100W+.

Expanding Bandwidth

by Minimizing Resistor

Capacitance

To support high power requirements

at higher frequencies, a design goal

was set to extend the frequency range

of ZACS242-100W+ while maintaining

low insertion loss and comparable

performance overall. One way to

achieve this would be to reduce the

capacitance from the resistors. We

know that capacitance is a function

of the overlapping area of conductive

surfaces on the bottom of the resistor

and on the PCB. Note that the

resistors in Figure 1 sit face-down,

with the entire conductive surface flat

against the PCB. While we cannot

reduce the size of the resistor or the

area of the conductive surface itself,

we can reorient the resistor to the

PCB to minimize the overlapping area

of the parallel plates.

The splitter/combiner was thus rebuilt

with the resistors oriented 90° to the

PCB as shown in Figure 2. Reorienting

the resistors this way effectively

reduces the resistor capacitance

by more than 10 fold, which in turn

significantly reduces the overall

insertion loss at higher frequencies.

Test data for insertion loss swept over

frequency verifies the improvement

between ZACS242-100W+ in which

the resistors are positioned flat

against the PCB, and ZACS363-

100W+ in which the resistors are

positioned vertically, orthogonal to the

PCB. Figure 3 shows a comparison of

insertion loss versus frequency for the

old and new designs.

While insertion loss for ZACS242-

100W+ degrades above 2400 MHz,

the modified design in ZACS362-

100W+ achieves low insertion loss

up to 3600 MHz, amounting to a 50%

expansion in operating bandwidth.

Both models provide 100W power

handling as splitters, although

whereas ZACS242-100W+ handles up

to 40W RF power as a combiner, new

model ZACS362-100W+ can handle

up to 5W as a combiner. In all other

respects, ZACS362-100W+ provides

comparable performance to that of

ZACS242-100W+ up to 3600 MHz

with high isolation (22 dB typ.), and

low phase and amplitude unbalance

(1° and 0.15 dB, respectively).

Conclusion

The design technique presented in

this article takes advantage of a basic

principle of parallel plate capacitance

to minimize the capacitance of

resistors in a splitter/combiner circuit,

Figure 1: Board layout of ZACS242-100W+ with 4 100W chip resistors.

Figure 2: 100W Chip resistor oriented with conductive surface perpendicular to the PCB.

32 l New-Tech Magazine Europe