IAM-91563 Datasheet, PDF(10/16 Page) Agilent(Hewlett-Packard) – 0.8-6 GHz 3V Downconverter

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IAM-91563 Datasheet, PDF (10/16 Pages) Agilent(Hewlett-Packard) – 0.8-6 GHz 3V Downconverter

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Application Example

The printed circuit layout in

Figure 28 is a general purpose

layout that will accommodate

components for using the

IAM-91563 for RF inputs from

800â£ MHz to 6 GHz. This layout is a

microstripline design (solid

groundplane on the backside of

the circuit board) with 50 â¦

interfaces for the RF input, IF

output, and LO input. The circuit

is fabricated on 0.031-inch thick

FR-4 dielectric material. Plated

through holes (vias) are used to

bring the ground to the top side of

the circuit where needed. Multiple

vias are used to reduce the

inductance of the paths to ground.

LO

H

RF

IF

+V

IAM-91

Figure 28. PCB Layout.

1.9 GHz Design Example

To illustrate a design approach for

using the IAM-91563, a PCS band

downconverter with an RF of

1.9â£ GHz and IF of 110 MHz is

presented. The PCB layout above

was used to assemble the mixer

and verify performance.

A schematic diagram of the

1.9â£ GHz circuit is shown in

Figureâ£ 29.

RF

Input C1

L1 = 0

MLIN C3

LO

Input

C7 C5

Vd

L3

C6

RFC

IF

L2

Output

C2

C4

Figure 29. Schematic of Example

Application Circuit.

At the RF input port, series

capacitor C1 and transmission line

MLIN form the input matching

network and high pass filter.

(Note: The PCB layout above has

provision for an inductor, L1, in

series with MLIN. Inductor L1 is

not used in this design.)

Referring to the table of Reflec-

tion Coefficients, the RF input

port ÎRF = 0.82 â â37Â° at 1.9 GHz.

This point is plotted as Point A on

the Smith chart in Figure 30. For

reasons previously discussed in

the âRF Portâ section above, a

series C - shunt L network (from

the 50 â¦ source to ÎRF) will be

used to match ÎRF to 50 â¦.

Addition of a 6.5 nH shunt induc-

tance moves the impedance

trajectory from Point A to Point B.

The match to 50 â¦ is completed

with a 0.6 pF series capacitance,

C1, that moves the match to

Pointâ£ C, the center of the Smith

chart.

1

0.5

2

B

0.2

0.2 0.5

CB

1

C

A

-0.2

RF C1

Input

L

2

A

-0.5

-2

-1

Figure 30. RF Input Impedance

Match.

For this example, the shunt

inductor was realized with the

transmission line, MLIN in Fig-

ureâ£ 29 ( ZO = 90 â¦, length =

0.35â£ in.). A high quality capacitor

should be selected for C1 to

minimize the effects of the

capacitorâs parasitic inductance

and resistance. Series capacitor

C1 also serves to block any DC

that may be present at the output

of the stage preceding the mixer.

At the IF output, the low pass

filter and impedance match is

formed by shunt capacitor C2 and

series inductor L2. Referring again

to the table of Reflection Coeffi-

cients, the IF output port ÎIF =

0.64 â -8Â° at 100 MHz, which is the

frequency point closest to the

desired IF of 110 MHz. ÎIF is

plotted as Point A in Figure 31.

1

0.5

2

AB C

0.2

C2

L2 IF

Output

0.2 0.5

1

C

-0.2

2

A

B

-0.5

-2

-1

Figure 31. IF Input Impedance Match.

Adding a shunt capacitance (C2)

of 11.3 pF brings the impedance to

Point B. The match to Point C at

the center of the chart is com-

pleted with a series inductance

(L2) of 150 nH.

Although not necessary for many

applications, the match at the LO

port can be improved by the

addition of series inductor L3 with

a value of approximately 8 nH.

Design information (ÎLO) for

matching the LO port is obtained

7-144

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