MRF173 - Motorola / Freescale Semiconductor

MRF173MOTOROLA RF DEVICE DATA

The RF MOSFET Line

RFPower

FieldEffectTransistor

N–Channel Enhancement Mode MOSFET

Designed for broadband commercial and military applications up to 200MHz

frequency range. The high–power, high–gain and broadband performance of

this device make possible solid state transmitters for FM broadcast or TV

channel frequency bands.

•Guaranteed Performance at 150 MHz, 28 V:

Output Power = 80 W

Gain = 11 dB (13 dB Typ)

Efficiency = 55% Min. (60% Typ)

•Low Thermal Resistance

•Ruggedness Tested at Rated Output Power

•Nitride Passivated Die for Enhanced Reliability

•Low Noise Figure — 1.5 dB Typ at 2.0 A, 150 MHz

•Excellent Thermal Stability; Suited for Class A Operation

•S–Parameters Available for Download into Frequency Domain Simulators.

See http://motorola.com/sps/rf/designtds/

MAXIMUM RATINGS

Rating Symbol Value Unit

Drain–Source Voltage VDSS 65 Vdc

Drain–Gate Voltage VDGO 65 Vdc

Gate–Source Voltage VGS ±40 Vdc

Drain Current — Continuous ID9.0 Adc

Total Device Dissipation @ TC = 25°C

Derate above 25°CPD220

1.26 Watts

W/°C

Storage Temperature Range Tstg –65 to +150 °C

Operating Temperature Range TJ200 °C

THERMAL CHARACTERISTICS

Characteristic Symbol Max Unit

Thermal Resistance, Junction to Case RθJC 0.8 °C/W

ELECTRICAL CHARACTERISTICS (TC = 25°C unless otherwise noted)

Characteristic Symbol Min TypMax Unit

OFF CHARACTERISTICS

Drain–Source Breakdown Voltage (VDS = 0 V, VGS = 0 V)ID = 50 mA V(BR)DSS 65 — — V

Zero Gate Voltage Drain Current (VDS = 28 V, VGS = 0 V) IDSS — — 2.0 mA

Gate–Source Leakage Current (VGS = 40 V, VDS = 0 V) IGSS — — 1.0 µA

ON CHARACTERISTICS

Gate Threshold Voltage (VDS = 10 V, ID = 50 mA) VGS(th) 1.0 3.0 6.0 V

Drain–Source On–Voltage (VDS(on), VGS = 10 V, ID = 3.0 A) VDS(on) — — 1.4 V

Forward Transconductance (VDS = 10 V, ID = 2.0 A) gfs 1.8 2.2 — mhos

(continued)

NOTE — CAUTION — MOS devices are susceptible to damage from electrostatic charge. Reasonable precautions in handling and

packaging MOS devices should be observed.

Order this document

by MRF173/D

MOTOROLA

SEMICONDUCTOR TECHNICAL DATA

MRF173

80 W, 28 V, 175 MHz

N–CHANNEL

BROADBAND

RF POWER MOSFET

CASE 211–11, STYLE 2

 Motorola, Inc. 1998

REV 10

MRF173

2MOTOROLA RF DEVICE DATA

ELECTRICAL CHARACTERISTICS — continued (TC = 25°C unless otherwise noted)

Characteristic Symbol Min Typ Max Unit

DYNAMIC CHARACTERISTICS

Input Capacitance (VDS = 28 V, VGS = 0 V, f = 1.0 MHz) Ciss —110 — pF

Output Capacitance (VDS = 28 V, VGS = 0 V, f = 1.0 MHz) Coss — 105 — pF

Reverse Transfer Capacitance (VDS = 28 V, VGS = 0 V, f = 1.0 MHz) Crss — 10 — pF

FUNCTIONAL CHARACTERISTICS

Noise Figure (VDD = 28 V, f = 150 MHz, IDQ = 50 mA) NF — 1.5 — dB

Common Source Power Gain

(VDD = 28 V, Pout = 80 W, f = 150 MHz, IDQ = 50 mA) Gps 11 13 — dB

Drain Efficiency (VDD = 28 V, Pout = 80 W, f = 150 MHz, IDQ = 50 mA) η55 60 — %

Electrical Ruggedness

(VDD = 28 V, Pout = 80 W, f = 150 MHz, IDQ = 50 mA)

Load VSWR 30:1 at all phase angles

ψNo Degradation in Output Power

Series Equivalent Input Impedance

(VDD = 28 V, Pout = 80 W, f = 150 MHz, IDQ = 50 mA) Zin — 2.99–j4.5 — Ohms

Series Equivalent Output Impedance

(VDD = 28 V, Pout = 80 W, f = 150 MHz, IDQ = 50 mA) Zout — 2.68–j1.3 — Ohms

C1, C15 — 470 pF Unelco

C2, C3, C5 — 9–180 pF, Arco 463

C4, C6 — 15 pF, Unelco

C7 — 5–80 pF, Arco 462

C8, C10, C14, C16 — 0.1 µF

C9, C13 — 50 µF, 50 Vdc

C11, C12 — 680 pF, Feed Through

L1 — #16 A WG, 1–1/4 Turns, 0.3″ ID

L2 — #16 A WG Hairpin 1″ long

L3 — #14 A WG Hairpin 0.8″ long

L4 — #14 A WG Hairpin 1.1″ long

RFC1 — Ferroxcube VK200–19/4B

RFC2 — 18 T urns #18 AWG Enameled, 0.3″ ID

R1 — 10 kΩ, 10 Turns Bourns

R2 — 1.8 kΩ, 1/4 W

R3 — 10 kΩ, 1/2 W

Z1 — 1N5925A Motorola Zener

C11

C8 C9 Z1 C10 C13 C14

C12

C2 C3

C4 C5 C6 C7

C15

L1 L2

L3 L4

INPUT

OUTPUT

VDD = 28 V +

–

RFC1

RFC2

C16

D.U.T.

Figure 1. 150 MHz Test Circuit

–

Vdc

–

MRF173MOTOROLA RF DEVICE DATA

TYPICAL CHARACTERISTICS

8910

0234 7156

120

100

150 MHz

200 MHz

VDD = 28 V

IDQ = 50 mA

Pin, INPUT POWER (W ATTS)

P , OUTPUT POWER (WATTS)

out

Figure 2. Output Power versus Input Power Pin, INPUT POWER (WATTS)

P , OUTPUT POWER (WATTS)

out

Figure 3. Output Power versus Input Power

0 2.0 4.0 6.0 128.0 10

f = 100 MHz

150 MHz

200 MHz

26 28 30

10 14 16 18 2412 20 22

140

120

VDD, SUPPLY VOL TAGE (VOL TS)

P , OUTPUT POWER (WATTS)

out

Figure 4. Output Power versus Supply Voltage

100 3.0 W

2.0 W

1.0 W

Pin = 4.0 W

26 28 30

10 14 16 18 2412 20 22

140

120

VDD, SUPPLY VOL TAGE (VOL TS)

P , OUTPUT POWER (WATTS)

out

Figure 5. Output Power versus Supply Voltage

100 6.0 W

4.0 W

2.0 W

Pin = 8.0 W

26 28 30

10 14 16 18 2412 20 22

140

120

VDD, SUPPLY VOL TAGE (VOL TS)

P , OUTPUT POWER (WATTS)

out

Figure 6. Output Power versus Supply Voltage

100 10 W

6.0 W

4.0 W

Pin = 14 W

8.0

6.0

4.0

2.020 40 60 80 100 120 140 160 200 220

f, FREQUENCY (MHz) 180

G , POWER GAIN (dB)

Pout = 80 W

VDD = 28 V

IDQ = 50 mA

Figure 7. Power Gain versus Frequency

VDD = 13.5 V

IDQ = 50 mA

f = 100 MHz

IDQ = 50 mA

f = 100 MHz IDQ = 50 mA

f = 150 MHz

IDQ = 50 mA

f = 200 MHz

MRF173

4MOTOROLA RF DEVICE DATA

Figure 8. Output Power versus Gate Voltage Figure 9. Drain Current versus Gate Voltage

Figure 10. Gate–Source Voltage versus

Case Temperature Figure 1 1. Capacitance versus Drain Voltage

Figure 12. DC Safe Operating Area

–14 –12 –10 –8.0 –6.0 –4.0 –2.0 0 2.0 6.0

VGS, GATE–SOURCE VOLTAGE (VOLTS) 4.0

P , OUTPUT POWER (WATTS)

out

VGS, GATE–SOURCE VOLTAGE (VOLTS)

I , DRAIN CURRENT (AMPS)

VDS = 10 V

VGS(th) = 3.0 V

6.0

5.0

4.0

3.0

2.0

1.0

00 1.0 2.0 3.0 4.0 5.0 6.0

175

–25 0 25 75 100 125 15050

1.2

1.1

1.0

0.9

0.7

0.8

TC, CASE TEMPERATURE (C°)

V , GATE-SOURCE VOLTAGE (NORMALIZED)

VDS = 28 V

ID = 3.0 A

1.0 A

500 mA

50 mA

04812162024

420

360

300

240

180

120

VDS, DRAIN–SOURCE VOLT AGE (VOLTS)

VGS = 0 V

FREQ = 1 MHz

Coss

Crss

100

1.0 2.0 4.0 6.0 10 20 40 60

5.0

2.0

1.0

0.5

0.1

0.2

VDS, DRAIN–SOURCE VOLT AGE (VOLTS)

I , DRAIN CURRENT (AMPS)

TC = 25°C

f = 150 MHz

Pin = CONSTANT

VDS = 28 V

IDQ = 50 mA

VGS(th) = 3.0 V

Coss, CAPACIT ANCE (pF)

Crss, Ciss, CAPACITANCE (pF)

140

120

100

Ciss

MRF173MOTOROLA RF DEVICE DATA

Table 1. Common Source S–Parameters (VDS = 12.5 V, ID = 4 A)

S11 S21 S12 S22

MHz |S11|φ|S21|φ|S12|φ|S22|φ

ÁÁÁÁÁ

0.879

ÁÁÁÁ

–170

ÁÁÁÁÁ

8.09

ÁÁÁÁ

ÁÁÁÁÁ

0.014

ÁÁÁÁÁ

ÁÁÁÁ

0.839

ÁÁÁÁÁ

–174

ÁÁÁÁÁ

0.883

ÁÁÁÁ

–173

ÁÁÁÁÁ

6.19

ÁÁÁÁ

ÁÁÁÁÁ

0.016

ÁÁÁÁÁ

ÁÁÁÁ

0.839

ÁÁÁÁÁ

–179

ÁÁÁÁÁ

0.885

ÁÁÁÁ

–174

ÁÁÁÁÁ

4.94

ÁÁÁÁ

ÁÁÁÁÁ

0.016

ÁÁÁÁÁ

ÁÁÁÁ

0.853

ÁÁÁÁÁ

–178

ÁÁÁÁÁ

0.885

ÁÁÁÁ

–175

ÁÁÁÁÁ

4.21

ÁÁÁÁ

ÁÁÁÁÁ

0.017

ÁÁÁÁÁ

ÁÁÁÁ

0.845

ÁÁÁÁÁ

180

ÁÁÁÁÁ

0.888

ÁÁÁÁ

–176

ÁÁÁÁÁ

3.57

ÁÁÁÁ

ÁÁÁÁÁ

0.017

ÁÁÁÁÁ

ÁÁÁÁ

0.849

ÁÁÁÁÁ

179

ÁÁÁÁÁ

0.888

ÁÁÁÁ

–177

ÁÁÁÁÁ

3.06

ÁÁÁÁ

ÁÁÁÁÁ

0.017

ÁÁÁÁÁ

ÁÁÁÁ

0.852

ÁÁÁÁÁ

–179

ÁÁÁÁÁ

0.888

ÁÁÁÁ

–178

ÁÁÁÁÁ

2.71

ÁÁÁÁ

ÁÁÁÁÁ

0.018

ÁÁÁÁÁ

ÁÁÁÁ

0.842

ÁÁÁÁÁ

–179

ÁÁÁÁÁ

100

ÁÁÁÁÁ

0.890

ÁÁÁÁ

–178

ÁÁÁÁÁ

2.45

ÁÁÁÁ

ÁÁÁÁÁ

0.019

ÁÁÁÁÁ

ÁÁÁÁ

0.858

ÁÁÁÁÁ

180

ÁÁÁÁÁ

110

ÁÁÁÁÁ

0.888

ÁÁÁÁ

–179

ÁÁÁÁÁ

2.28

ÁÁÁÁ

ÁÁÁÁÁ

0.020

ÁÁÁÁÁ

ÁÁÁÁ

0.859

ÁÁÁÁÁ

179

ÁÁÁÁÁ

120

ÁÁÁÁÁ

0.892

ÁÁÁÁ

–179

ÁÁÁÁÁ

2.02

ÁÁÁÁ

ÁÁÁÁÁ

0.021

ÁÁÁÁÁ

ÁÁÁÁ

0.872

ÁÁÁÁÁ

–180

ÁÁÁÁÁ

130

ÁÁÁÁÁ

0.893

ÁÁÁÁ

–179

ÁÁÁÁÁ

1.84

ÁÁÁÁ

ÁÁÁÁÁ

0.022

ÁÁÁÁÁ

ÁÁÁÁ

0.870

ÁÁÁÁÁ

–179

ÁÁÁÁÁ

140

ÁÁÁÁÁ

0.894

ÁÁÁÁ

–180

ÁÁÁÁÁ

1.73

ÁÁÁÁ

ÁÁÁÁÁ

0.023

ÁÁÁÁÁ

ÁÁÁÁ

0.880

ÁÁÁÁÁ

–180

ÁÁÁÁÁ

150

ÁÁÁÁÁ

0.896

ÁÁÁÁ

–180

ÁÁÁÁÁ

1.58

ÁÁÁÁ

ÁÁÁÁÁ

0.024

ÁÁÁÁÁ

ÁÁÁÁ

0.887

ÁÁÁÁÁ

180

ÁÁÁÁÁ

160

ÁÁÁÁÁ

0.896

ÁÁÁÁ

180

ÁÁÁÁÁ

1.51

ÁÁÁÁ

ÁÁÁÁÁ

0.026

ÁÁÁÁÁ

ÁÁÁÁ

0.863

ÁÁÁÁÁ

180

ÁÁÁÁÁ

170

ÁÁÁÁÁ

0.898

ÁÁÁÁ

179

ÁÁÁÁÁ

1.38

ÁÁÁÁ

ÁÁÁÁÁ

0.026

ÁÁÁÁÁ

ÁÁÁÁ

0.850

ÁÁÁÁÁ

179

ÁÁÁÁÁ

180

ÁÁÁÁÁ

0.899

ÁÁÁÁ

179

ÁÁÁÁÁ

1.28

ÁÁÁÁ

ÁÁÁÁÁ

0.028

ÁÁÁÁÁ

ÁÁÁÁ

0.871

ÁÁÁÁÁ

179

ÁÁÁÁÁ

190

ÁÁÁÁÁ

0.899

ÁÁÁÁ

179

ÁÁÁÁÁ

1.25

ÁÁÁÁ

ÁÁÁÁÁ

0.030

ÁÁÁÁÁ

ÁÁÁÁ

0.890

ÁÁÁÁÁ

178

ÁÁÁÁÁ

200

ÁÁÁÁÁ

0.902

ÁÁÁÁ

179

ÁÁÁÁÁ

1.15

ÁÁÁÁ

ÁÁÁÁÁ

0.030

ÁÁÁÁÁ

ÁÁÁÁ

0.884

ÁÁÁÁÁ

178

ÁÁÁÁÁ

210

ÁÁÁÁÁ

0.902

ÁÁÁÁ

179

ÁÁÁÁÁ

1.12

ÁÁÁÁ

ÁÁÁÁÁ

0.032

ÁÁÁÁÁ

ÁÁÁÁ

0.899

ÁÁÁÁÁ

178

ÁÁÁÁÁ

220

ÁÁÁÁÁ

0.904

ÁÁÁÁ

178

ÁÁÁÁÁ

1.08

ÁÁÁÁ

ÁÁÁÁÁ

0.034

ÁÁÁÁÁ

ÁÁÁÁ

0.893

ÁÁÁÁÁ

178

ÁÁÁÁÁ

230

ÁÁÁÁÁ

0.907

ÁÁÁÁ

178

ÁÁÁÁÁ

0.97

ÁÁÁÁ

ÁÁÁÁÁ

0.037

ÁÁÁÁÁ

ÁÁÁÁ

0.941

ÁÁÁÁÁ

176

ÁÁÁÁÁ

240

ÁÁÁÁÁ

0.907

ÁÁÁÁ

178

ÁÁÁÁÁ

0.95

ÁÁÁÁ

ÁÁÁÁÁ

0.037

ÁÁÁÁÁ

ÁÁÁÁ

0.884

ÁÁÁÁÁ

176

ÁÁÁÁÁ

250

ÁÁÁÁÁ

0.909

ÁÁÁÁ

178

ÁÁÁÁÁ

0.90

ÁÁÁÁ

ÁÁÁÁÁ

0.039

ÁÁÁÁÁ

ÁÁÁÁ

0.896

ÁÁÁÁÁ

177

ÁÁÁÁÁ

260

ÁÁÁÁÁ

0.911

ÁÁÁÁ

177

ÁÁÁÁÁ

0.85

ÁÁÁÁ

ÁÁÁÁÁ

0.039

ÁÁÁÁÁ

ÁÁÁÁ

0.888

ÁÁÁÁÁ

176

ÁÁÁÁÁ

270

ÁÁÁÁÁ

0.909

ÁÁÁÁ

177

ÁÁÁÁÁ

0.83

ÁÁÁÁ

ÁÁÁÁÁ

0.042

ÁÁÁÁÁ

ÁÁÁÁ

0.895

ÁÁÁÁÁ

176

ÁÁÁÁÁ

280

ÁÁÁÁÁ

0.913

ÁÁÁÁ

177

ÁÁÁÁÁ

0.78

ÁÁÁÁ

ÁÁÁÁÁ

0.044

ÁÁÁÁÁ

ÁÁÁÁ

0.893

ÁÁÁÁÁ

175

ÁÁÁÁÁ

290

ÁÁÁÁÁ

0.914

ÁÁÁÁ

177

ÁÁÁÁÁ

0.74

ÁÁÁÁ

ÁÁÁÁÁ

0.044

ÁÁÁÁÁ

ÁÁÁÁ

0.882

ÁÁÁÁÁ

174

ÁÁÁÁÁ

300

ÁÁÁÁÁ

0.915

ÁÁÁÁ

176

ÁÁÁÁÁ

0.74

ÁÁÁÁ

ÁÁÁÁÁ

0.047

ÁÁÁÁÁ

ÁÁÁÁ

0.877

ÁÁÁÁÁ

175

ÁÁÁÁÁ

310

ÁÁÁÁÁ

0.917

ÁÁÁÁ

176

ÁÁÁÁÁ

0.70

ÁÁÁÁ

ÁÁÁÁÁ

0.048

ÁÁÁÁÁ

ÁÁÁÁ

0.909

ÁÁÁÁÁ

176

ÁÁÁÁÁ

320

ÁÁÁÁÁ

0.916

ÁÁÁÁ

176

ÁÁÁÁÁ

0.69

ÁÁÁÁ

ÁÁÁÁÁ

0.052

ÁÁÁÁÁ

ÁÁÁÁ

0.912

ÁÁÁÁÁ

175

ÁÁÁÁÁ

330

ÁÁÁÁÁ

0.917

ÁÁÁÁ

176

ÁÁÁÁÁ

0.65

ÁÁÁÁ

ÁÁÁÁÁ

0.055

ÁÁÁÁÁ

ÁÁÁÁ

0.885

ÁÁÁÁÁ

173

ÁÁÁÁÁ

340

ÁÁÁÁÁ

0.919

ÁÁÁÁ

176

ÁÁÁÁÁ

0.65

ÁÁÁÁ

ÁÁÁÁÁ

0.055

ÁÁÁÁÁ

ÁÁÁÁ

0.898

ÁÁÁÁÁ

173

ÁÁÁÁÁ

350

ÁÁÁÁÁ

0.919

ÁÁÁÁ

175

ÁÁÁÁÁ

0.62

ÁÁÁÁ

ÁÁÁÁÁ

0.057

ÁÁÁÁÁ

ÁÁÁÁ

0.887

ÁÁÁÁÁ

174

ÁÁÁÁÁ

360

ÁÁÁÁÁ

0.920

ÁÁÁÁ

175

ÁÁÁÁÁ

0.60

ÁÁÁÁ

ÁÁÁÁÁ

0.059

ÁÁÁÁÁ

ÁÁÁÁ

0.918

ÁÁÁÁÁ

172

ÁÁÁÁÁ

370

ÁÁÁÁÁ

0.921

ÁÁÁÁ

175

ÁÁÁÁÁ

0.57

ÁÁÁÁ

ÁÁÁÁÁ

0.061

ÁÁÁÁÁ

ÁÁÁÁ

0.929

ÁÁÁÁÁ

172

ÁÁÁÁÁ

380

ÁÁÁÁÁ

0.923

ÁÁÁÁ

175

ÁÁÁÁÁ

0.56

ÁÁÁÁ

ÁÁÁÁÁ

0.063

ÁÁÁÁÁ

ÁÁÁÁ

0.900

ÁÁÁÁÁ

172

ÁÁÁÁÁ

390

ÁÁÁÁÁ

0.925

ÁÁÁÁ

175

ÁÁÁÁÁ

0.54

ÁÁÁÁ

ÁÁÁÁÁ

0.065

ÁÁÁÁÁ

ÁÁÁÁ

0.907

ÁÁÁÁÁ

171

ÁÁÁÁÁ

400

ÁÁÁÁÁ

0.926

ÁÁÁÁ

174

ÁÁÁÁÁ

0.51

ÁÁÁÁ

ÁÁÁÁÁ

0.067

ÁÁÁÁÁ

ÁÁÁÁ

0.902

ÁÁÁÁÁ

173

ÁÁÁÁÁ

410

ÁÁÁÁÁ

0.927

ÁÁÁÁ

174

ÁÁÁÁÁ

0.51

ÁÁÁÁ

ÁÁÁÁÁ

0.070

ÁÁÁÁÁ

ÁÁÁÁ

0.942

ÁÁÁÁÁ

170

ÁÁÁÁÁ

420

ÁÁÁÁÁ

0.929

ÁÁÁÁ

174

ÁÁÁÁÁ

0.49

ÁÁÁÁ

ÁÁÁÁÁ

0.071

ÁÁÁÁÁ

ÁÁÁÁ

0.926

ÁÁÁÁÁ

169

ÁÁÁÁÁ

430

ÁÁÁÁÁ

0.929

ÁÁÁÁ

173

ÁÁÁÁÁ

0.46

ÁÁÁÁ

ÁÁÁÁÁ

0.072

ÁÁÁÁÁ

ÁÁÁÁ

0.901

ÁÁÁÁÁ

170

ÁÁÁÁÁ

440

ÁÁÁÁÁ

0.930

ÁÁÁÁ

173

ÁÁÁÁÁ

0.45

ÁÁÁÁ

ÁÁÁÁÁ

0.076

ÁÁÁÁÁ

ÁÁÁÁ

0.904

ÁÁÁÁÁ

170

MRF173

6MOTOROLA RF DEVICE DATA

Table 1. Common Source S–Parameters (VDS = 12.5 V, ID = 4 A) continued

S11 S21 S12 S22

MHz |S11|φ|S21|φ|S12|φ|S22|φ

ÁÁÁÁÁ

450

ÁÁÁÁÁ

0.932

ÁÁÁÁ

173

ÁÁÁÁÁ

0.45

ÁÁÁÁ

ÁÁÁÁÁ

0.079

ÁÁÁÁÁ

ÁÁÁÁ

0.924

ÁÁÁÁÁ

170

ÁÁÁÁÁ

460

ÁÁÁÁÁ

0.932

ÁÁÁÁ

172

ÁÁÁÁÁ

0.44

ÁÁÁÁ

ÁÁÁÁÁ

0.082

ÁÁÁÁÁ

ÁÁÁÁ

0.938

ÁÁÁÁÁ

167

ÁÁÁÁÁ

470

ÁÁÁÁÁ

0.933

ÁÁÁÁ

172

ÁÁÁÁÁ

0.42

ÁÁÁÁ

ÁÁÁÁÁ

0.081

ÁÁÁÁÁ

ÁÁÁÁ

0.908

ÁÁÁÁÁ

168

ÁÁÁÁÁ

480

ÁÁÁÁÁ

0.931

ÁÁÁÁ

172

ÁÁÁÁÁ

0.42

ÁÁÁÁ

ÁÁÁÁÁ

0.086

ÁÁÁÁÁ

ÁÁÁÁ

0.933

ÁÁÁÁÁ

168

ÁÁÁÁÁ

490

ÁÁÁÁÁ

0.931

ÁÁÁÁ

171

ÁÁÁÁÁ

0.41

ÁÁÁÁ

ÁÁÁÁÁ

0.089

ÁÁÁÁÁ

ÁÁÁÁ

0.926

ÁÁÁÁÁ

167

ÁÁÁÁÁ

500

ÁÁÁÁÁ

0.931

ÁÁÁÁ

171

ÁÁÁÁÁ

0.41

ÁÁÁÁ

ÁÁÁÁÁ

0.092

ÁÁÁÁÁ

ÁÁÁÁ

0.936

ÁÁÁÁÁ

167

Table 2. Common Source S–Parameters (VDS = 28 V, ID = 4 A)

S11 S21 S12 S22

MHz |S11|φ|S21|φ|S12|φ|S22|φ

ÁÁÁÁÁ

0.840

ÁÁÁÁ

–163

ÁÁÁÁÁ

11.48

ÁÁÁÁ

ÁÁÁÁÁ

0.016

ÁÁÁÁÁ

ÁÁÁÁ

0.718

ÁÁÁÁÁ

–169

ÁÁÁÁÁ

0.849

ÁÁÁÁ

–167

ÁÁÁÁÁ

8.80

ÁÁÁÁ

ÁÁÁÁÁ

0.017

ÁÁÁÁÁ

ÁÁÁÁ

0.713

ÁÁÁÁÁ

–174

ÁÁÁÁÁ

0.853

ÁÁÁÁ

–170

ÁÁÁÁÁ

6.99

ÁÁÁÁ

ÁÁÁÁÁ

0.017

ÁÁÁÁÁ

ÁÁÁÁ

0.748

ÁÁÁÁÁ

–174

ÁÁÁÁÁ

0.854

ÁÁÁÁ

–171

ÁÁÁÁÁ

5.92

ÁÁÁÁ

ÁÁÁÁÁ

0.017

ÁÁÁÁÁ

ÁÁÁÁ

0.746

ÁÁÁÁÁ

–175

ÁÁÁÁÁ

0.859

ÁÁÁÁ

–172

ÁÁÁÁÁ

5.00

ÁÁÁÁ

ÁÁÁÁÁ

0.018

ÁÁÁÁÁ

ÁÁÁÁ

0.746

ÁÁÁÁÁ

–175

ÁÁÁÁÁ

0.859

ÁÁÁÁ

–174

ÁÁÁÁÁ

4.29

ÁÁÁÁ

ÁÁÁÁÁ

0.018

ÁÁÁÁÁ

ÁÁÁÁ

0.741

ÁÁÁÁÁ

–174

ÁÁÁÁÁ

0.861

ÁÁÁÁ

–174

ÁÁÁÁÁ

3.77

ÁÁÁÁ

ÁÁÁÁÁ

0.019

ÁÁÁÁÁ

ÁÁÁÁ

0.735

ÁÁÁÁÁ

–174

ÁÁÁÁÁ

100

ÁÁÁÁÁ

0.866

ÁÁÁÁ

–175

ÁÁÁÁÁ

3.39

ÁÁÁÁ

ÁÁÁÁÁ

0.018

ÁÁÁÁÁ

ÁÁÁÁ

0.768

ÁÁÁÁÁ

–176

ÁÁÁÁÁ

110

ÁÁÁÁÁ

0.865

ÁÁÁÁ

–175

ÁÁÁÁÁ

3.12

ÁÁÁÁ

ÁÁÁÁÁ

0.018

ÁÁÁÁÁ

ÁÁÁÁ

0.782

ÁÁÁÁÁ

–177

ÁÁÁÁÁ

120

ÁÁÁÁÁ

0.871

ÁÁÁÁ

–176

ÁÁÁÁÁ

2.75

ÁÁÁÁ

ÁÁÁÁÁ

0.019

ÁÁÁÁÁ

ÁÁÁÁ

0.794

ÁÁÁÁÁ

–175

ÁÁÁÁÁ

130

ÁÁÁÁÁ

0.875

ÁÁÁÁ

–176

ÁÁÁÁÁ

2.49

ÁÁÁÁ

ÁÁÁÁÁ

0.021

ÁÁÁÁÁ

ÁÁÁÁ

0.783

ÁÁÁÁÁ

–172

ÁÁÁÁÁ

140

ÁÁÁÁÁ

0.877

ÁÁÁÁ

–177

ÁÁÁÁÁ

2.31

ÁÁÁÁ

ÁÁÁÁÁ

0.023

ÁÁÁÁÁ

ÁÁÁÁ

0.776

ÁÁÁÁÁ

–175

ÁÁÁÁÁ

150

ÁÁÁÁÁ

0.883

ÁÁÁÁ

–177

ÁÁÁÁÁ

2.10

ÁÁÁÁ

ÁÁÁÁÁ

0.023

ÁÁÁÁÁ

ÁÁÁÁ

0.806

ÁÁÁÁÁ

–176

ÁÁÁÁÁ

160

ÁÁÁÁÁ

0.884

ÁÁÁÁ

–177

ÁÁÁÁÁ

1.99

ÁÁÁÁ

ÁÁÁÁÁ

0.023

ÁÁÁÁÁ

ÁÁÁÁ

0.807

ÁÁÁÁÁ

–176

ÁÁÁÁÁ

170

ÁÁÁÁÁ

0.886

ÁÁÁÁ

–178

ÁÁÁÁÁ

1.82

ÁÁÁÁ

ÁÁÁÁÁ

0.023

ÁÁÁÁÁ

ÁÁÁÁ

0.806

ÁÁÁÁÁ

–176

ÁÁÁÁÁ

180

ÁÁÁÁÁ

0.890

ÁÁÁÁ

–178

ÁÁÁÁÁ

1.66

ÁÁÁÁ

ÁÁÁÁÁ

0.025

ÁÁÁÁÁ

ÁÁÁÁ

0.820

ÁÁÁÁÁ

–175

ÁÁÁÁÁ

190

ÁÁÁÁÁ

0.891

ÁÁÁÁ

–179

ÁÁÁÁÁ

1.62

ÁÁÁÁ

ÁÁÁÁÁ

0.027

ÁÁÁÁÁ

ÁÁÁÁ

0.815

ÁÁÁÁÁ

–176

ÁÁÁÁÁ

200

ÁÁÁÁÁ

0.896

ÁÁÁÁ

–179

ÁÁÁÁÁ

1.47

ÁÁÁÁ

ÁÁÁÁÁ

0.030

ÁÁÁÁÁ

ÁÁÁÁ

0.819

ÁÁÁÁÁ

–177

ÁÁÁÁÁ

210

ÁÁÁÁÁ

0.898

ÁÁÁÁ

–179

ÁÁÁÁÁ

1.41

ÁÁÁÁ

ÁÁÁÁÁ

0.031

ÁÁÁÁÁ

ÁÁÁÁ

0.842

ÁÁÁÁÁ

–178

ÁÁÁÁÁ

220

ÁÁÁÁÁ

0.901

ÁÁÁÁ

–179

ÁÁÁÁÁ

1.36

ÁÁÁÁ

ÁÁÁÁÁ

0.032

ÁÁÁÁÁ

ÁÁÁÁ

0.855

ÁÁÁÁÁ

–178

ÁÁÁÁÁ

230

ÁÁÁÁÁ

0.905

ÁÁÁÁ

–180

ÁÁÁÁÁ

1.22

ÁÁÁÁ

ÁÁÁÁÁ

0.033

ÁÁÁÁÁ

ÁÁÁÁ

0.906

ÁÁÁÁÁ

–178

ÁÁÁÁÁ

240

ÁÁÁÁÁ

0.906

ÁÁÁÁ

–180

ÁÁÁÁÁ

1.19

ÁÁÁÁ

ÁÁÁÁÁ

0.034

ÁÁÁÁÁ

ÁÁÁÁ

0.845

ÁÁÁÁÁ

–178

ÁÁÁÁÁ

250

ÁÁÁÁÁ

0.909

ÁÁÁÁ

180

ÁÁÁÁÁ

1.11

ÁÁÁÁ

ÁÁÁÁÁ

0.037

ÁÁÁÁÁ

ÁÁÁÁ

0.831

ÁÁÁÁÁ

–178

ÁÁÁÁÁ

260

ÁÁÁÁÁ

0.913

ÁÁÁÁ

180

ÁÁÁÁÁ

1.03

ÁÁÁÁ

ÁÁÁÁÁ

0.038

ÁÁÁÁÁ

ÁÁÁÁ

0.837

ÁÁÁÁÁ

–180

ÁÁÁÁÁ

270

ÁÁÁÁÁ

0.912

ÁÁÁÁ

179

ÁÁÁÁÁ

0.10

ÁÁÁÁ

ÁÁÁÁÁ

0.041

ÁÁÁÁÁ

ÁÁÁÁ

0.859

ÁÁÁÁÁ

179

ÁÁÁÁÁ

280

ÁÁÁÁÁ

0.916

ÁÁÁÁ

179

ÁÁÁÁÁ

0.93

ÁÁÁÁ

ÁÁÁÁÁ

0.042

ÁÁÁÁÁ

ÁÁÁÁ

0.876

ÁÁÁÁÁ

178

ÁÁÁÁÁ

290

ÁÁÁÁÁ

0.918

ÁÁÁÁ

179

ÁÁÁÁÁ

0.88

ÁÁÁÁ

ÁÁÁÁÁ

0.041

ÁÁÁÁÁ

ÁÁÁÁ

0.865

ÁÁÁÁÁ

179

ÁÁÁÁÁ

300

ÁÁÁÁÁ

0.919

ÁÁÁÁ

178

ÁÁÁÁÁ

0.87

ÁÁÁÁ

ÁÁÁÁÁ

0.044

ÁÁÁÁÁ

ÁÁÁÁ

0.837

ÁÁÁÁÁ

–180

ÁÁÁÁÁ

310

ÁÁÁÁÁ

0.922

ÁÁÁÁ

178

ÁÁÁÁÁ

0.83

ÁÁÁÁ

ÁÁÁÁÁ

0.046

ÁÁÁÁÁ

ÁÁÁÁ

0.863

ÁÁÁÁÁ

180

ÁÁÁÁÁ

320

ÁÁÁÁÁ

0.922

ÁÁÁÁ

178

ÁÁÁÁÁ

0.80

ÁÁÁÁ

ÁÁÁÁÁ

0.051

ÁÁÁÁÁ

ÁÁÁÁ

0.879

ÁÁÁÁÁ

177

ÁÁÁÁÁ

330

ÁÁÁÁÁ

0.924

ÁÁÁÁ

177

ÁÁÁÁÁ

0.75

ÁÁÁÁ

ÁÁÁÁÁ

0.054

ÁÁÁÁÁ

ÁÁÁÁ

0.878

ÁÁÁÁÁ

176

ÁÁÁÁÁ

340

ÁÁÁÁÁ

0.926

ÁÁÁÁ

177

ÁÁÁÁÁ

0.74

ÁÁÁÁ

ÁÁÁÁÁ

0.053

ÁÁÁÁÁ

ÁÁÁÁ

0.897

ÁÁÁÁÁ

177

ÁÁÁÁÁ

350

ÁÁÁÁÁ

0.926

ÁÁÁÁ

177

ÁÁÁÁÁ

0.71

ÁÁÁÁ

ÁÁÁÁÁ

0.054

ÁÁÁÁÁ

ÁÁÁÁ

0.879

ÁÁÁÁÁ

179

MRF173MOTOROLA RF DEVICE DATA

Table 2. Common Source S–Parameters (VDS = 28 V, ID = 4 A) continued

S11 S21 S12 S22

MHz |S11|φ|S21|φ|S12|φ|S22|φ

ÁÁÁÁÁ

360

ÁÁÁÁÁ

0.927

ÁÁÁÁ

177

ÁÁÁÁÁ

0.68

ÁÁÁÁ

ÁÁÁÁÁ

0.056

ÁÁÁÁÁ

ÁÁÁÁ

0.888

ÁÁÁÁÁ

177

ÁÁÁÁÁ

370

ÁÁÁÁÁ

0.929

ÁÁÁÁ

177

ÁÁÁÁÁ

0.64

ÁÁÁÁ

ÁÁÁÁÁ

0.058

ÁÁÁÁÁ

ÁÁÁÁ

0.893

ÁÁÁÁÁ

175

ÁÁÁÁÁ

380

ÁÁÁÁÁ

0.931

ÁÁÁÁ

176

ÁÁÁÁÁ

0.62

ÁÁÁÁ

ÁÁÁÁÁ

0.062

ÁÁÁÁÁ

ÁÁÁÁ

0.885

ÁÁÁÁÁ

174

ÁÁÁÁÁ

390

ÁÁÁÁÁ

0.934

ÁÁÁÁ

176

ÁÁÁÁÁ

0.60

ÁÁÁÁ

ÁÁÁÁÁ

0.064

ÁÁÁÁÁ

ÁÁÁÁ

0.903

ÁÁÁÁÁ

174

ÁÁÁÁÁ

400

ÁÁÁÁÁ

0.934

ÁÁÁÁ

176

ÁÁÁÁÁ

0.57

ÁÁÁÁ

ÁÁÁÁÁ

0.065

ÁÁÁÁÁ

ÁÁÁÁ

0.898

ÁÁÁÁÁ

177

ÁÁÁÁÁ

410

ÁÁÁÁÁ

0.936

ÁÁÁÁ

175

ÁÁÁÁÁ

0.56

ÁÁÁÁ

ÁÁÁÁÁ

0.068

ÁÁÁÁÁ

ÁÁÁÁ

0.931

ÁÁÁÁÁ

175

ÁÁÁÁÁ

420

ÁÁÁÁÁ

0.938

ÁÁÁÁ

175

ÁÁÁÁÁ

0.53

ÁÁÁÁ

ÁÁÁÁÁ

0.070

ÁÁÁÁÁ

ÁÁÁÁ

0.906

ÁÁÁÁÁ

173

ÁÁÁÁÁ

430

ÁÁÁÁÁ

0.938

ÁÁÁÁ

174

ÁÁÁÁÁ

0.51

ÁÁÁÁ

ÁÁÁÁÁ

0.072

ÁÁÁÁÁ

ÁÁÁÁ

0.885

ÁÁÁÁÁ

173

ÁÁÁÁÁ

440

ÁÁÁÁÁ

0.939

ÁÁÁÁ

174

ÁÁÁÁÁ

0.49

ÁÁÁÁ

ÁÁÁÁÁ

0.075

ÁÁÁÁÁ

ÁÁÁÁ

0.895

ÁÁÁÁÁ

172

ÁÁÁÁÁ

450

ÁÁÁÁÁ

0.941

ÁÁÁÁ

174

ÁÁÁÁÁ

0.48

ÁÁÁÁ

ÁÁÁÁÁ

0.080

ÁÁÁÁÁ

ÁÁÁÁ

0.923

ÁÁÁÁÁ

172

ÁÁÁÁÁ

460

ÁÁÁÁÁ

0.941

ÁÁÁÁ

173

ÁÁÁÁÁ

0.47

ÁÁÁÁ

ÁÁÁÁÁ

0.082

ÁÁÁÁÁ

ÁÁÁÁ

0.940

ÁÁÁÁÁ

171

ÁÁÁÁÁ

470

ÁÁÁÁÁ

0.942

ÁÁÁÁ

173

ÁÁÁÁÁ

0.45

ÁÁÁÁ

ÁÁÁÁÁ

0.080

ÁÁÁÁÁ

ÁÁÁÁ

0.904

ÁÁÁÁÁ

172

ÁÁÁÁÁ

480

ÁÁÁÁÁ

0.940

ÁÁÁÁ

173

ÁÁÁÁÁ

0.44

ÁÁÁÁ

ÁÁÁÁÁ

0.083

ÁÁÁÁÁ

ÁÁÁÁ

0.910

ÁÁÁÁÁ

171

ÁÁÁÁÁ

490

ÁÁÁÁÁ

0.940

ÁÁÁÁ

172

ÁÁÁÁÁ

0.43

ÁÁÁÁ

ÁÁÁÁÁ

0.088

ÁÁÁÁÁ

ÁÁÁÁ

0.906

ÁÁÁÁÁ

169

ÁÁÁÁÁ

500

ÁÁÁÁÁ

0.940

ÁÁÁÁ

172

ÁÁÁÁÁ

0.42

ÁÁÁÁ

ÁÁÁÁÁ

0.092

ÁÁÁÁÁ

ÁÁÁÁ

0.927

ÁÁÁÁÁ

168

DESIGN CONSIDERATIONS

The MRF173 is a RF MOSFET power N–channel en-

hancement mode field–effect transistor (FET) designed for

VHF power amplifier applications. Motorola’s RF MOSFETs

feature a vertical structure with a planar design, thus avoid-

ing the processing difficulties associated with V–groove pow-

er FETs.

Motorola Application Note AN211A, FETs in Theory and

Practice, is suggested reading for those not familiar with the

construction and characteristics of FETs.

The major advantages of RF power FETs include high

gain, low noise, simple bias systems, relative immunity from

thermal runaway, and the ability to withstand severely mis-

matched loads without suffering damage. Power output can

be varied over a wide range with a low power dc control sig-

nal, thus facilitating manual gain control, ALC and modula-

tion.

DC BIAS

The MRF173 is an enhancement mode FET and, there-

fore, does not conduct when drain voltage is applied.

Drain current flows when a positive voltage is applied to

the gate. See Figure 9 for a typical plot of drain current

versus gate voltage. RF power FETs require forward bias

for optimum performance. The value of quiescent drain

current (IDQ) is not critical for many applications. The

MRF173 was characterized at IDQ = 50 mA, which is the

suggested minimum value of IDQ. For special applications

such as linear amplification, IDQ may have to be selected to

optimize the critical parameters.

The gate is a dc open circuit and draws no current. There-

fore, the gate bias circuit may generally be just a simple re-

sistive divider network. Some special applications may

require a more elaborate bias system.

GAIN CONTROL

Power output of the MRF173 may be controlled from its

rated value down to zero (negative gain) by varying the dc

gate voltage. This feature facilitates the design of manual gain

control, AGC/ALC and modulation systems. (see Figure 8.)

AMPLIFIER DESIGN

Impedance matching networks similar to those used with

bipolar VHF transistors are suitable for MRF173. See Moto-

rola Application Note AN721, Impedance Matching Networks

Applied to RF Power Transistors. The higher input imped-

ance of RF MOSFETs helps ease the task of broadband net-

work design. Both small–signal scattering parameters and

large–signal impedances are provided. While the s–parame-

ters will not produce an exact design solution for high power

operation, they do yield a good first approximation. This is an

additional advantage of RF MOS power FETs.

MRF173

8MOTOROLA RF DEVICE DATA

PACKAGE DIMENSIONS

CASE 211–11

ISSUE N

NOTES:

1. DIMENSIONING AND TOLERANCING PER ANSI

Y14.5M, 1982.

2. CONTROLLING DIMENSION: INCH.

ESEATING

PLANE

DIM MIN MAX MIN MAX

MILLIMETERSINCHES

A0.960 0.990 24.39 25.14

B0.465 0.510 11.82 12.95

C0.229 0.275 5.82 6.98

D0.216 0.235 5.49 5.96

E0.084 0.110 2.14 2.79

H0.144 0.178 3.66 4.52

J0.003 0.007 0.08 0.17

K0.435 ––– 11.05 –––

M45 NOM 45 NOM

Q0.115 0.130 2.93 3.30

R0.246 0.255 6.25 6.47

U0.720 0.730 18.29 18.54

STYLE 2:

PIN 1. SOURCE

2. GATE

3. SOURCE

4. DRAIN

Motorola reserves the right to make changes without further notice to any products herein. Motorola makes no warranty, representation or guarantee regarding

the suitability of its products for any particular purpose, nor does Motorola assume any liability arising out of the application or use of any product or circuit, and

specifically disclaims any and all liability, including without limitation consequential or incidental damages. “Typical” parameters which may be provided in Motorola

data sheets and/or specifications can and do vary in different applications and actual performance may vary over time. All operating parameters, including “Typicals”

must be validated for each customer application by customer’s technical experts. Motorola does not convey any license under its patent rights nor the rights of

others. Motorola products are not designed, intended, or authorized for use as components in systems intended for surgical implant into the body, or other

applications intended to support or sustain life, or for any other application in which the failure of the Motorola product could create a situation where personal injury

or death may occur. Should Buyer purchase or use Motorola products for any such unintended or unauthorized application, Buyer shall indemnify and hold Motorola

and its officers, employees, subsidiaries, affiliates, and distributors harmless against all claims, costs, damages, and expenses, and reasonable attorney fees

arising out of, directly or indirectly, any claim of personal injury or death associated with such unintended or unauthorized use, even if such claim alleges that

Motorola was negligent regarding the design or manufacture of the part. Motorola and are registered trademarks of Motorola, Inc. Motorola, Inc. is an Equal

Opportunity/Af firmative Action Employer .

Mfax is a trademark of Motorola, Inc.

How to reach us:

USA/EUROPE/Locations Not Listed: Motorola Literature Distribution; JAPAN: Nippon Motorola Ltd.; SPD, Strategic Planning Office, 141,

P.O. Box 5405, Denver, Colorado 80217. 1–303–675–2140 or 1–800–441–2447 4–32–1 Nishi–Gotanda, Shinagawa–ku, Tokyo, Japan. 81–3–5487–8488

Customer Focus Center: 1–800–521–6274

Mfax: RMFAX0@email.sps.mot.com – TOUCHT ONE 1–602–244–6609 ASIA/PACIFIC: Motorola Semiconductors H.K. Ltd.; 8B Tai Ping Industrial Park,

Motor ola Fa x Back System – US & Canada ONLY 1–800–774–1848 51 Ting Kok Road, Tai Po, N.T., Hong Kong. 852–26629298

– http://sps.motorola.com/mfax/

HOME PAGE: http://motorola.com/sps/

MRF173/D

◊