SA5219 Datasheet, PDF(4/18 Page) NXP Semiconductors – Wideband variable gain amplifier

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SA5219 Datasheet, PDF (4/18 Pages) NXP Semiconductors – Wideband variable gain amplifier

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Philips Semiconductors

Wideband variable gain amplifier

Product specification

SA5219

AC ELECTRICAL CHARACTERISTICS

TA = 25oC, VCC1 = VCC2 = +5.0V, VAGC = 1.0V, unless otherwise specified.

SYMBOL

PARAMETER

LIMITS

TEST CONDITIONS

UNIT

MIN

TYP

MAX

-3dB bandwidth

700

MHz

Gain flatness

DC - 500MHz

+0.4

VIMAX

Maximum input voltage swing (single-ended) for

linear operation1

200

mVP-P

VOMAX

VIN-EQ

Maximum output voltage swing (single-ended)

for linear operation1

Noise figure (unmatched configuration)

Equivalent input noise voltage spectral density

RL = 50â¦

RL = 1kâ¦

RS = 50â¦, f = 50MHz

f = 100MHz

400

mVP-P

1.9

VP-P

9.3

2.5

nV/âHz

S12

Reverse isolation

f = 100MHz

-60

âG/âVCC

âG/âT

Gain supply sensitivity (single-ended)

Gain temperature sensitivity

RL = 50â¦

0.3

0.013

dB/V

dB/Â°C

CIN

BWAGC

PO-1dB

PI-1dB

Input capacitance (single-ended)

-3dB bandwidth of gain control function

1dB gain compression point at output

1dB gain compression point at input

f = 100MHz

f = 100MHz, VAGC

=0.1V

MHz

-3

dBm

-10

dBm

IP3OUT

Third-order intercept point at output

f = 100MHz, VAGC

>0.5V

+13

dBm

IP3IN

Third-order intercept point at input

f = 100MHz, VAGC

<0.5V

dBm

âGAB

Gain match output A to output B

f = 100MHz, VAGC = 1V

0.1

NOTE:

1. With RL > 1kâ¦, overload occurs at input for single-ended gain < 13dB and at output for single-ended gain > 13dB. With RL = 50â¦, overload

occurs at input for single-ended gain < 6dB and at output for single-ended gain > 6dB.

SA5219 APPLICATIONS

The SA5219 is a wideband variable gain amplifier (VGA) circuit

which finds many applications in the RF, IF and video signal

processing areas. This application note describes the operation of

the circuit and several applications of the VGA. The simplified

equivalent schematic of the VGA is shown in Figure 2. Transistors

Q1-Q6 form the wideband Gilbert multiplier input stage which is

biased by current source I1. The top differential pairs are biased

from a buffered and level-shifted signal derived from the VAGC input

and the RF input appears at the lower differential pair. The circuit

topology and layout offer low input noise and wide bandwidth. The

second stage is a differential transimpedance stage with current

feedback which maintains the wide bandwidth of the input stage.

The output stage is a pair of emitter followers with 50â¦ output

impedance. There is also an on-chip bandgap reference with

buffered output at 1.3V, which can be used to derive the gain control

voltage.

Both the inputs and outputs should be capacitor coupled or DC

isolated from the signal sources and loads. Furthermore, the two

inputs should be DC isolated from each other and the two outputs

should likewise be DC isolated from each other. The SA5219 was

designed to provide optimum performance from a 5V power source.

However, there is some range around this value (4.5 - 7V) that can

be used.

The input impedance is about 1kâ¦. The main advantage to a

differential input configuration is to provide the balun function.

Otherwise, there is an advantage to common mode rejection, a

specification that is not normally important to RF designs. The

source impedance can be chosen for two different performance

characteristics: Gain, or noise performance. Gain optimization will

be realized if the input impedance is matched to about 1kâ¦. A 4:1

balun will provide such a broadband match from a 50â¦ source.

Noise performance will be optimized if the input impedance is

matched to about 200â¦. A 2:1 balun will provide such a broadband

match from a 50â¦ source. The minimum noise figure can then be

expected to be about 7dB. Maximum gain will be about 23dB for a

single-ended output. If the differential output is used and properly

matched, nearly 30dB can be realized. With gain optimization, the

noise figure will degrade to about 8dB. With no matching unit at the

input, a 9dB noise figure can be expected from a 50â¦ source. If the

source is terminated, the noise figure will increase to about 15dB.

All these noise figures will occur at maximum gain.

The SA5219 has an excellent noise figure vs gain relationship. With

any VGA circuit, the noise performance will degrade with decreasing

gain. The 5219 has about a 1.2dB noise figure degradation for

each 2dB gain reduction. With the input matched for optimum gain,

the 8dB noise figure at 23dB gain will degrade to about a 20dB

noise figure at 0dB gain.

The SA5219 also displays excellent linearity between voltage gain

and control voltage. Indeed, the relationship is of sufficient linearity

that high fidelity AM modulation is possible using the SA5219. A

1997 Nov 07

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