WJ Company FP1189-PCB-900, FP1189-PCB-1900, FP1189 Datasheet

This document contains information on a new product.

Specifications and information are subject to change without notice

WJ Communications, Inc • Phone 1-800-WJ1-4401 • FAX: 408-577-6620 • e-mail: sales@wj.com

• Web site: www.wj.com

March 2002

The Communications Edge TM

Preliminary Product Information

FP1189

½ Watt HFET

Product Features

• DC – 4000 MHz

• +28 dBm P1dB

• +40 dBm Output IP3

• High Drain Efficiency

• 17 dB Gain @ 1900 MHz

• MTBF >100 Years

• SOT-89 SMT Package

Product Description

The FP1189 is a high performance ½-Watt HFET
(Heterostructure FET) in a low-cost SOT-89 surface­mount package. This device works optimally at a drai

n

b

ias of +8 V and 100 mA to achieve +40 dBm outpu

t

IP3 performance and an output power of +28 dBm a

t

1-dB compression.

The device conforms to WJ Communications’ long
history of producing high reliability and qualit

y

components. The FP1189 has an associated MTBF o

f

over 100 years at a mounting temperature of 85° C. All
devices are 100% RF & DC tested.

The product is targeted for use as driver amplifiers fo

r

wireless infrastructure where high performance and high
efficiency is required.

Functional Diagram

1 3

2

4

Function Pin No.

Input 1

Ground 2

Output/Bias 3

Ground 4

Specifications

DC Electrical Parameter Units Min Typ Max

Saturated Drain Current1, I

dss

mA 300

Transconductance, Gm mS

175

Pinch Off Voltage2, Vp V

-2.0

Parameters3 Units Min Typ Max

Frequency Range MHz DC 4000
Small Signal Gain, Gss dB

17

Output P1dB dBm

+28

Output IP34 dBm

+40

Thermal Resistance °C/W

70

1. I

dss

is measured with Vgs = 0 V, Vds = 3 V.

2. Pinch-off voltage is measured when Ids = 0.8 mA.

3. Test conditions unless otherwise noted: T = 25ºC, VDS = 8 V, IDQ = 100 mA, frequency = 1960 MHz
in an application circuit with ZL = Z

LOPT

, ZS = Z

SOPT

.

4. 3OIP measured with two tones at an output power of +15 dBm/tone separated by 1 MHz. The
suppression on the largest IM3 product is used to calculate the 3OIP using a 2:1 rule.



Absolute Maximum Ratings

Parameters Rating

Operating Case Temperature

-40 to +85 °C

Storage Temperature

-40 to +125 °C
Maximum DC Power 2 W
RF Input Power (continuous) +20 dBm

Operation of this device above any of there parameters may cause permanent damage

Typical Parameters

Parameter Units Typical

Frequency MHz 900 1960 2140
S21 dB

TBD

16.5 17

S11 dB

TBD

-23 -30

S22 dB

TBD

-6 -7

Output P1dB dBm

TBD

+28 +28

Output IP3 dBm

TBD

+40 +40

Noise Figure dB

TBD

3.8 3.9

Drain Voltage V

TBD

+8.0 +8.0

Drain Current mA

TBD

100 100

1. The drain current is the quiescent current at small signal output levels.
The current may increase as the output power is increased near its
compression point.

Ordering Information

Part No. Description

FP1189

½-Watt HFET

(Available in Tape & Reel)

FP1189-PCB-900 900 MHz Application Circuit
FP1189-PCB-1900 1900 MHz Application Circuit

This document contains information on a new product.

Specifications and information are subject to change without notice

WJ Communications, Inc • Phone 1-800-WJ1-4401 • FAX: 408-577-6620 • e-mail: sales@wj.com

• Web site: www.wj.com

March 2002

The Communications Edge TM

Preliminary Product Information

FP1189

½ Watt HFET

Application Circuit: 1960 MHz

R6

8.2 kΩ

Vdd = +8 V

Vgg = -4 V

UMT1N

6

1

5 2

4

3

Connected to Vdd

on App Circuit

Connected to Vgg

on App Circuit

R5

8.2 kΩ

R3

220 Ω

R4
2 Ω
1%

0603

Application Note

Special attention should be taken to properly bias up the HFETs. Power supply
sequencing is required to prevent the device from operating at 100% I

dss

for a prolonged

p

eriod of time and possibly causing damage to the device. It is recommended that for
the safest operation, the negative supply be “first on and last off.” With a negative gate
voltage present, the drain voltage can then be applied to the device. The gate voltage
can then be adjusted to have the device be used at the proper quiescent bias condition.

An optional temperature-compensation active-bias circuit is recommended for use with
the application circuit, which requires two standard voltage supplies +8V and -4V, an

d

is set for an optimal drain bias of +8V @ 100 mA. The circuit schematic, shown on the
right, uses dual PNP transistors to provide a constant drain current into the FET and also
eliminating the effects of pinchoff variation. Temperature compensation is achieved b

y

tracking the voltage variation with the temperature of the emitter-to-base junction of the
PNP transistors. Thus the transistor emitter voltage adjusts the voltage incident at the
gate of the FET so that the device draws a constant current, regardless of the
temperature. Two fixed voltage supplies are needed for operation. A Rohm dual
transistor, UMT1N, and a dual-chip resistor (8.2 kΩ) are recommended to minimize
board space and help decrease the current variability through R4 with the components
being matched to one another. The active-bias circuit can directly be attached to the
voltage supply ports in the circuit diagram as shown above (V

dd

and Vgg).

Vdd

+ 8 V @ 250 mA

FP1189

Sot-89

PIN 1

PIN 3

PIN 2,4

RF OUT

RF IN

L1

10 nH

C2

56 pF

Vgg

C3

2.2 pF

R1

20 Ω

C7

.018 µF

R2

5.1 Ω

L2

22 nH

C8

.018 µF

MLIN MLIN MLIN

MLIN

C5

0.6 pF

MLIN

C6

56 pF

C4

0.6 pF

C1

0.6 pF

Typical Specifications

Frequency 1960

S21 - Gain 16.5 dB
S11 - Input R.L. -23 dB
S22 - Output R.L. -6 dB
Output P1dB +28 dBm
Output IP3 +40 dBm
Noise Figure 3.8 dB
V

dd

+8.0 V

I

dd

1

100 mA

1 Idd is the quiescent current at small signal output levels. The current may increase

as the output power is increased near its compression point.

S-Pa rameters

-30

-20

-10

0

10

1930 1940 1950 1960 1970 1980 1990

Frequency (MHz)

S11, S22 (dB)

14

15

16

17

18

S21 (dB)

S21

S11

S22