Tunable magnonic crystal device and filtering method

What is claimed is: 1. A tunable magnonic crystal device, comprising: a spin wave waveguide; a magnonic crystal structure provided in or on the spin wave waveguide, the magnonic crystal structure being adapted for selectively filtering a spin wave spectral component of a spin wave propagating through the spin wave waveguide so as to provide a filtered spin wave; and a magneto-electric cell operably connected to the magnonic crystal structure, wherein the magneto-electric cell comprises an electrode for receiving a control voltage, and wherein adjusting the control voltage of the electrode controls a spectral parameter of the filtered spectral component of the spin wave via an interaction, dependent on the control voltage, between the magneto-electric cell and a magnetic property of the magnonic crystal structure. 2. The tunable magnonic crystal device of claim 1 , wherein the magneto-electric cell comprises a magnetostrictive layer and a piezoelectric layer, wherein adjusting the control voltage of the electrode adjusts an electric field in the piezoelectric layer thereby inducing a mechanical stress in the magnetostrictive layer, and wherein the induced mechanical stress in the magnetostrictive layer adjusts a magnetization of the magnetostrictive layer thereby adjusting the magnetic property of the magnonic crystal structure. 3. The tunable magnonic crystal device of claim 1 , wherein the spin wave waveguide comprises an elongate ferromagnetic or ferrite material on a substrate. 4. The tunable magnonic crystal device of claim 1 , wherein the spin wave waveguide is adapted for conducting the spin wave, and wherein the spin wave comprises at least a microwave frequency spectral component. 5. The tunable magnonic crystal device of claim 1 , wherein the magnonic crystal structure comprises a periodic structure formed by a periodic spatial variation of magnetic or geometrical properties. 6. The tunable magnonic crystal device of claim 5 , wherein the periodic spatial variation comprises a periodic variation of at least one of a saturation magnetization, a damping, a magnetocrystalline anisotropy, or a shape of the magnonic crystal structure. 7. The tunable magnonic crystal device of claim 1 , further comprising: an input transducer for converting an input signal into the spin wave, wherein the spin wave has substantially the same spectrum as the input signal; and an output transducer for converting the filtered spin wave into an output signal having substantially the same spectrum as the filtered spin wave. 8. The tunable magnonic crystal device of claim 7 , wherein at least one of the input transducer or the output transducer comprises a magneto-electric transducer or a co-planar waveguide antenna. 9. The tunable magnonic crystal device of claim 1 , further comprising a spin wave amplifier in or on the spin wave waveguide for amplifying the filtered spin wave. 10. The tunable magnonic crystal device of claim 9 , wherein the spin wave amplifier is configured to generate a spin transfer torque or a spin orbit torque on the spin wave waveguide. 11. The tunable magnonic crystal device of claim 10 , wherein the spin wave amplifier comprises a magnetic tunnel junction, and wherein the magnetic tunnel junction generates the spin transfer torque on the spin wave waveguide. 12. The tunable magnonic crystal device of claim 1 , further comprising: an output transducer for converting the filtered spin wave into an output signal having substantially the same spectrum as the filtered spin wave; and an electrical signal amplifier connected to the output transducer for amplifying the output signal in the electrical domain. 13. The tunable magnonic crystal device of claim 12 , further comprising a semiconductor substrate underneath at least one of the spin wave waveguide or the magnonic crystal structure, wherein the electrical signal amplifier comprises a sense amplifier integrated in the semiconductor substrate. 14. A method for selectively filtering a spectral component of a signal, the method comprising: providing the signal in the form of a spin wave; transmitting the spin wave through a magnonic crystal structure, thereby filtering a spin wave spectral component of the spin wave so as to provide a filtered spin wave; and applying a control voltage to a magneto-electric cell operably connected to the magnonic crystal structure in order to control a spectral parameter of the filtered spectral component of the spin wave via an interaction, dependent on the control voltage, between the magneto-electric cell and a magnetic property of the magnonic crystal structure. 15. The method of claim 14 , wherein providing the signal in the form of a spin wave comprises receiving a radio frequency electric or electromagnetic input signal and converting the received input signal into the spin wave, such that the spin wave has substantially the same spectrum as the received input signal. 16. The method of claim 14 , further comprising converting the filtered spin wave into an electric or electromagnetic output signal, such that the output signal has substantially the same spectrum as the filtered spin wave. 17. The method of claim 14 , wherein the magneto-electric cell comprises a magnetostrictive layer and a piezoelectric layer, and wherein applying the control voltage to the magneto-electric cell in order to control the spectral parameter of the filtered spectral component of the spin wave comprises: applying an electric field to the piezoelectric layer thereby inducing a mechanical stress in the magnetostrictive layer, wherein the induced mechanical stress in the magnetostrictive layer adjusts a magnetization of the magnetostrictive layer thereby adjusting the magnetic property of the magnonic crystal structure in order to control the spectral parameter of the filtered spectral component of the spin wave. 18. The method of claim 14 , further comprising transmitting the filtered spin wave through a spin wave amplifier in order to amplify the filtered spin wave. 19. The method of claim 14 , wherein transmitting the spin wave through the magnonic crystal structure comprises transmitting the spin wave through a periodic structure formed by a periodic spatial variation of magnetic or geometrical properties. 20. The method of claim 19 , wherein the periodic spatial variation comprises a periodic variation of at least one of a saturation magnetization, a damping, a magnetocrystalline anisotropy, or a shape of the magnonic crystal structure.