Triaxial transmission line for transmitting two independent frequencies

Abstract

A triaxial transmission line provides for the transmission of two independent signals from a transmitter to an antenna utilizing the middle conductor as a portion of the coaxial line for both signals. One signal utilizes the inner and middle conductor and the second signal the outer and middle conductor. The outer conductor at both ends of the triaxial transmission is line is shorted to the middle conductor.

Claims

1. A triaxial transmission line having two ends for transmitting two independent and different frequency signals f.sub.1 and f.sub.2, from two transmitter channels at one end respectively to two antennas, one for each signal at the other end, comprising:

an inner substantially cylindrical conductor having an axis;

an outer tubular conductor coaxial with said inner conductor;

a middle tubular conductor coaxial with and between said inner and outer conductors;

coaxial input and output ports for said signal f.sub.1 for respective connection to one of said transmitter channels and one of said antennas, each coaxial with said conductors at said two ends respectively of said transmission line and including said inner and middle conductors as the active portions of said ports;

coaxial input and output ports for said signal f.sub.2 for respective connection to the other of said transmitter channels and the other of said antennas, each perpendicular to said axis of said inner conductor and respectively positioned near said two ends of said transmission line and including as active portions said outer and middle conductors whereby two independent and isolated signal paths for f.sub.1 and f.sub.2 are respectively provided by said triaxial transmission line from said transmitter channels to said respective antennas.

2. A transmission line as in claim 1 including shorting ring means for conductively shorting said outer to said middle conductor near said ends at a distance substantially one quarter wavelength, with respect to said frequency f.sub.2, from said f.sub.2 coaxial ports.

3. A triaxial transmission line, as in claim 1 where said f.sub.2 ports each include a stepped coaxial conductor connected to said middle conductor to transform the impedance to said outer and middle conductors to the desired characteristic impedance of said f.sub.2 ports.

4. A triaxial transmission line as in claim 1 where the diameter of the middle conductor is chosen with respect to the diameter of said inner conductor to match the desired characteristic impedance of said f.sub.1 ports..Iadd.

5. A triaxial transmission line having two ends for transmitting two independent and different frequency signals f.sub.1 and f.sub.2 from two transmitter channels at one end respectively to two antennas, one for each signal, at the other end, comprising:

an inner substantially cylindrical conductor having an axis;

an outer tubular conductor coaxial with said inner conductor;

a middle tubular conductor coaxial with and between said inner and outer conductors;

a coaxial input port for said signal f.sub.1, for connection to one of said transmitter channels, coaxial with and connected at said one end and including as active portions said inner and middle conductors, said inner and middle conductors transmitting said signal f.sub.1 to one of said antennas at said other end of said transmission line;

a coaxial input port for said signal f.sub.2, for connection to the other of said transmitter channels, perpendicular to said axis of said inner conductor and positioned near said one end of said transmission line and connected to and including as active portions said outer and middle conductors, said outer and middle conductors transmitting said signal f.sub.2 to the other of said antennas at said other end of said transmission line, whereby two independent and isolated signal paths for f.sub.1 and f.sub.2 are respectively provided by said triaxial transmission line from said transmitter channels to said respective antennas..Iaddend.