MGA-81563-TR1G Avago Technologies US Inc., MGA-81563-TR1G Datasheet - Page 7

MGA-81563-TR1G

Manufacturer Part Number

MGA-81563-TR1G

Description

IC AMP MMIC GAAS 3V SOT-363

Manufacturer

Avago Technologies US Inc.

Type

General Purpose Amplifierr

Datasheet

1.MGA-81563-TR1G.pdf (11 pages)

Specifications of MGA-81563-TR1G

P1db

14.8dBm

Noise Figure

2.7dB

Package / Case

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

Current - Supply

31mA ~ 51mA

Frequency

100MHz ~ 6GHz

Gain

12.3dB

Rf Type

ISM, PCS, PHS, SATCOM, WLL

Test Frequency

2GHz

Voltage - Supply

2.7V ~ 3.3V

Mounting Style

SMD/SMT

Technology

MMIC Amplifier

Number Of Channels

Operating Frequency

6000 MHz

Operating Supply Voltage

3 V

Supply Current

51 mA @ 3 V

Manufacturer's Type

MMIC Amplifier

Frequency (max)

6GHz

Operating Supply Voltage (typ)

Package Type

SOT-363

Mounting

Surface Mount

Pin Count

Noise Figure (typ)

3.5@6000MHzdB

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Lead Free Status / RoHS Status

Lead free / RoHS Compliant, Lead free / RoHS Compliant

Other names

516-1586-2

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Current page: 7 of 11
Download datasheet (158Kb)

The power supply is bypassed to ground with capacitor

C3 to keep RF off of the DC lines and to prevent gain dips

or peaks in the response of the amplifier.

An additional bypass capacitor, C4, may be added to the

bias line near the V

feedback through bias lines that could cause oscillation.

C4 will not normally be needed unless several stages are

cascaded using a common power supply.

When multiple bypass capacitors are used, consideration

should be given to potential resonances. It is important

to ensure that the capacitors when combined with addi-

tional parasitic L’s and C’s on the circuit board do not form

resonant circuits. The addition of a small value resistor in

the bias supply line between bypass capacitors will often

“de-Q” the bias circuit and eliminate the effect of a reso-

nance.

The value of the DC blocking and RF bypass capacitors

(C1 – C3) should be chosen to provide a small reactance

(typically < 5 ohms) at the lowest operating frequency.

The reactance of the RF choke (RFC) should be high (e.g.,

several hundred ohms) at the lowest frequency of opera-

tion.

The MGA-81563’s response at low frequencies is limited

to approximately 100 MHz by the size of capacitors inte-

grated on the MMIC chip.

The input of the MGA-81563 is partially matched inter-

nally to 50 Ω. Without external matching elements, the

input VSWR of the MGA-81563 is 3.0:1 at 300 MHz and de-

creases to 1.5:1 at 6 GHz. This will be adequate for many

applications. If a better input VSWR is required, the use of

a series inductor, L1 in the applications example, (or, alter-

natively a length of high impedance transmission line) is

all that is needed to improve the match. The table in Fig-

ure 16 shows suggested values for L1 for various wireless

frequency bands.

Figure 16. Values for L1.

These values for L1 take into account the short length of

50Ω transmission line between the inductor and the input

pin of the device.

Frequency

(GHz)

0.9

1.5

1.9

2.4

4.0

5.8

Inductor, L1

connection to eliminate unwanted

(nH)

6.8

3.9

2.7

0.5

For applications requiring minimum noise figure (NF

some improvement over a 50Ω match is possible by

matching the signal input to the optimum noise match

impedance, *

eters” table.

For most applications, as shown in the example circuit,

the output of the MGA-81563 is already sufficiently well

matched to 50Ω and no additional matching is needed.

The nominal device output VSWR is ≤ 2.2:1 from 300 MHz

through 6 GHz.

The completed application amplifier with all components

and SMA connectors is shown in Figure 17.

Figure 17. Complete Application Circuit.

Operation in Saturation for Higher Output Power

For applications such as pre-driver and driver stages in

transmitters, the MGA-81563 can be operated in satura-

tion to deliver up to 50 mW (17 dBm) of output power. The

power added efficiency increases to 45% at these power

levels.

There are several design considerations related to reliabil-

ity and performance that should be taken into account

when operating the amplifier in saturation.

First of all, it is important that the stage preceding the

MGA-81563 not overdrive the device. Referring to the “Ab-

solute Maximum Ratings” table, the maximum allowable

input power is +13 dBm. This should be regarded as the

input power level above which the device could be per-

manently damaged.

Driving the amplifier into saturation will also affect elec-

trical performance. Figure 18 presents the Output Power,

Third Order Intercept Point (Output IP

Efficiency (PAE) as a function of Input Power. This data

represents performance into a 50: load. Since the output

impedance of the device changes when driven into satu-

ration, it is possible to obtain even more output power

with a “power match. ” The optimum impedance match for

maximum output power is dependent on frequency and

actual output power level and can be arrived at empiri-

cally.

MGA-8-A

, as specified in the “Typical Noise Param-

RFC

, and Power Added

OUT

MGA-81563-TR1G Avago Technologies US Inc., MGA-81563-TR1G Datasheet - Page 7

MGA-81563-TR1G

Specifications of MGA-81563-TR1G

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