Architectures having bridge combiners and multiplexers

1 . A radio-frequency architecture comprising: a first group of filters each configured to support a band such that a first frequency range covers the respective bands, and a second group of one or more filters each configured to support a band such that a second frequency range covers the respective one or more bands, each filter of the first group configured to provide an impedance at or near a short circuit impedance for a signal in each band of the second group, each filter of the second group configured to provide an impedance at or near a short circuit impedance for a signal in each band of the first group, the filters of the first and second groups implemented as one or more multiplexers; and a coupling circuit including a common node and configured to couple the common node to the one or more multiplexers through a first path and a second path, the coupling circuit further configured such that the impedance provided by each filter of the first group for the signal in each band of the second group results in the signal being sufficiently excluded from the first path, and such that the impedance provided by each filter of the second group for the signal in each band of the first group results in the signal being sufficiently excluded from the second path. 2 . The radio-frequency architecture of claim 1 wherein the one or more multiplexers includes a multiplexer that includes the first group of filters but not the second group of one or more filters. 3 . The radio-frequency architecture of claim 1 wherein the one or more multiplexers includes a multiplexer that includes the first group of filters and the second group of one or more filters. 4 . The radio-frequency architecture of claim 1 wherein the first path presents a first impedance Z 1 to the coupling circuit, and the second path presents a second impedance Z 2 to the coupling circuit, such that complex part of Z 1 is a conjugate of complex part of Z 1 . 5 . The radio-frequency architecture of claim 4 wherein the first impedance Z 1 is one of a capacitive impedance and an inductive impedance, and the second impedance Z 2 is the other of the capacitive impedance and the inductive impedance. 6 . The radio-frequency architecture of claim 4 wherein the complex part of Z 1 is approximately zero, and the complex part of Z 2 is approximately zero. 7 . The radio-frequency architecture of claim 4 wherein at least some of the filters of the first group and the second group are configured to provide the first impedance Z 1 for the first path and the second impedance Z 2 for the second path. 8 . The radio-frequency architecture of claim 7 wherein all of the filters of the first group and the second group are configured to provide the first impedance Z 1 for the first path and the second impedance Z 2 for the second path. 9 . The radio-frequency architecture of claim 1 wherein each of the first and second paths includes a phase shifter. 10 . The radio-frequency architecture of claim 9 further comprising a third group of one or more filters each configured to support a band such that a third frequency range covers the respective one or more bands, the phase shifters of the first and second paths configured to reduce mutual loading between each filter of the third group and each filter of either or both of the first and second groups. 11 . The radio-frequency architecture of claim 10 wherein the plurality bands supported by the first group are low frequency bands, the one or more bands supported by the second group is/are high frequency band(s), and the one or more bands supported by the third group is/are mid frequency band(s). 12 . The radio-frequency architecture of claim 1 further comprising a third group of one or more filters each configured to support a band such that a third frequency range covers the respective one or more bands, each filter of the third group configured to provide an impedance at or near a short circuit impedance for a signal in each band of the first and second groups, each filter of the first and second groups further configured to provide an impedance at or near a short circuit impedance for a signal in each band of the third group. 13 . The radio-frequency architecture of claim 12 further comprising another coupling circuit including a common node and configured to couple its common node to the common node of the coupling circuit through a third path and to couple its common node to the third group through a fourth path, the other coupling circuit further configured such that the impedance provided by each filter of the first and second groups for the signal in each band of the third group results in the signal being sufficiently excluded from the third path, and such that the impedance provided by each filter of the third group for the signal in each band of the first and second groups results in the signal being sufficiently excluded from the fourth path. 14 . (canceled) 15 . The radio-frequency architecture of claim 13 wherein the plurality bands supported by the first group are low frequency bands, the one or more bands supported by the second group is/are mid frequency band(s), and the one or more bands supported by the third group is/are high frequency band(s). 16 . The radio-frequency architecture of claim 1 wherein the coupling circuit includes a resonator. 17 . The radio-frequency architecture of claim 16 wherein the coupling circuit includes a first circuit and a second circuit that couple the common node to ground in a parallel manner, the first circuit including a first inductance L 1 and the resonator in series, the second circuit including a capacitance C and a second inductance in series. 18 . The radio-frequency architecture of claim 1 wherein the coupling circuit includes a first LC circuit and a second LC circuit that couple the common node to ground in a parallel manner, the first LC circuit including a first inductance L 1 and a first capacitance C 1 in series, the second LC circuit including a second capacitance C 2 and a second inductance L 2 in series. 19 . The radio-frequency architecture of claim 18 wherein the first path is coupled to the coupling circuit at a node between L 1 and C 1 , and the second path is coupled to the coupling circuit at a node between C 2 and L 2 . 20 . A packaged module comprising: a packaging substrate configured to receive a plurality of components; and a radio-frequency circuit implemented on the packaging substrate and including a first group of filters each configured to support a band such that a first frequency range covers the respective bands, and a second group of one or more filters each configured to support a band such that a second frequency range covers the respective one or more bands, each filter of the first group configured to provide an impedance at or near a short circuit impedance for a signal in each band of the second group, each filter of the second group configured to provide an impedance at or near a short circuit impedance for a signal in each band of the first group, the filters of the first and second groups implemented as one or more multiplexers, the radio-frequency circuit further including a coupling circuit having a common node and configured to couple the common node to the one or more multiplexers through a first path and a second path, the coupling circuit further configured such that the impedance provided by each filter of the first group for the signal in each band of the second group results in the signal being s