MGA-83563-TR2G Avago Technologies US Inc., MGA-83563-TR2G Datasheet - Page 11

MGA-83563-TR2G

Manufacturer Part Number

MGA-83563-TR2G

Description

IC AMP RFIC GAAS 3V 20DBM SOT363

Manufacturer

Avago Technologies US Inc.

Type

Power Amplifierr

Datasheet

1.MGA-83563-BLKG.pdf (22 pages)

Specifications of MGA-83563-TR2G

P1db

19.7dBm

Package / Case

SC-70-6, SC-88, SOT-363

Current - Supply

152mA ~ 200mA

Frequency

500MHz ~ 6GHz

Gain

23dB

Rf Type

Cellular, ISM, PCS

Test Frequency

2GHz

Voltage - Supply

2.7V ~ 3.6V

Operating Frequency

500 MHz to 6 GHz

Operating Supply Voltage

4 V

Supply Current

200 mA

Mounting Style

SMD/SMT

Number Of Channels

1 Channel

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Noise Figure

Lead Free Status / RoHS Status

Lead free / RoHS Compliant, Lead free / RoHS Compliant

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

Meier Automation Equipment Co., Limited

Part Number:

MGA-83563-TR2G

Manufacturer:

AVAGO/安华高

Quantity:

20 000

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The channel-to-case thermal resistance (T

the table of Absolute Maximum Ratings is 175°C/watt.

Note that the meaning of “case” for packages such

as the SOT-363 is defined as the interface between

the package pins and the mounting surface, i.e., at

the PCB pads. The temperature rise from the mount-

ing surface to the MMIC channel is then calculated as

0.264 watt

Operating life tests

lished that a MTTF of 10

temperatures ≤ 150°C. To achieve the 10

goal, the circuit to which the device is mounted (i.e., the

case temperature) should therefore not exceed 150° –

46°C, or 104°C.

Repeating the reliability calculation using the worst case

maximum device current of 200 mA, the DC power dis-

sipation is 552 mW. Summing the RF input and output

powers, P

case temperature rise of 69°C. The maximum case tem-

perature for the MTTF goal of 10

69°C, or 81°C.

For other MTTF goals, power dissipation, or operating

temperatures, Avago publishes reliability data sheets

based on operating life tests to enable designers to arrive

at a thermal design for their particular operating envi-

ronment. For a reliability data sheet covering the MGA-

83563, request Avago publication number 5988-9935EN,

titled "MGA-8XXXX Series Reliability Data Sheet." This

reliability data sheet covers the Avago family of PHEMT

GaAs RFICs.

Linear Amplifier Thermal Example

If the MGA-83563 is used in a linear application, the total

power dissipation is significantly higher than for the

saturated mode. The dissipated power is greater due

to higher device current (not as efficient as the satu-

rated mode) and also because no signal power is being

removed.

The maximum power dissipation for reliable linear op-

eration is calculated in the same manner as was done for

the saturated amplifier example. For linear circuits, the

RF input and output power are negligible and assumed

to be zero. All of the DC power is thus dissipated as heat.

For purposes of comparison to the saturated mode

example, this calculation will use the same MTTF goal of

again made for both nominal and worst case conditions.

From the data of Figure 10, the typical 3-volt, small signal

device current for the MGA-83563 at elevated tempera-

tures is 156 mA. The total device power dissipation, P

is then 3.0 volts

increment from the RFIC channel to case is 0.468 watt

hours and supply voltage of 3 volts. Calculations are

diss

175°C/watt, or 46°C.

is 397 mW which results in a channel-to-

156 mA, or 468 mW. The temperature

[1]

for the MGA-83563 have estab-

hours will be met for channel

hours is then 150°–

hour MTTF

ch-c

) from

diss

175°C/watt, or 82°C.

Commensurate with the MTTF goal of 10

circuit to which the device is mounted should therefore

not exceed 150°– 82°C, or 68°C.

For the worst case calculation, a guard band of 40% is

added to the typical current to arrive at a maximum DC

current of 218 mA. The P

to-case temperature rise is 115°C. The maximum case

temperature for worst case current condition is 35°C.

A case temperature of 68°C for nominal operation, or

35°C in the worst case, is unacceptably low for most ap-

plications. In order to use the MGA-83562 reliably for

linear applications, the P

ing the supply voltage.

The implication on RF output power performance for

amplifiers operating with a reduced V

this application note in the section subtitled “Use of the

MGA-83563 for Linear Applications”.

Design Example for 2.5 GHz

The design of a 2.5 GHz amplifier will be used to illus-

trate the approach for using the MGA-83563. The basic

design procedure outlined earlier will be used, in which

the interstage inductor (L2) is chosen first, followed by

the design of an initial small signal, output match. The

output match will then be empirically optimized for

large signal conditions after which an input match will

be added.

The printed circuit layout in Figure 21 is used as the start-

ing place. The circuit is designed for fabrication on 0.031-

inch thick FR-4 dielectric material.

Interstage Inductor L2

The first step is to choose a value for the interstage in-

ductor, L2. Referring to Figure 19, a value of 1.5 nH corre-

sponds to the design frequency of 2.5 GHz. A chip induc-

tor is chosen for L2 in this example. However, for small

inductance values such as this, the interstage inductor

could also be realized with a length of high impedance

transmission line.

The interstage inductor is bypassed with a 62 pF capaci-

tor, which has a reactance of 1 Ω at 2.5 GHz. Connecting

the supply voltage to the bypassed side of the inductor

completes the interstage part of the amplifier.

diss

is 655 mW and the channel-

must be lowered by reduc-

is covered later in

hours, the

MGA-83563-TR2G Avago Technologies US Inc., MGA-83563-TR2G Datasheet - Page 11

MGA-83563-TR2G

Specifications of MGA-83563-TR2G

Available stocks

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