Radio frequency architectures and methods providing switchable bypass and pass-through paths

What is claimed is: 1. A method for selecting a path in a radio-frequency (RF) architecture, the method comprising: generating a command indicating a bypass mode or a pass-through mode; issuing a switching signal to a first switch, to a second switch, and to a third switch based on the generated command, the second switch including a single-pole-single-throw switch (SPST), the third switch connected in parallel with the second switch, the third switch coupled to a second output of an RF component and to a second signal output port to form a second pass-through path; in the pass-through mode indicated by the generated command, forming a pass-through path by connecting a pole of the first switch to a pass-through throw of the first switch and connecting a pole of the second switch to an output throw of the second switch such that the pass-through path passes through the first switch to an input of the RF component and from an output of the RF component to a signal output port through the second switch; and in the bypass mode indicated by the generated command, forming a bypass path by connecting the pole of the first switch to a bypass throw of the first switch and disconnecting the pole of the second switch from the output throw of the second switch such that the bypass path passes through the first switch to the signal output port and bypasses the RF component. 2. The method of claim 1 wherein the RF component includes a filter. 3. The method of claim 1 wherein the first switch includes a single-pole-multiple-throw switch (SPMT). 4. The method of claim 1 wherein the first switch includes multiple throws and the multiple throws of the first switch includes a plurality of pass-through throws and at least one bypass throw. 5. The method of claim 1 further comprising, in the pass-through mode, connecting a pole of the third switch to an output throw of the third switch such that the second pass-through path passes through the first switch to the input of the RF component and from the second output of the RF component to the second signal output port through the third switch. 6. The method of claim 1 wherein the RF component includes a diplexer. 7. The method of claim 1 wherein the RF component includes a multiplexer. 8. A radio-frequency (RF) device comprising: a transceiver configured to process RF signals; an antenna in communication with the transceiver to facilitate transmission and reception of the RF signals; and a packaged module having a multiplexer having an input node and at least two output nodes and a switching network implemented between the transceiver and the antenna and configured to route the RF signals, the switching network including a first single-pole-multiple-throw (SPMT) switch that does not include any throws coupled to a bypass path, the switching network also including a second SPMT switch having a pass-through throw coupled to the input node of the multiplexer and at least two bypass throws, each bypass throw coupled to a respective bypass path, a pole coupled to a throw of the first SPMT switch, the switching network also including a first output switch having a bypass throw coupled to a corresponding bypass throw of the second SPMT switch and a pass-through throw coupled to a first output node of the multiplexer, the switching network also including a second output switch having a bypass throw coupled to a corresponding bypass throw of the second SPMT switch and a pass-through throw coupled to a second output node of the multiplexer. 9. The RF device of claim 8 wherein the switching network is implemented on a semiconductor die. 10. The RF device of claim 9 wherein the switching network is based on a network of field-effect transistors using silicon-on-insulator process technology. 11. The RF device of claim 9 wherein the switching network is based on a network of pseudomorphic high-electron-mobility transistors (pHEMTs) implemented with gallium arsenide (GaAs) process technology. 12. The RF device of claim 9 wherein the switching network is interconnected to the multiplexer using conductive paths from the semiconductor die to the multiplexer. 13. The RF device of claim 9 further comprising an overmold structure formed over the semiconductor die. 14. The RF device of claim 8 wherein the packaged module includes a packaging substrate.