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A cable connector comprising a connector body, a compression member operably connected to a second end of the connector body, the compression member including a compression portion having a forward facing surface, wherein the compression portion protrudes from an inner surface of the compression mem

A cable connector comprising a connector body, a compression member operably connected to a second end of the connector body, the compression member including a compression portion having a forward facing surface, wherein the compression portion protrudes from an inner surface of the compression member, wherein, when the compression member is slidably axially compressed within the connector body, the compression portion of the compression member compresses an inner sleeve into crimping engagement with a coaxial cable is provided. An associated method is also provided.

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1. A cable connector comprising: a connector body defining a main bore along an elongate axis, a first end, and a second end extending axially aft of the first end:an inner sleeve disposed within the main bore of the connector body and including a plurality of flexible compression segments separated

1. A cable connector comprising: a connector body defining a main bore along an elongate axis, a first end, and a second end extending axially aft of the first end:an inner sleeve disposed within the main bore of the connector body and including a plurality of flexible compression segments separated by a plurality of axial slots;an extension tip having a first end and a second end disposed within the main bore, the extension tip configured to engage a conductor pin of a coaxial cable at the first end;an extension rod removably connected to the second end of the extension tip;wherein the extension rod and the extension tip are configured to slide within the main bore to accommodate different assembly configurations and cable sizes; anda compression member operably connected to a second end of the connector body, the compression member including a compression portion having a forward facing surface, wherein the compression portion protrudes from an inner surface of the compression member, the compression member being configured to compress a portion of the compression segments of the inner sleeve into crimping engagement with the coaxial cable. 2. The cable connector of claim 1, wherein the extension rod includes a projection at one end. 3. The cable connector of claim 2, wherein the extension tip includes a recess at an opposite end that is configured for press-fit engagement with the projection. 4. The cable connector of claim 1, further comprising a fastener member extending from a first end of the connector body for interchangeable connection to one of a plurality of electronic devices. 5. The cable connector of claim 1, wherein the portion of the inner sleeve is compressed onto a doubled-over, braided layer of the coaxial cable. 6. The cable connector of claim 1, wherein the coaxial cable is a mini-coaxial cable. 7. A coaxial cable connector comprising: a connector body defining a main bore, the main bore traversing the connector body from a first end to a second end;a compression member operably connected to the second end of the connector body;an inner sleeve including a plurality of elongate slots defining a plurality of axially extending compression segments, each compression segment having a leading end and a trailing end, a portion of the trailing end being configured to contact compression member being configured to contact a compression segment such that the trailing end thereof is and be compressed into engagement with a coaxial cable; andan extension tip having a first end and second end inserted in the main bore, the extension tip configured to engage a conductor pin of the coaxial cable at the first end and removeably connect to an extension rod at the second end, and wherein the extension tip and the extension rod are slidable within and through the main bore in response to axial movement of the coaxial cable and conductor pin through the main bore. 8. The coaxial cable connector of claim 7, wherein the extension rod includes a projection at one end. 9. The coaxial cable connector of claim 8, wherein the extension tip includes a recess at the opposite end that is configured for press-fit engagement with the projection of the extension rod. 10. The coaxial cable connector of claim 7, further comprising a fastener member extending from the first end of the connector body for interchangeable connection to one of a plurality of electronic devices. 11. The coaxial cable connector of claim 7, wherein at least part of the inner sleeve is disposed within the main bore of the connector body. 12. The coaxial cable connector of claim 7, wherein the coaxial cable is a mini-coaxial cable. 13. A connector comprising: a connector body defining a main bore;an inner sleeve disposed in the main bore and mounted to the connector, the inner sleeve having a plurality of circumferentially-spaced slots defining a plurality of axially extending compression segments;an extension structure disposed within the main bore, the extension structure having a first end configured to engage a conductor pin of a coaxial cable and a second end configured to engage an extension rod, and wherein the extension structure and the extension rod is configured to slide within the main bore to accommodate different coaxial cable configurations and sizes; anda compression sleeve disposed within at least a portion of the main bore, the compression sleeve configured to compress a portion of the slotted end of the inner sleeve into crimping engagement with the coaxial cable. 14. The connector of claim 13, wherein the compression sleeve further comprises a compression portion, the compression portion protruding from an inner surface of the compression sleeve. 15. The connector of claim 14, wherein the compression portion is structurally integral to the compression sleeve. 16. The connector of claim 14, wherein the compression portion includes a ramped surface configured to gradually compress the slotted end of the inner sleeve into crimping engagement with the portion of the coaxial cable. 17. The connector of claim 13, wherein a portion of the inner sleeve is disposed within the main bore. 18. The connector of claim 13, wherein axially advancing the conductor pin through the main bore into engagement with the extension structure causes the extension structure to slide in an axial direction within the main bore. 19. A cable connector comprising: a connector body defining a main bore;an extension rod disposed and centered within the main bore;an extension tip having a first end and a second end disposed and centered within the main bore, the extension tip configured to receive a conductor pin of a coaxial cable at the first end and guide the conductor pin into the main bore, the extension tip configured to guide the extension rod out the second end of the connector body;the extension rod and extension tip, in combination, being configured to slide within the main bore to guide and receive different coaxial cable configurations and sizes;a sleeve disposed in the main bore and mounted to the connector, the sleeve having a plurality of circumferentially-spaced slots defining a plurality of axially extending compression segments, the compression segments each configured for form an effective hinge portion extending tangential to a circumference of the sleeve and a compression end;a compression member slidably mounted to the second end of the connector body, the compression member including a compression portion protruding inwardly and contacting a portion of the compression segments between the effective hinge portion and the compression end to flex the compression end into frictional engagement with an outer jacket of a coaxial cable so as to fit different coaxial cable configurations and sizes. 20. The connector of claim 19, wherein axially advancing the conductor pin through the main bore into engagement with the extension tip causes the extension tip to slide in an axial direction within the main bore. 21. The connector of claim 19, wherein a width of the slots is configured to controls flexure of the compression segments in response to contact by the compression member. 22. The connector of claim 19 wherein the compression end of each compression segment includes a plurality of serrations to effect frictional and mechanical engagement with the outer jacket of the coaxial cable. 23. The connector of claim 19, wherein the extension tip includes a recess at the opposite end that is configured for press-fit engagement with the projection of the extension rod. 24. The connector of claim 19, wherein the compression member includes a ramped surface configured to gradually compress the sleeve into crimping engagement around different coaxial cable configurations and sizes. 25. The connector of claim 24, wherein the compression member includes a ramped surface configured to gradually crimp the sleeve around the cable when the compression member axially moves from the uncrimped position to the crimped position. 26. A cable connector for being compressively fit around a plurality of different sizes and shapes of a cable comprising: a connector body defining a main bore;an extension tip having a first end and a second end disposed within the main bore, the extension tip configured to engage a conductor pin of the cable at the first end;an extension rod removably connected to the second end of the extension tip;wherein the extension rod and the extension tip are configured to slide within the main bore;an inner compression sleeve member configured to be compressively fit around a plurality of different sizes and shapes of the cable;an outer compression ring member configured to axially move relative to the inner compression sleeve member so as compressively fit the inner compression sleeve member around the plurality of different sizes and shapes of the cable; andwherein the inner compression sleeve member has a plurality of longitudinally extending inner compression segments that are circumferentially separated by a plurality of longitudinally extending inner slots so as to control inner degrees of bending of the plurality of longitudinally extending inner compression segments when the outer compression ring member axially moves relative to the inner compression sleeve member and compressively fit the plurality of longitudinally extending inner compression segments around the plurality of different sizes and shapes of the cable. 27. The connector of claim 26, wherein the extension tip and the extension rod are configured to accommodate the plurality of different sizes and shapes of the cable. 28. The connector of claim 26, wherein the inner compression sleeve member has an inner trailing end, and the plurality of longitudinally extending inner compression segments extend from the inner trailing end of the inner compression sleeve member toward a rearward direction away from an interface port when the connector is installed on the interface port. 29. The connector of claim 26, wherein the outer compression ring member includes a plurality of longitudinally extending outer compression segments that are circumferentially separated by a plurality of longitudinally extending outer slots so as to control outer degrees of bending of the plurality of longitudinally extending outer compression segments when the outer compression ring member axially moves relative to the inner compression sleeve member and compressively fit the plurality of longitudinally extending inner compression segments around the plurality of different sizes and shapes of cable. 30. The connector of claim 29, wherein the outer compression ring member has an outer trailing end, and the plurality of longitudinally extending outer compression segments extend from the outer trailing end of the outer compression ring member toward a rearward direction away from an interface port when the connector is installed on the interface port. 31. The connector of claim 26, wherein the outer compression ring member includes a ramped surface configured to gradually compress the inner compression sleeve member into crimping engagement around different coaxial cable configurations and sizes. 32. The connector of claim 26, wherein the outer compression ring member is configured to axially move from an uncrimped position, where the inner compression sleeve member is not crimped around a cable, and a crimped position, where the inner compression sleeve member is crimped around the cable. 33. The connector of claim 32, wherein the outer compression ring member includes a ramped surface configured to gradually crimp the inner compression sleeve member around the cable when the outer compression ring member axially moves from the uncrimped position to the crimped position. 34. A cable connector for being compressively fit around a plurality of different sizes and shapes of a cable comprising: a connector body defining a main bore;an extension tip having a first end and a second end disposed within the main bore, the extension tip configured to engage a conductor pin of the cable at the first end;an extension rod removably connected to the second end of the extension tip;wherein the extension rod and the extension tip are configured to slide within the main bore:an inner compression sleeve member configured to be compressively fit around a plurality of different sizes and shapes of the cable;an outer compression ring member configured to axially move relative to the inner compression sleeve member so as compressively fit the inner compression sleeve member around the plurality of different sizes and shapes of the cable;wherein the inner compression sleeve member has a plurality of longitudinally extending inner compression segments that are circumferentially separated by a plurality of longitudinally extending inner slots so as to control inner degrees of bending of the plurality of longitudinally extending inner compression segments when the outer compression ring member axially moves relative to the inner compression sleeve member and compressively fit the plurality of longitudinally extending inner compression segments around the plurality of different sizes and shapes of the cable;wherein the inner compression sleeve member has an inner trailing end, and the plurality of longitudinally extending inner compression segments extend from the inner trailing end of the inner compression sleeve member toward a rearward direction away from an interface port when the connector is installed on the interface port;wherein the outer compression ring member includes a plurality of longitudinally extending outer compression segments that are circumferentially separated by a plurality of longitudinally extending outer slots so as to control outer degrees of bending of the plurality of longitudinally extending outer compression segments when the outer compression ring member axially moves relative to the inner compression sleeve member and compressively fit the plurality of longitudinally extending inner compression segments around the plurality of different sizes and shapes of the cable; andwherein the outer compression ring member has an outer trailing end, and the plurality of longitudinally extending outer compression segments extend from the outer trailing end of the outer compression ring member toward the rearward direction away from an interface port when the connector is installed on the interface port. 35. The connector of claim 34, wherein the extension tip and the extension rod are configured to accommodate the plurality of different sizes and shapes of the cable. 36. The connector of claim 34, wherein the outer compression ring member includes a ramped surface configured to gradually compress the inner compression sleeve member into crimping engagement around different cable configurations and sizes. 37. The connector of claim 34, wherein the outer compression ring member is configured to axially move from an uncrimped position, where the inner compression sleeve member is not crimped around a cable, and a crimped position, where the inner compression sleeve member is crimped around the cable. 38. The connector of claim 37, wherein the outer compression ring member includes a ramped surface configured to gradually crimp the inner compression sleeve member around the cable when the outer compression ring member axially moves from the uncrimped position to the crimped position.