IAM-91563-TR1G Avago Technologies US Inc., IAM-91563-TR1G Datasheet - Page 8

IAM-91563-TR1G

Manufacturer Part Number

IAM-91563-TR1G

Description

MIXER RFIC GAAS 3V SOT-363

Manufacturer

Avago Technologies US Inc.

Series

IAM-91563r

Datasheet

1.IAM-91563-TR2G.pdf (14 pages)

Specifications of IAM-91563-TR1G

Rf Type

Cellular, ISM, PCS, PHS, WLL

Frequency

800MHz ~ 6GHz

Number Of Mixers

Gain

7.7dB

Noise Figure

11dB

Secondary Attributes

Down Converter

Current - Supply

12mA

Voltage - Supply

Package / Case

6-TSSOP, SC-88, SOT-363

Frequency Range

0.8GHz To 6GHz

Supply Voltage Range

Rf Ic Case Style

SOT-363

No. Of Pins

Peak Reflow Compatible (260 C)

Yes

Frequency Max

6GHz

Noise Figure Typ

8.5dB

Termination Type

SMD

Rohs Compliant

Yes

Operating Supply Voltage

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Lead Free Status / RoHS Status

Lead free / RoHS Compliant, Lead free / RoHS Compliant

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

Bonase Electronics (HK) Co., Limited

Part Number:

IAM-91563-TR1G

Manufacturer:

AVAGO

Quantity:

10 000

Company:

Meier Automation Equipment Co., Limited

Part Number:

IAM-91563-TR1G

Manufacturer:

AVAGO/安华高

Quantity:

20 000

Current page: 8 of 14
Download datasheet (273Kb)

Application Guidelines

Several design considerations should be taken into ac-

count to ensure that maximum performance is obtained

from the IAM-9563 downconverter. The RF and IF ports

must be impedance matched at their respective frequen-

cies to the circuits to which they are connected. This is

typically 50 ohms when the mixer is used as a building

block component in a 50-ohm system. These ports have

been left untuned on the MMIC to allow the mixer to be

used over a wide range of RF and IF bands. The LO port is

already sufficiently well matched (less than dB of mis-

match loss) for most applications.

As with most mixers, appropriate filters must be placed at

the RF port and IF port such as in Figure . The filter in

front of the RF port eliminates interference from the im-

age frequency and the IF filter prevents RF and LO signal

leakage into the IF signal processing circuitry.

Figure 22. Image and IF Filters.

Additional design considerations relate to the use of high-

er bias current where greater linearity is required, bypass-

ing of the Source Bypass pin, bias injection, and DC block-

ing and bypassing.

Each of these design factors will be discussed in greater

detail in the following sections.

RF Port

A well matched RF port is especially important to maxi-

mize the conversion gain of the IAM-9563 mixer. Match-

ing is also necessary to realize the specified noise figure

and RF-to-LO isolation. The amount the conversion gain

can be increased by impedance matching is equal to the

mismatch loss at the RF port. The impedance of the RF

port is characterized by the measured reflection coeffi-

cients shown in Typical Reflection Coefficients Table. The

maximum “mismatch gain” that results from eliminating

the mismatch loss is expressed in dB as a function of the

reflection coefficient as:

For wireless bands in the 800 MHz to 6 GHz range, the

magnitude of the reflection coefficient of the RF port var-

ies from 0.9 to 0.80, which corresponds to a mismatch

gain of 7.6 to 4.4 dB.

The impedance of the RF port is capacitive, and for fre-

quencies from 800 MHz to .4 GHz, falls very near the R=

circle of a Smith chart. While these impedances could be

easily matched to 50 ohms with a simple series inductor,

RF, mm

HP Filter

= 10 log

1 – Γ

LP Filter

(1)

it is advantageous to use a -element matching network

of the series C, shunt L type as shown in Figure 3 in-

stead. There are two main reasons for this choice. The first

is to incorporate a high pass filter characteristic into the

matching circuit. Second, the series C, shunt L combina-

tion will match the entire range of RF port impedances to

50 Ω. Most wireless communication bands are sufficiently

narrow that a single (mid-band) frequency approach to

impedance matching is adequate.

Input

Figure 23. RF Input HPF Matching.

Impedance matching can be accomplished with lumped

element components, transmission lines, or a combina-

tion of both. The use of surface mount inductors and ca-

pacitors is convenient for lower frequencies to minimize

printed circuit board space. The use of high impedance

transmission lines works well for higher frequencies where

lumped element inductors may have excessive parasitics

and/or self-resonances.

If other types of matching networks are used, it should be

noted that while the RF input terminal of the IAM-9563

is at ground potential, it should not be used as a current

sink. If the input is connected directly to a preceding stage

that has a voltage present, a DC blocking capacitor should

be used.

IF port

The IAM-9563 can be used for downconvesion to inter-

mediate frequencies in the 50 to 700 MHz range. Similar to

the RF port, the reflection coefficient at the IF is fairly high

and Equation can be used to predict a mismatch gain

of up to . dB by impedance matching. A well matched

IF port will also provide the optimum output power and

LO-to-IF isolation. Reflection coefficients for the IF port are

shown in the Typical Reflection Coefficients Table.

The IF port impedance matching network should be of

the low pass filter type to reflect RF and LO power back

into the mixer while allowing the IF to pass through. The

shunt C, series L type of network in Figure 4 is a very

practical choice that will meet the low pass filter require-

ment while matching any IF impedances over the 50 - 700

MHz range to 50 ohms.

Figure 24. IF Output LPF Matching.

Output

IAM-91563-TR1G Avago Technologies US Inc., IAM-91563-TR1G Datasheet - Page 8

IAM-91563-TR1G

Specifications of IAM-91563-TR1G

Available stocks

Related parts for IAM-91563-TR1G