.0

-2.995 0.708

-3.432 0.674

-4.250 0.613

-4.096 0.624

-4.325 0.608

-4.797 0.576

-6.417 0.478

-11.055 0.280

-18.578 0.118

-23.802 0.065

-25.186 0.055

-27.287 0.043

-27.021 0.045

-24.540 0.059

-23.582 0.066

-23.477 0.067

-24.304 0.061

-22.475 0.075

-19.215 0.109

-16.258 0.154

-14.234 0.194

-13.024 0.223

-12.514 0.237

-12.482 0.238

-12.919 0.226

-13.636 0.208

-13.993 0.200

-13.835 0.203

-13.000 0.224

-12.524 0.236

-12.067 0.222

-11.963 0.200

-12.862 0.181

-12.547 0.187

-11.062 0.225

-10.610 0.272

-10.469 0.300

-10.018 0.316

-9.997 0.316

-10.136 0.311

-9.631 0.330

-7.870 0.404

-5.619 0.524

-4.449 0.599

-4.155 0.620

-4.196 0.617

-4.530 0.594

70.854

-22.696 0.073

-16.093 0.157

-4.538 0.593

-1.726 0.461

45.614

-58.670

-49.826

-43.091

-36.349

-39.160

-42.543

-50.015

-46.815

-42.183

-40.719

-39.954

-39.602

-39.264

-39.039

-38.938

-38.808

-38.711

-38.700

-38.773

-38.489

-38.221

-38.071

-37.739

-37.252

-37.903

-37.680

-38.692

-39.424

-38.107

-37.443

-37.604

-37.848

-38.170

-38.384

-39.112

-39.698

-40.748

-42.165

-43.928

-45.145

-49.217

-47.596

-53.021

-51.322

-46.344

-45.149

0.001

0.003

0.007

0.015

0.011

0.007

0.003

0.005

0.008

0.009

0.010

0.011

0.012

0.013

0.014

0.013

0.012

0.011

0.012

0.013

0.012

0.011

0.010

0.009

0.008

0.006

0.003

0.004

0.002

0.003

0.005

0.006

91.028

-0.537

0.940

0.923

0.841

0.642

0.615

0.559

0.475

0.373

0.302

0.247

0.191

0.138

0.113

0.126

0.152

0.172

0.180

0.169

0.149

0.119

0.094

0.074

0.063

0.059

0.057

0.050

0.051

0.071

0.081

0.080

0.079

0.072

0.060

0.063

0.093

0.141

0.204

0.265

0.323

0.369

0.437

0.445

0.440

0.421

0.383

0.325

118.786

56.844

2.5

7.524

62.385

-30.565

172.431

-48.599

-129.213

166.320

130.192

155.918

114.699

69.159

-0.694

3.0

-59.292

-112.628

-174.493

121.652

52.449

-0.007

-1.503

-77.196

-20.982

-101.456

-168.104

130.723

79.201

3.5

-157.105

-52.399

-107.307

-175.227

108.456

38.847

-3.848

4.0

0.287

5.870

0.394

1.131

-4.217

4.5

-5.052

5.0

10.805 3.164

13.764 4.712

14.224 5.385

14.468 5.475

14.500 5.495

14.416 5.506

14.509 5.501

14.512 5.503

14.523 5.510

14.491 5.490

14.473 5.479

14.479 5.482

14.388 5.425

14.419 5.382

14.367 5.350

14.328 5.326

14.202 5.249

14.147 5.216

13.972 5.054

14.029 4.971

13.739 4.920

13.725 4.969

13.966 5.109

14.024 5.143

14.002 5.130

14.148 5.217

14.132 5.207

14.210 5.254

14.091 5.183

13.858 5.046

13.623 4.911

13.398 4.785

13.019 4.797

12.886 4.724

12.504 4.219

11.738 3.863

10.831 3.480

-6.475

5.5

-16.473

-62.704

-78.360

-114.355

176.586

89.220

-8.555

6.0

-10.393

-12.156

-14.372

-17.196

-18.937

-17.986

-16.383

-15.281

-14.875

-15.430

-16.520

-18.494

-20.529

-22.659

-24.039

-24.607

-24.958

-26.020

-25.949

-25.799

-23.027

-21.872

-21.936

-22.039

-22.843

-24.452

-24.014

-20.632

-16.990

-13.793

-11.540

-9.819

36.021

6.5

-23.228

-75.874

-127.412

-176.352

134.523

87.924

-7.111

7.0

27.235

-54.746

-111.340

-179.767

115.789

65.272

7.5

-12.197

-50.735

-88.381

-124.530

-160.536

163.632

128.550

92.021

8.0

8.5

16.508

9.0

-43.865

-104.344

-175.038

107.849

44.619

9.5

41.684

25.081

10.0

10.5

11.0

11.5

12.0

12.5

13.0

13.5

14.0

14.5

15.0

15.5

16.0

16.5

17.0

17.5

18.0

18.5

19.0

19.5

20.0

20.5

21.0

21.5

22.0

22.5

23.0

23.5

24.0

24.5

25.0

-3.914

-11.906

-47.630

-83.772

-122.670

-163.935

150.698

107.199

69.051

-48.272

-93.057

-137.014

179.443

136.208

92.923

-5.409

61.222

-51.554

-95.001

-138.454

177.883

132.024

87.229

26.022

-8.975

-43.893

-78.798

-114.505

-153.055

172.112

133.007

104.224

82.267

50.240

6.926

37.568

-35.308

-77.276

-118.133

-158.923

158.580

115.249

72.656

10.165

38.470

-2.864

-5.903

-10.215

-27.632

-63.932

-90.189

-122.785

-163.441

144.595

83.275

-52.805

-103.865

-152.985

153.118

93.198

37.833

0.928

29.105

-35.629

-72.292

-109.537

-147.597

176.777

139.612

102.558

74.095

28.065

-14.187

-58.599

-104.365

-149.000

165.396

122.433

77.749

-33.067

-88.132

-138.271

173.388

122.816

65.257

30.364

-10.504

-47.217

-83.538

-119.330

-153.160

166.236

131.591

97.415

-1.277

29.934

49.307

-8.659

-59.633

-127.317

171.791

119.140

71.146

-13.003

-63.650

-112.183

-157.885

159.348

116.230

-1.915

-7.188

-40.229

-136.023

114.374

21.965

-7.034

-7.133

9.293

8.021

6.897

2.915

2.518

2.212

-7.517

61.706

-8.346

22.766

23.384

-35.249

-9.765

-21.448

Note:

1. Data obtained from in fixture de-embedded

to package edge.

Input Reference Plane

for s-para^fm^ore^s-t^pe^ar^ras^meters

Output Reference Plane

fo^fr^ors^s-^-pp^aa^rar^ma^em^tere^sters.

Input Reference Plane

Output Reference Plane

(View from package bottom)

Biasing and Operation

The AMMC-5618 does not require

a negative gate voltage to bias

any of the two stages. No ground

wires are needed because all

ground connections are made

with plated through-holes to the

backside of the package.

The AMMC-5618 is normally

biased with a single positive

drain supply connected to both

V_Dpins through bypass capaci-

tors as shown in Figure 19. The

recommended supply voltage is

5V. It is important to have 0.1 µF

bypass capacitor, and the capaci- Refer to the Absolute Maximum

Figure 21. Demonstration Board

(available upon request).

tor should be placed as close to

the component as possible.

Ratings table for allowed DC and

thermal conditions.

(Typ 5V)

0.1 µF

RFin

RFout

BASE

GND

Figure 19. Typical Application.

Feedback

Network

Feedback

Network

Matching

RF Input

Matching

RF Output

Figure 20. Simplified MMIC Schematic.

2 3

Recommended SMT Attachment

The AMMP Packaged Devices are

compatible with high volume

surface mount PCB assembly

processes.

AMMP

XXXX

YWWDNN

The PCB material and mounting

pattern, as defined in the data

sheet, optimizes RF performance

and is strongly recommended.

An electronic drawing of the land

pattern is available upon request

from Avago Sales & Application

Engineering.

Front View

Side View

Symbol

Min

Max

0.198 (5.03)

0.213 (5.4)

0.0685 (1.74)

0.088 (2.25)

0.114 [2.9]

0.011 [0.28]

0.018 [0.46]

0.014 [0.365]

Manual Assembly

2 1

1. Follow ESD precautions while

handling packages.

0.016 [0.40]

2. Handling should be along the

edges with tweezers.

0.126 [3.2]

0.059 [1.5]

0.100 [2.54]

0.012 [0.30]

3. Recommended attachment is

conductive solder paste.

Please see recommended

solder reflow profile. Conduc-

tive epoxy is not recom-

mended. Hand soldering is not

recommended.

0.029 [0.75]

6 7

0.100 [2.54]

0.016 [0.40]

0.028 [0.70]

0.093 [2.36]

Back View

Dimensional tolerance for back view: 0.002" [0.05 mm]

4. Apply solder paste using a

stencil printer or dot place-

ment. The volume of solder

paste will be dependent on

PCB and component layout

and should be controlled to

ensure consistent mechanical

and electrical performance.

5. Follow solder paste and

vendor’s recommendations

when developing a solder

reflow profile. A standard

profile will have a steady ramp

up from room temperature to

the pre-heat temperature to

avoid damage due to thermal

shock.

Notes:

1. * Indicates Pin 1

2. Dimensions are in inches [millimeters]

3. All Grounds must be soldered to PCB RF Ground

Figure 22. Outline Drawing.

.093 [2.36]

.010 [0.25]

.016 [0.40]

.011 [0.28]

.0095 [0.24]

.016 [0.40]

.126 [3.20]

.059 [1.50]

.020 [0.50]

.012 [0.3]

6. Packages have been qualified

to withstand a peak tempera-

ture of 260°C for 20 seconds.

Verify that the profile will not

expose device beyond these

limits.

.018 [0.46]

.0095 [0.24]

.018 [0.46]

.114 [2.90]

Figure 23. Suggested PCB Material and Land Pattern.

Solder Reflow Profile

lead to excessive solder paste

smear or bridging across the I/O

pads. Considering the fact that

solder paste thickness will

directly affect the quality of the

solder joint, a good choice is to

use a laser cut stencil composed

of 0.127 mm (5 mils) thick

stainless steel which is capable of

producing the required fine

stencil outline.

Stencil Design Guidelines

A properly designed solder

The most commonly used solder

reflow method is accomplished in

a belt furnace using convection

heat transfer. The suggested

reflow profile for automated

reflow processes is shown in

Figure 24. This profile is designed

to ensure reliable finished joints.

However, the profile indicated in

Figure 1 will vary among differ-

ent solder pastes from different

manufacturers and is shown here

for reference only.

screen or stencil is required to

ensure optimum amount of solder

paste is deposited onto the PCB

pads. The recommended stencil

layout is shown in Figure 25. The

stencil has a solder paste deposi-

tion opening approximately 70%

to 90% of the PCB pad. Reducing

stencil opening can potentially

generate more voids underneath.

On the other hand, stencil

The combined PCB and stencil

layout is shown in Figure 26.

openings larger than 100% will

300

Peak = 250 5°C

250

Melting point = 218°C

200

150

100

Ramp 1

Preheat

Ramp 2

Reflow

Cooling

250

100

150

200

300

Seconds

Figure 24. Suggested Lead-Free Reflow Profile for SnAgCu Solder Paste.

0.40

0.46

0.70

0.60

0.67

0.60

0.36

0.40

1.60

0.9550

0.27

3.20 1.80 0.40

0.36

0.95

0.36

0.30

0.27

0.36

1.80

0.36

Stencil

Opening

1.60

2.90

0.40

4x - R0.14

Figure 26. Combined PCB and Stencil Layouts (mm).

Figure 25. Stencil Outline Drawing (mm).

Part Number Ordering Information

Devices

Device Orientation (Top View)

Part Number

per Container

Container

antistatic bag

7” Reel

AMMP-5618-BLK

AMMP-5618-TR1

AMMP-5618-TR2

100

500

7” Reel

Carrier Tape and Pocket Dimensions

For product information and a complete list of distributors, please go to our web site:

www.avagotech.com

Avago, Avago Technologies, and the A logo are trademarks of Avago Technologies, Limited

in the United States and other countries.

Obsoletes 5989-3210EN

5989-3545EN April 24, 2006

AMMP-5618-BLK [AVAGO]

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