Communication connector with crosstalk compensation

We claim: 1. A circuit for crosstalk compensation, said circuit comprising: a first, a second, a third, and a fourth signal conductors, said first and said fourth signal conductors forming a first signal-pair, and said second and said third signal conductors forming a second signal-pair, a first offshoot conductor having a first end and a second end; and a second offshoot conductor having a first end and a second end, said first end of said first offshoot conductor being connected to said second signal conductor, said first end of said second offshoot conductor being connected to said third signal conductor, and said second end of said first offshoot conductor being capacitively coupled to said second end of said second offshoot conductor, wherein a first capacitive coupling and a first mutual inductive coupling occur between at least a portion of said first signal conductor and at least a portion of said first offshoot conductor, and wherein a second capacitive coupling and a second mutual inductive coupling occur between at least a portion of said fourth signal conductor and at least a portion of said second offshoot conductor. 2. The circuit of claim 1 , wherein said second end of said first offshoot conductor is capacitively coupled to said second end of said second offshoot conductor via a capacitor. 3. The circuit of claim 2 , wherein said capacitor includes a first capacitor member and a second capacitor member, said first capacitor member being connected to said second end of said first offshoot conductor and said second capacitor member being connected to said second end of said second offshoot conductor. 4. The circuit of claim 2 , wherein said capacitor is at least one of a finger capacitor and a pad capacitor. 5. The circuit of claim 1 , wherein at least one of said first capacitive coupling and said first mutual inductive coupling is achieved by at least one of distributed coupling and discrete coupling element. 6. The circuit of claim 1 , wherein said first capacitive coupling and said first mutual inductive coupling occur at an approximately same time. 7. The circuit of claim 6 , wherein said second capacitive coupling and said second mutual inductive coupling occur at an approximately same time. 8. The circuit of claim 7 , wherein said first capacitive coupling, said first mutual inductive coupling, said second capacitive coupling, and said second mutual inductive coupling occur at an approximately same time. 9. The circuit of claim 1 , wherein a signal produced by said first mutual inductive coupling is phase-shifted approximately 90 degrees relative to a signal produced by said first capacitive coupling. 10. The circuit of claim 1 , wherein a combined signal produced by said first mutual inductive coupling and said second mutual inductive coupling is phase-shifted approximately 90 degrees relative to a combined signal produced by said first capacitive coupling and said second capacitive coupling. 11. The circuit of claim 1 , wherein said second signal conductor is connected to a first source impedance, said third signal conductor is connected to a second source impedance, and said first source impedance, said second source impedance, and said capacitive coupling between said second end of said first offshoot conductor and said second end of said second offshoot conductor forming a resistor-capacitor circuit, said resistor-capacitor circuit being excited in response to a signal transmitted on said first signal conductor and said fourth signal conductor. 12. The circuit of claim 1 , wherein said circuit is implemented on at least one of a printed circuit board and a lead frame. 13. A communication jack, comprising: a first, a second, a third, and a fourth signal conductors, each of said first, said second, said third, and said fourth signal conductors having a respective plug interface contact, a respective insulation displacement contact, and a respective signal trace connecting said respective plug interface contact to said respective insulation displacement contact, said first and said fourth signal conductors forming a first signal-pair, and said second and said third signal conductors forming a second signal-pair; a first offshoot conductor having a first end and a second end; and a second offshoot conductor having a first end and a second end, said first end of said first offshoot conductor being connected to said second signal conductor, said first end of said second offshoot conductor being connected to said third signal conductor, and said second end of said first offshoot conductor being capacitively coupled to said second end of said second offshoot conductor, wherein a first capacitive coupling and a first mutual inductive coupling occur between at least a portion of said first signal conductor and at least a portion of said first offshoot conductor, and wherein a second capacitive coupling and a second mutual inductive coupling occur between at least a portion of said fourth signal conductor and at least a portion of said second offshoot conductor. 14. The communication jack of claim 13 , wherein said second end of said first offshoot conductor is capacitively coupled to said second end of said second offshoot conductor via a capacitor. 15. The communication jack of claim 14 , wherein said capacitor includes a first capacitor member and a second capacitor member, said first capacitor member being connected to said second end of said first offshoot conductor and said second capacitor member being connected to said second end of said second offshoot conductor. 16. The communication jack of claim 14 , wherein said capacitor is at least one of a finger capacitor and a pad capacitor. 17. The communication jack of claim 13 , wherein at least one of said first capacitive coupling and said first mutual inductive coupling is achieved by at least one of distributed coupling and discrete coupling element. 18. The communication jack of claim 13 , wherein said first capacitive coupling and said first mutual inductive coupling occur at an approximately same time. 19. The communication jack of claim 18 , wherein said second capacitive coupling and said second mutual inductive coupling occur at an approximately same time. 20. The communication jack of claim 19 , wherein said first capacitive coupling, said first mutual inductive coupling, said second capacitive coupling, and said second mutual inductive coupling occur at an approximately same time. 21. The communication jack of claim 13 , wherein a signal produced by said first mutual inductive coupling is phase-shifted approximately 90 degrees relative to a signal produced by said first capacitive coupling. 22. The communication jack of claim 13 , wherein a combined signal produced by said first mutual inductive coupling and said second mutual inductive coupling is phase-shifted approximately 90 degrees relative to a combined signal produced by said first capacitive coupling and said second capacitive coupling. 23. The communication jack of claim 13 , wherein said second signal conductor is connected to a first source impedance, said third signal conductor is connected to a second source impedance, and said first source impedance, said second source impedance, and said capacitive coupling between said second end of said first offshoot conductor and said second end of said second offshoot conductor forming a resistor-capacitor circuit, said resistor-capacitor circuit bei