Active quasi circulator

The invention claimed is: 1. An RF quasi circulator circuit, comprising: a receive port, a transmit port and an antenna port; a differential amplifier stage having a first input, a second input, and an output that is coupled to the receive port; a first phase shifting element and a second phase shifting element, the first phase shifting element being coupled between the transmit port and the first input of the differential amplifier, and the second phase shifting element being coupled between the transmit port and the second input of the differential amplifier, the antenna port being coupled to the first input of the differential amplifier, and the antenna port being coupled to the second input of the differential amplifier via the first phase shifting element and the second phase shifting element, wherein the first phase shifting element provides a first phase shift, and the second phase shifting element provides a second phase shift, and wherein the first phase shift and the second phase shift add together to cause a total phase shift of 180 degrees between the first input and the second input of the differential amplifier for a signal incident at the antenna port; and a tunable impedance coupled to the differential amplifier, wherein the tunable impedance is controlled to tune a damping in a signal path from the transmit port to the receive port. 2. The RF quasi circulator of claim 1 , wherein the tunable impedance is controlled to maximize the damping in the signal path from the transmit port to the receive port. 3. The RF quasi circulator of claim 1 , wherein the first phase shifting element and the second phase shifting element each provides a 90 degree phase shift. 4. The RF quasi circulator of claim 1 , wherein at least one of the first and the second phase shifting elements is a delay line. 5. The RF quasi circulator of claim 1 , further comprising: an additional amplifier stage comprising an input coupled to the transmit port, and an output coupled to the first phase shifting element and to the second phase shifting element, wherein the antenna port is coupled to the output of the additional amplifier via the first phase shifting element. 6. The RF quasi circulator of claim 5 , wherein the additional amplifier stage includes at least one transistor stage including one or more transistors. 7. The RF quasi circulator of claim 6 , wherein the additional amplifier stage includes at least one transconductance stage having an output node, which is coupled to the antenna port via the first phase shifting element and which is coupled to the tunable impedance via the second phase shifting element. 8. The RF quasi circulator circuit of claim 1 , wherein the tunable impedance includes at least one tunable capacitance. 9. The RF quasi circulator circuit of claim 1 , wherein the tunable impedance is coupled to the second input of the differential amplifier or to the antenna port. 10. The RF quasi circulator circuit of claim 9 , wherein the tunable impedance is coupled to the antenna port in parallel with or in series to an antenna. 11. An RF quasi circulator circuit, comprising: a receive port, a transmit port and an antenna port; a first amplifier stage coupling the transmit port to the antenna port and configured to direct signals received at the transmit port to the antenna port; a second amplifier stage that is a differential amplifier stage coupling the antenna port and the receive port, and configured to direct signals received at the antenna port to the receive port; a first phase shifting element and a second phase shifting element, the first phase shifting element being coupled between the transmit port and a first input of the second amplifier stage, and the second phase shifting element being coupled between the transmit port and a second input of the second amplifier stage, the antenna port being coupled to the first input of the second amplifier stage, and the antenna port being coupled to the second input of the second amplifier stage via the first phase shifting element and the second phase shifting element, wherein the first phase shifting element provides a first phase shift, and the second phase shifting element provides a second phase shift, and wherein the first phase shift and the second phase shift add together to cause a total phase shift of 180 degrees between the first input and the second input of the second amplifier stage for a signal incident at the antenna port; and a tunable impedance coupled to the second amplifier stage, the tunable impedance being controlled to tune a damping in a signal path from the transmit port to the receive port. 12. The RF quasi circulator circuit of claim 11 , wherein the first amplifier stage is a transconductance stage having an output node, which is coupled to the antenna port via a first transmission line and which is coupled to the tunable impedance via a phase shifting element. 13. The RF quasi circulator circuit of claim 12 , wherein the second amplifier stage includes at least one second transistor having a base and an emitter, the antenna port being coupled to the emitter of the transistor and to the base of the transistor via a signal path that causes a 180° phase lag. 14. The RF quasi circulator circuit of claim 13 , wherein the signal path that causes a 180° phase lag includes at least one delay line. 15. The RF quasi circulator circuit of claim 13 , wherein the base of the transistor is AC coupled to a supply potential via the tunable impedance. 16. The RF quasi circulator circuit of claim 12 , wherein the phase shifting element includes at least one delay line. 17. The RF quasi circulator circuit of claim 11 , wherein the tunable impedance is coupled to the antenna port in parallel or coupled to an antenna in series. 18. The RF quasi circulator circuit of claim 17 , wherein the tunable impedance includes at least one capacitance. 19. The RF quasi circulator circuit of claim 17 , wherein the tunable impedance includes at least one varactor diode. 20. The RF quasi circulator of claim 11 , wherein the tunable impedance is controlled to maximize the damping in the signal path from the transmit port to the receive port.