System and method for a radio frequency filter

What is claimed is: 1. A circuit comprising: a first RF front-end of a first band; a second RF front-end of the first band; a first multi-feed antenna; a second multi-feed antenna; and a first RF switch configured to couple the first RF front-end to a first element of the first multi-feed antenna and coupled the second RF front-end to a first element of the second multi-feed antenna in a first configuration, and configured to couple the first RF front-end to the first element of the second multi-feed antenna and couple the second RF front-end to the first element of the first multi-feed antenna in a second configuration, wherein: the first RF front-end comprises a first receive path, a first transmit path, and a first frequency combiner configured to couple the first receive path and the first transmit path; and the second RF front-end comprises a second receive path, a second transmit path, and a second frequency combiner configured to couple the second receive path and the second transmit path in a first mode, and configured to couple the second receive path, the second transmit path, and the first frequency combiner in a second mode. 2. The circuit of claim 1 , wherein: the first RF front-end comprises a first power amplifier; and the second RF front-end comprises a second power amplifier. 3. The circuit of claim 1 , wherein: the first receive path comprises a first plurality of filters coupled in series with a corresponding first plurality of low noise amplifiers; and the second receive path comprises a first plurality of filters coupled in series with a corresponding first plurality of low noise amplifiers. 4. The circuit of claim 1 , further comprising: a third RF front-end of a second band; a fourth RF front-end of the second band; and a second RF switch configured to couple the third RF front-end to a second element of the first multi-feed antenna and couple the fourth RF front-end to a second element of the second multi-feed antenna in a third configuration, and configured to couple the third RF front-end to the second element of the second multi-feed antenna and couple the fourth RF front-end to the second element of the first multi-feed antenna in a fourth configuration. 5. The circuit of claim 4 , wherein the first band is higher in frequency than the second band. 6. The circuit of claim 1 , further comprising: a third RF front-end of a second band; a fourth RF front-end of the second band; a second RF switch configured to couple the third RF front-end to the first element of the first multi-feed antenna and couple the fourth RF front-end to the first element of the second multi-feed antenna in a third configuration, and configured to couple the third RF front-end to the first element of the second multi-feed antenna and couple the fourth RF front-end to the first element of the first multi-feed antenna in a fourth configuration; a first diplexer having inputs coupled to the first and second RF switches and an output coupled to the first element of the first multi-feed antenna; and a second diplexer having inputs coupled to the first and second RF switches and an output coupled to the first element of the second multi-feed antenna. 7. The circuit of claim 6 , further comprising: a fifth RF front-end of a third band; a sixth RF front-end of the third band; and a third RF switch configured to couple the fifth RF front-end to a second first element of the first multi-feed antenna and couple the sixth RF front-end to a second element of the second multi-feed antenna in a fifth configuration, and configured to couple the fifth RF front-end to the second element of the second multi-feed antenna and couple the sixth RF front-end to the second element of the first multi-feed antenna in a sixth configuration. 8. The circuit of claim 7 , wherein: the first band is higher in frequency than the second band; and the third band in higher in frequency than the first and second bands. 9. The circuit of claim 1 , wherein: the first frequency combiner is configured to couple an input of the first receive path and an output of the first transmit path to a first port of the first RF front-end; and the second frequency combiner is configured to in the first mode, couple an input of the second receive path and an output of the second transmit path to a second port, and in the second mode, couple the input of the second receive path, the output of the second transmit path, and the first port of the first RF front-end to the second port, wherein the first port is coupled to a first input of the first RF switch and the second port is coupled to a second input of the first RF switch. 10. The circuit of claim 9 , wherein the first frequency combiner comprises: a first power splitter having an input coupled to the first transmit path; a first phase shifter coupled to a first output of the first power splitter; a second phase shifter coupled a second output of the first power splitter; a first filter coupled to the first phase shifter; a second filter coupled to the second phase shifter; and a hybrid circuit having an input port coupled to the first filter, an isolated power coupled to the second filter, a first phase shift output coupled to the first receive path and a second phase shift output coupled to the first port. 11. The circuit of claim 9 , further comprising: a third RF front-end of a second band; a fourth RF front-end of the second band; a second RF switch configured to couple the third RF front-end to the first element of the first multi-feed antenna and couple the fourth RF front-end to the first element of the second multi-feed antenna in a third configuration, and configured to couple the third RF front-end to the first element of the second multi-feed antenna and couple the fourth RF front-end to the first element of the first multi-feed antenna in a fourth configuration; a first diplexer having inputs coupled to the first and second RF switches and an output coupled to the first element of the first multi-feed antenna; and a second diplexer having inputs coupled to the first and second RF switches and an output coupled to the first element of the second multi-feed antenna. 12. The circuit of claim 11 , wherein the third RF front-end comprises a third receive path, a third transmit path, a third frequency combiner configured to couple an input of the third receive path and an output of the third transmit path to a third port; the fourth RF front-end comprises a fourth receive path, a fourth transmit path, a fourth frequency combiner configured to: in a third mode, couple an input of the fourth receive path and an output of the fourth transmit path to a fourth port, and in a fourth mode, couple the input of the fourth receive path, the output of the fourth transmit path, and the third port of the second RF front-end to the fourth port, wherein the third port is coupled to a first input of the second RF switch and the fourth port is coupled to a second input of the second RF switch. 13. A method of operating a circuit including a first RF front-end of a first band; a second RF front-end of the first band; a first multi-feed antenna; and a second multi-feed antenna, the method comprising: coupling the first RF front-end to a first element of the first multi-feed antenna and coupling the second RF front-end to a first element of the second multi-feed antenna in a first configuration; coupling the first RF front-end to the first element of the second multi-feed antenna and coupling the second RF front-end to the first element of the first multi-feed antenna in a second configurat