1. Field of the Invention
This invention relates to a connector for a coaxial transmission line used for limited bandwidth. More particularly, the invention relates to a connector for connecting coaxial transmission lines over a specified RF band by the use of a coaxial open circuit stub section.
2. Description of the Related Art
Currently, coaxial connectors use a spring-type contacts for connecting to the inner conductor of a coaxial transmission line and a clamp for connecting to the outer conductor of the coaxial transmission line. These metal-to-metal electrical contacts known in the art provide an extension of the signal path in a broad frequency range. Such connectors are generally made of costly materials and are designed in a way that excessive force is exerted on the cable conductors to eliminate the poor contact of conductors. Such a design solution requires cables with thicker conductors to withstand the contact force and to ensure proper electrical contact. Consequently, the cost of the cables as well as the connectors is relatively high. Further, such connectors require specific installation requirements, such as torque levels, to apply the proper contact force between the conductors. A field service technician may have a difficult time fulfilling installation requirements in adverse weather conditions which require the use of gloves. If the field installation requirements are not met, then electrical contact may be lost, resulting in the inability to properly transmit the signals.
In certain applications, however, only signals within a specified frequency band are transmitted and thus do not require broadband connectors. To properly transmit these signals, costly materials or designs providing metal-to-metal electrical contacts are not necessary.
A coaxial electrical connector for mating a coaxial transmission line having a center conductor and an outer conductor with an electrical device is disclosed. The connector includes a substantially cylindrical outer conductor having spaced first and second end portions, an elongate central portion intermediate said end portions, said cylindrical outer conductor having an axial bore therethrough, and a dielectric insulator fixed within said bore at said center portion.
The connector also includes a coupling mechanism mating said coaxial transmission line to said substantially cylindrical outer conductor, and an inner conductor within said insulator and extending coaxially within the bore, said inner conductor having first and second end portions corresponding to said first and second end portions of said cylindrical outer conductor and a central portion corresponding to said central portion of said cylindrical outer conductor.
The first end portions of the inner conductor interfits with the coaxial transmission line such that said first end portion of said inner conductor mates with the center conductor of the coaxial transmission line, said first end portion of said cylindrical outer conductor mates with the outer conductor of the coaxial transmission line. Additionally, said second end portions are mateable with the electrical device. Moreover, a dielectric member is disposed between (1) the first end portion of the inner conductor of the connector and the center conductor of the coaxial transmission line, or between (2) the first end portion of the cylindrical outer conductor of the connector and the outer conductor of the coaxial transmission line, or (3) both, so as to prevent a direct electrical contact therebetween.
In another embodiment, the inner conductor of the connector is coupled inside a hollow center conductor of the coaxial transmission line.
In yet another embodiment, a solid center conductor of the coaxial transmission line is coupled inside a hollow inner conductor of the connector.
In an alternative embodiment, a shunt short circuit stub is disposed to provide an electrical connection between the inner and the outer conductor of the connector.
In another alternative embodiment, an outer choke is disposed in the cylindrical outer conductor of the connector.
In yet another alternative embodiment, the outer conductor of the connector is coupled inside the outer conductor of the coaxial transmission line.
Other features and advantages of the present invention will be apparent from the following description taken in connection with the accompanying drawings, wherein:
In a preferred embodiment of the invention, a transmission line is coupled to a connector, wherein the connector comprises a cylindrical outer conductor body, a dielectric insulator, an inner conductor within the dielectric insulator, and a series open circuit inner stub and a series open circuit outer stub at an end of the connector coupled to the connector. Although the preferred embodiment is described below in
A cross sectional view of a tuned RF coaxial connector 101 is shown in
The coaxial transmission line 180 includes a typically smooth hollow tube center conductor 182A surrounded by an insulation 184 with a dielectric constant ε1. The insulation 184 is made of any suitable dielectric, including, for example, solid polyethylene, foamed polyethylene, TEFLON (polytetrafluoroethylene), fluorinated ethylene propylene, and foamed fluorinated ethylene propylene, or any material in combination with air. The dielectric provides support to maintain the inner conductor on the axis of cable. Surrounding the insulation 184 is an outer conductor 186. The outer conductor 186 is typically made of an annular corrugated copper sheet to provide flexibility and ease in attaching standard connectors. Surrounding the outer conductor 186 is a protective cover 188.
The coaxial transmission line 180 is coupled to the connector 101. The connector 101 comprises a substantially cylindrical outer conductor 200 having spaced first end portion 210, second end portion 220, and an elongate central portion 230. The elongate central portion 230 is disposed between the first end portion 210 and the second end portion 220, and has an axial bore 240 therethrough. Additionally, there is a dielectric bead 250 with a dielectric constant ε2 fixed inside the axial bore 240 at an end of the center portion 230. As with the insulation 184 of the coaxial cable 180, the dielectric bead 250 is made of any suitable dielectric, including, for example, solid polyethylene, foamed polyethylene, TEFLON, fluorinated ethylene propylene, and foamed fluorinated ethylene propylene. By way of example, the dielectric bead 250 is made of solid TEFLON.
The connector 101 also includes an inner conductor 300 within the dielectric bead 250 and extending coaxially within the axial bore 240. The inner conductor 300 has first and second end portions 310 and 320 corresponding to the first and second end portions 210 and 220 of the cylindrical outer conductor 200, and a central portion 330 corresponding to the central portion 230 of the cylindrical outer conductor 200. In the axial bore 240, the inner conductor 300 is fixed in place and electrically insulated from the cylindrical outer conductor 200 by the dielectric bead 250. The first end portions 210 and 310 interfit with the coaxial transmission line 180.
Specifically, the first end portion 310 of the inner conductor 300 has spring-type contacts for electrical contact with the center conductor 182A. As there are numerous standard means in the art to connect cables and connectors in metal-to-metal electrical contact, the electrical contact between the first end portion 310 of the inner conductor 300 and the center conductor 182A of the coaxial transmission line 180 will not be described in detail.
At the first end portion 210 of the cylindrical outer conductor 200, there is a series open circuit outer stub 212A capacitively coupled to the outer conductor 186. In this embodiment, the capacitive coupling is created by the larger inside diameter of the first end portion 210 of the cylindrical outer conductor 200 surrounding the outer conductor 186. The open circuit outer stub 212A is preferably lined with a dielectric lining 214A between the series open circuit outer stub 212A and the outer conductor 186 to maintain the proper alignment of components and to prevent electrical contact. The dielectric lining 214A is made of a suitable dielectric material such as polyethylene. By providing a dielectric material such as the dielectric lining 214A, metal-to-metal contact requiring a complex design is not required between the outer conductors of the connector and the coaxial transmission line.
Further, there is a coupling mechanism 500 to mate the coaxial transmission line 180 to the cylindrical outer conductor 200. The coupling mechanism 500 is a coupling nut made of a dielectric material such as DELRIN.
The second end portions 220 and 320 are mateable with an electrical device, including coaxial transmission lines (not pictured). By way of example, the second end portions 220 and 320 comprise a standard 7-16 DIN-type cable interface mateable with the electrical device. In another configuration, the second end portions 220 and 320 comprise a standard N-type cable interface (not pictured).
Additionally, the embodiment includes a resilient gland 510A disposed between a distal end of the dielectric lining 214A and an inside surface of the coupling mechanism 500. Specifically, the coupling mechanism 500 has a hollow inner cavity wherein a step is disposed along the inside surface. When the connector 101 is coupled to the cable 180, i.e., when the coupling mechanism 500 is tightened with respect to the cylindrical outer conductor 200 and the coaxial transmission line 180, the resilient gland 510A is compressed. As a result, the resilient gland 510A deforms and protrudes into a corrugation of the corrugated outer conductor 186 of the cable 180. In such an arrangement, the resilient gland 510A grips the corrugated outer conductor 186 of the coaxial transmission line 180 to hold the same in place and, at the same time, provides a moisture barrier.
Alternatively, in another embodiment shown in
At the open series outer stub 212C, there is an outer choke 600 extending down the length of the first end portion 210 into the cylindrical center portion 230 and surrounding the dielectric lining 214C. The choke 600 is a dielectric layer such as an air gap, preferably, or a dielectric sleeve, that is disposed within first end portion 210 of the cylindrical outer conductor 200 of the connector 106 and is electrically quarter wavelength long. With an air gap, the choke 600 is physically longer than a quarter wavelength dielectric loaded stub.
Further, there is a conductive member 520 disposed between the resilient gland 510B and the distal end of the series open circuit outer stub 212C, as shown in
In an alternative embodiment, the conductive resilient gland 510B may replace the conductive member 520 depending on the conductivity of the resilient gland 510B.
In another embodiment of the invention (not shown), a matching transformer section can be integrally incorporated into the connector 108 shown in
It is noted that in all the embodiments described above, the length of the series open circuit stub inner conductor and the series open circuit stub outer conductor is electrically one quarter wavelength long. The exact physical length of a stub is usually determined by test since the volume of cavity created by the cable conductors and connector is a combination of dielectric and air to maintain the slip fit requirement for field installation of the connector.
This design can theoretically be used at any RF frequency, however, the invention is used for frequencies preferably above 800 MHz. In one embodiment, the invention is used for frequencies between 800 MHz and 6000 MHz. A cable for the connector embodiments described above for application in the 1850 to 1990 MHz frequency range uses a corrugated outer conductor. Such an outer conductor complicates the impedance since the effective diameter of outer conductor used to form the inner conductor of stub will be less than the maximum outer diameter of the cable. The maximum outer diameter of the outer conductor of the cable will determine the lowest impedance stub that can be realized. For example, an 8 ohm impedance can still be obtained on a ⅞ nominal cable with a 0.02 inch dielectric wall tube used at the stub.
Physically, the incorporation of the series open circuit stub conductor allow for simplified connector installation by allowing for less precise cutting of the coaxial transmission cable and less critical torque requirements to install the connector. In effect, the utilization of a non-metallic connector contact through the use of a dielectric sleeve allows the connector to be hand tightened. Furthermore, capacitively coupling both inner and outer conductors eliminates all passive intermodulation (PIM) from the most likely source while eliminating the most expensive and complicated parts of the connector. Additionally, implementation cost is reduced through the elimination of some of the expensive contact parts used in the standard coaxial connector.
The invention is described in terms of the above embodiments which are to be construed as illustrative rather than limiting, and this invention is accordingly to be broadly construed. The principle upon which this invention is based can also be applied to other frequency bands of interest.
It is contemplated that numerous modifications may be made to the present invention without departing from the spirit and scope of the invention as defined in the following claims.