Front-end module for carrier aggregation mode

The invention claimed is: 1. A front-end module comprising: an antenna terminal; a first switch having an input connected to the antenna terminal and a number of k outputs, wherein k is an integer equal or greater than 3; and a second switch having an input and a number of n outputs, n being an integer equal or greater than 2, wherein a first output of the first switch is directly connected to the input of the second switch via a bypass path, wherein a second output of the first switch is connected to the input of the second switch via at least one notch path comprising a notch, wherein a third output of the first switch is connected to at least one auxiliary signal path assigned to a band of an auxiliary communication system, wherein each of the n outputs of the second switch is connected to a main signal path assigned to a band of a main communication system respectively, wherein the notch comprises a resonator adapted to provide a high impedance element for a frequency assigned to the band of the auxiliary communication system, wherein the first and second switches are configured to set a single band operation mode and a carrier aggregation mode, and wherein, in the carrier aggregation mode, one of the main signal paths is coupled to the antenna terminal via the at least one notch path, and the at least one auxiliary signal path is coupled to the antenna terminal in parallel to the one of the main signal paths. 2. The front-end module of claim 1 , wherein the first and second switches are configured to select two or more different carrier aggregation modes, wherein in each of these two or more different carrier aggregation modes a respective one of the main signal paths is connected to the antenna terminal via the notch path comprising the notch and wherein the at least one auxiliary signal path is connected to the antenna terminal in parallel to the respective one of the main signal paths and the notch path. 3. The front-end module of claim 1 , wherein the first and second switches are configured to set a further carrier aggregation mode by connecting two further signal paths selected from the main signal paths and one of the auxiliary signal paths to the antenna terminal in parallel, each of the further signal paths comprising a phase shifter adapted to mutually provide an open state for a signal having a frequency within a band of another further signal path of the main signal paths. 4. The front-end module according to claim 1 , further comprising a second antenna terminal connectable to a series of second signal paths via a third switch, each second signal path assigned to operate in a high band having a frequency higher than the frequencies the main signal paths are assigned to. 5. The front-end module according to claim 1 , further comprising a fourth switch having an input connected to a fourth output of the first switch, the fourth switch comprising outputs each being connected to a respective one of third signal paths assigned to a band of a third communication system. 6. The front-end module according to claim 5 , wherein the at least one auxiliary signal paths, the main signal paths and the third signal paths comprises at least one of a bypass path, a duplexer, a filter, a transmission line or a phase shifter. 7. The front-end module according to claim 1 , wherein the first switch, the bypass path and the at least one notch path comprising the notch are integrated on a sub-module, wherein the second switch is integrated on at least a further sub-module, and wherein the sub-module and the further sub-module are mounted on or electrically connected to a main front-end module. 8. The front-end module according to one of claim 1 , wherein the resonator comprises a capacitance element connected in parallel with an inductance element. 9. The front-end module according of claim 8 , wherein the resonator is connected with a series transmission line. 10. The front-end module according to claim 1 , wherein the resonator comprises a capacitance element connected in series with an inductance element. 11. The front-end module according of claim 10 , wherein the resonator is connected with a series transmission line. 12. The front-end module according to claim 1 , wherein the resonator is coupled to a shunt inductance element. 13. The front-end module according to claim 1 , wherein each resonator in the at least one notch path is tuned at the frequency of the band of the auxiliary signal path or a third communication system that is active together with the at least one notch path in the carrier aggregation mode. 14. The front-end module according to claim 1 , further comprising a series of signal paths, frequencies thereof lying within the same decade and being connected to the first switch via respective throws, wherein the throws comprise transistors having an enhanced gate width for lower insertion loss and higher linearity with respect to standard throws used for signal paths assigned to out-of-band frequencies. 15. The front-end module according to claim 1 , wherein the first and second switches comprise throws comprising transistors having an enhanced gate width for a lower insertion loss and a higher linearity, and wherein, in an on-state of such a throw, two gates of enhanced gate widths are circuited in series for better isolation. 16. The front-end module according to claim 1 , wherein the front-end module has a substrate that is made of a laminate or a multilayer ceramic, and wherein capacitance elements and/or inductance elements of the resonator or a phase shifter are integrated within the substrate. 17. The front-end module according to claim 1 , wherein the main signal paths and the at least one auxiliary signal path that are coupled in parallel to the antenna terminal in the carrier aggregation mode comprise at least one of a notch and a phase shifter both adapted to mutually provide a high impedance for a signal within the band of the respective other signal path. 18. The front-end module according to claim 17 , further comprising enabling the carrier aggregation mode by coupling a transmit path in parallel to another signal path to the antenna terminal.