BGA2776,115 NXP Semiconductors, BGA2776,115 Datasheet - Page 4

BGA2776,115

Manufacturer Part Number

BGA2776,115

Description

IC MMIC AMPLIFIER SOT-363

Manufacturer

NXP Semiconductors

Type

General Purpose Amplifierr

Datasheet

1.BGA2776115.pdf (10 pages)

Specifications of BGA2776,115

Noise Figure

4.9dB

Package / Case

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

Current - Supply

24.4mA

Frequency

0Hz ~ 3GHz

Gain

23.2dB

P1db

7.2dBm

Rf Type

ISM

Test Frequency

1GHz

Voltage - Supply

5 V ~ 6 V

Bandwidth

2800 MHz

Mounting Style

SMD/SMT

Number Of Channels

Operating Supply Voltage

5 V

Supply Current

34 mA @ 5 V

Maximum Power Dissipation

200 mW

Maximum Operating Temperature

+ 150 C

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Lead Free Status / RoHS Status

Lead free / RoHS Compliant, Lead free / RoHS Compliant

Other names

568-3545-2
934056630115
BGA2776 T/R

Current page: 4 of 10
Download datasheet (259Kb)

NXP Semiconductors

APPLICATION INFORMATION

Figure 2 shows a typical application circuit for the

BGA2776 MMIC. The device is internally matched to 50 ,

and therefore does not need any external matching. The

value of the input and output DC blocking capacitors C2

and C3 should be not more than 100 pF for applications

above 100 MHz. However, when the device is operated

below 100 MHz, the capacitor value should be increased.

The nominal value of the RF choke L1 is 100 nH. At

frequencies below 100 MHz this value should be

increased to 220 nH. At frequencies above 1 GHz a much

lower value must be used (e.g. 10 nH) to improve return

losses. For optimal results, a good quality chip inductor

such as the TDK MLG 1608 (0603), or a wire-wound SMD

type should be chosen.

Both the RF choke L1 and the 22 nF supply decoupling

capacitor C1 should be located as closely as possible to

the MMIC.

Separate paths must be used for the ground planes of the

ground pins GND1 and GND2, and these paths must be as

short as possible. When using vias, use multiple vias per

pin in order to limit ground path inductance.

Figure 3 shows two cascaded MMICs. This configuration

doubles overall gain while preserving broadband

characteristics. Supply decoupling and grounding

conditions for each MMIC are the same as those for the

circuit of Fig.2.

The excellent wideband characteristics of the MMIC make

it and ideal building block in IF amplifier applications such

as LBNs (see Fig.4).

As a buffer amplifier between an LNA and a mixer in a

receiver circuit, the MMIC offers an easy matching, low

noise solution (see Fig.5).

handbook, halfpage

MMIC wideband ampliﬁer

RF input

V s

Fig.2 Typical application circuit.

RF in

GND1

V s

GND2

RF out

RF output

MGU436

Rev. 04 – 29 August 2007

In Fig.6 the MMIC is used as a driver to the power amplifier

as part of a transmitter circuit. Good linear performance

and matched input and output offer quick design solutions

in such applications.

handbook, halfpage

antenna

from modulation

input

from RF

or IF circuit

circuit

Fig.6 Power amplifier driver application.

DC-block

100 pF

Fig.5 RF amplifier application.

oscillator

Fig.3 Simple cascade circuit.

Fig.4 IF amplifier application.

LNA

oscillator

mixer

wideband

mixer

amplifier

oscillator

DC-block

100 pF

wideband

amplifier

mixer

wideband

amplifier

Product speciﬁcation

DC-block

BGA2776

100 pF

to IF circuit

or demodulator

to IF circuit

or demodulator

to power

amplifier

MGU438

MGU440

4 of 10

MGU437

MGU439

output

BGA2776,115 NXP Semiconductors, BGA2776,115 Datasheet - Page 4

BGA2776,115

Specifications of BGA2776,115

Related parts for BGA2776,115