MGA-82563-TR1 Avago Technologies US Inc., MGA-82563-TR1 Datasheet - Page 9

MGA-82563-TR1

Manufacturer Part Number

MGA-82563-TR1

Description

RF Amplifiers/MMIC Amplifier

Manufacturer

Avago Technologies US Inc.

Datasheet

1.MGA-82563-TR1G.pdf (11 pages)

Specifications of MGA-82563-TR1

No. Of Amplifiers

No. Of Pins

Peak Reflow Compatible (260 C)

Frequency Max

6GHz

Reel Quantity

3000

Noise Figure Typ

2.2dB

Gain

13.2dB

Supply Voltage Max

Leaded Process Compatible

Current - Supply

101mA

Frequency

100MHz ~ 6GHz

Noise Figure

2.2dB ~ 2.9dB

P1db

17.3dBm

Package / Case

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

Rf Type

ISM, PHS, PCS, WLL, SATCOM

Test Frequency

2GHz

Voltage - Supply

2.7V ~ 3.3V

Lead Free Status / RoHS Status

Contains lead / RoHS non-compliant

Other names

516-1511-2

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Figure 19. Gain, Noise Figure, and Output Power vs. Supply Voltage.

There are several means of biasing the MGA-82563 at

3 volts in systems that use higher power supply voltages.

The simplest method, shown in Figure 20a, is to use a

series resistor to drop the device voltage to 3 volts. For

example, a 24 Ω resistor will drop a 5-volt supply to 3

volts at the nominal current of 84 mA. Some variation in

performance could be expected for this method due to

variations in current within the specified 63 to 101 mA

min/max range.

Figure 20. Biasing From Higher Supply Voltages.

A second method illustrated in Figure 20b, is to use for-

ward-biased diodes in series with the power supply. For

example, three silicon diodes connected in series will

drop a 5-volt supply to approximately 3 volts.

The use of the series diode approach has the advantage

(a)

+5 V

24 Ω

SUPPLY VOLTAGE (V)

Silicon

Diodes

(b)

+5 V

Power

Gain

Zener

Diode

(c)

+5 V

of less dependency on current variation in the amplifiers

since the forward voltage drop of a diode is somewhat

current independent.

Reverse breakdown diodes (e.g., Zener diodes) could

also be used as in Figure 20c. However, care should be

taken to ensure that the noise generated by diodes in

either Zener or reverse breakdown is adequately filtered

(e.g., bypassed to ground) such that the diode’s noise is

not added to the amplifier’s signal.

Note that the voltage-dropping component in each of

these three methods must be able to safely dissipate up

to 200 mW.

SOT-363 PCB Footprint

A recommended PCB pad layout for the miniature SOT-

363 (SC-70) package used by the MGA-82563 is shown in

Figure 21 (dimensions are in inches). This layout provides

ample allowance for package placement by automated

assembly equipment without adding parasitics that

could impair the high frequency RF performance of the

MGA-82563. The layout is shown with a nominal SOT-363

package footprint superimposed on the PCB pads.

0.039

Figure 21. Recommended PCB Pad Layout for Avago’s SC70 6L/SOT-363 Products.

0.026

Dimensions in inches.

0.018

0.079

MGA-82563-TR1 Avago Technologies US Inc., MGA-82563-TR1 Datasheet - Page 9

MGA-82563-TR1

Specifications of MGA-82563-TR1

Available stocks

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