Transcript Slide 1

2010
Wideband, High Frequency,
and High Power Circulator
Problem
Method
The United States Navy uses HF, UHF, and VHF
frequency bands for person-to-person, ship-to-person,
and ship-to-ship communication systems. To reduce
size, weight, and cost it is common to use a single
antenna for both transmit and receive mode. This is
accomplished by means of a circulator that can direct a
signal to a particular port depending on the direction of
signal flow.
The team worked independent of each other , using a
“divide and conquer” approach. Andrew choose to
pursue a topology that consisted of transistors with
theories derived from “The Design of Active Circulators”
by Larry Lee Lamb, while Jake worked on a schematic
consisting of three cascading Op-Amps from “Low
Frequency Circulator/Isolator Uses No Ferrite or
Magnet” by Charles Wenzel.
Modern circulator technology has yet been able to
achieve high power in the HF, UHF, and VHF bands.
However, with improvements in the bandwidth and
power capabilities of discrete and integrated transistors
there is now reason to believe that active circulators
may in fact be suitable for this Navy application.
Transistor Design
This graph is only a simulation of the HF design
using the MPSH10 transistor because a working
physical circuit could not be realized. A 2N3904
transistor circuit was constructed in the first
semester and still has the highest bandwidth for
this design at 7.3 MHz.
Design
Transistor Design
Solution
Results
Op-Amp Design
The graph above shows the S-parameters
measured from port A to C. Since the design is
symmetric, all ports have all the same
parameters. The limiting factor in this design
proved to be the reflection coefficients, while
the forward and reverse gain passed
expectations.
Maximum Frequency = 44.38 MHz
(Small Signal)
THS3061
THS
Our senior design team, Laplace Sauce, was challenged
to develop an HF circulator that pushes the envelope in
terms of power, bandwidth, or both in the HF band.
Further Work &
Feasibility
Specifications
Insertion Loss < -.5dB
Op-Amp Design
Team Laplace Sauce
Isolation > -15db
Frequency > 30 MHz
10W < Power < 50W
Both candidates, especially the op amp
design, are exceptionally suited for
small signal operations. However, to
incorporate high power into the design;
available current technology dictates
use of RF amplifiers on the output
stages of the circulator.
Circulator Model
RF Amplifier
Andrew Wadja
Jake Smith
This project was funded by the US Navy under BAA 07-037. The faculty advisers are Dr. Jeffrey Young , Dr. Ken Noren, Dr. Herb Hess, and Dr. Greg
Donohoe. Special thanks to Greg Klemesrud and Chris Wagner.