IAM-91563 Datasheet, PDF(7/16 Page) Agilent(Hewlett-Packard)

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IAM-91563 Datasheet, PDF (7/16 Pages) Agilent(Hewlett-Packard) – 0.8-6 GHz 3V Downconverter

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or maximum values. For the

IAM-91563, these parameters are:

Conversion Gain (Gtest), Noise

Figure (NFtest), and Device

Current (Id). Each of these

guaranteed parameters is 100%

tested.

Values for most of the parameters

in the table of Electrical Specifica-

tions that are described by typical

data are the mathematical mean

(Âµ), of the normal distribution

taken from the characterization

data. For parameters where

measurements or mathematical

averaging may not be practical,

such as the Typical Reflection

Coefficients table or performance

curves, the data represents a

nominal part taken from the

âcenterâ of the characterization

distribution. Typical values are

intended to be used as a basis for

electrical design.

To assist designers in optimizing

not only the immediate circuit

using the IAM-91563, but to also

optimize and evaluate trade-offs

that affect a complete wireless

system, the standard deviation

(Ï) is provided for many of the

Electrical Specifications param-

eters (at 25Â°) in addition to the

mean. The standard deviation is a

measure of the variability about

the mean. It will be recalled that a

normal distribution is completely

described by the mean and

standard deviation.

Standard statistics tables or

calculations provide the probabil-

ity of a parameter falling between

any two values, usually symmetri-

cally located about the mean.

Referring to Figure 12 for ex-

ample, the probability of a param-

eter being between Â± 1Ï is 68.3%;

between Â± 2Ï is 95.4%; and be-

tween Â± 3Ï is 99.7%.

68%

95%

99%

-3Ï -2Ï -1Ï Mean (Âµ) +1Ï +2Ï +3Ï

(typical)

Parameter Value

Figure 19. Normal Distribution.

Phase Reference Planes

The positions of the reference

planes used to specify Reflection

Coefficients for this device are

shown in Figure 20. As seen in the

illustration, the reference planes

are located at the point where the

package leads contact the test

circuit.

REFERENCE

PLANES

TEST CIRCUIT

Figure 20. Phase Reference Planes.

RF Layout

An RF layout similar to the one in

Figure 21 is suggested as a

starting point for microstripline

designs using the IAM-91563

mixer. This layout shows the

capacitor for the Source Bypass

pin and the optional resistor used

to increase bias current. Adequate

grounding is important to obtain

maximum performance and to

maintain stability. Both of the

ground pins of the MMIC should

be connected to the RF

groundplane on the backside of

the PCB by means of plated

through holes (vias) that are

placed near the package termi-

nals. As a minimum, one via

should be located next to each of

the ground pins to ensure good RF

grounding. It is a good practice to

use multiple vias to further

minimize ground path inductance.

Figure21. RFLayout.

It is recommended that the PCB

pads for the ground pins not be

connected together underneath

the body of the package. PCB

traces hidden under the package

cannot be adequately inspected

for SMT solder quality.

PCB Material

FR-4 or G-10 printed circuit board

materials are a good choice for

most low cost wireless applica-

tions. Typical board thickness is

0.020 to 0.031 inches. Thicknesses

greater than 0.031 inch began to

introduce excessive inductance in

the ground vias. The width of the

50 â¦ microstriplines on PC boards

in this thickness range is also very

convenient for mounting chip

components such as the series

inductor at the input or DC

blocking and bypass capacitors.

For applications using higher

frequencies such as the 5.8 GHz

ISM band, the additional cost of

PTFE/glass dielectric materials

may be warranted to minimize

transmission line loss at the

mixerâs RF input. An additional

consideration of using lower cost

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