Digitally controlled phase shifter

What is claimed is: 1. An apparatus comprising: a first component connected between a first terminal and a node; a second component connected between a second terminal and the node; a third impedance connected between the first terminal and the second terminal; means for selectably disconnecting the third impedance from the second terminal, the means for selectively disconnecting the third impedance being coupled in series with the third impedance; and means for selectably connecting the node to a ground, the means for selectably disconnecting and connecting configured to enable selected amounts of phase shifts to signals flowing between the first and second terminals, wherein a first group delay of the selected amounts of phased shifts, measured when the third impedance is disconnected from the second terminal and the node is disconnected from the ground is substantially equal to a second group delay of the selected amounts of phased shifts, measured when the third impedance is connected to the second terminal and the node is connected to the ground. 2. The apparatus of claim 1 , a first amount of phase shift of the selected amounts of phased shifts, is provided between the first and second terminals when the third impedance is disconnected from the second terminal and the node is disconnected from the ground, and a second amount of phase shift of the selected amounts of phased shifts, is provided between the first and second terminals when the third impedance is connected to the second terminal and the node is connected to the ground. 3. An apparatus comprising: a first component connected between a first terminal and a node; a second component connected between a second terminal and the node; a third impedance selectively connected between the first and second terminals by a first switch coupled in series with the third impedance, wherein the third impedance comprises a capacitor; a second switch connected between the node and a ground, the first and second switches configured to enable selected amounts of phase shifts to signals flowing between the first and second terminals; and wherein the first and second components comprising first and second transmission lines, respectively. 4. The apparatus of claim 3 , the first and second transmission lines are configured to provide a first amount of phase shift of the selected amounts of phased shifts, between the first and second terminals when the first and second switches are in an open position. 5. The apparatus of claim 4 , the first transmission line, the second transmission line, and the third impedance are configured to provide a second amount of phase shift of the selected amounts of phased shifts, between the first and second terminals when the first and second switches are in a closed position. 6. The apparatus of claim 5 , the first amount of phase shift is configured to be different from the second amount of phase shift by a selected value. 7. The apparatus of claim 6 , the selected value chosen from a set of values consisting of 180, 90, and 45 degrees. 8. An apparatus comprising: a first component connected between a first terminal and a node; a second component connected between a second terminal and the node; a third impedance selectively connected between the first and second terminals by a first switch coupled in series with the third impedance; and a second switch connected between the node and a ground, the first and second switches configured to enable selected amounts of phase shifts to signals flowing between the first and second terminals, wherein a first group delay of the selected amounts of phased shifts, measured when the first and second switches are open is substantially equal to a second group delay of the selected amounts of phased shifts, measured when the first and second switches are closed. 9. The apparatus of claim 8 , further comprising a fourth impedance connected between the node and the ground. 10. The apparatus of claim 9 , the fourth impedance comprising a second capacitor. 11. The apparatus of claim 8 , the first and second components comprising first and second capacitors, respectively, the third impedance comprising a first inductor and further including a fourth impedance connected between the node and the ground, the fourth impedance comprising a second inductor. 12. The apparatus of claim 11 , the first and second capacitors and the fourth impedance are configured to provide a first amount of phase shift of the selected amounts of phased shifts, between the first and second terminals when the first and second switches are in an open position. 13. The apparatus of claim 12 , the first and second capacitors and third impedance are configured to provide a second amount of phase shift of the selected amounts of phased shifts, between the first and second terminals when the first and second switches are in a closed position. 14. The apparatus of claim 13 , the first amount of phase shift is configured to be different from the second amount of phase shift by a selected value.