Terahertz waveguide switches

What is claimed is: 1. A waveguide integrated switch, comprising: an actuator comprising a switching body coupled to one or more waveguides, the actuator actuating the switching body to open or close transmission of an electromagnetic wave to the one or more waveguides and the one or more waveguides configured and dimensioned to guide the electromagnetic wave having a frequency in a range of 100 gigahertz (GHz) to 1000 terahertz (THz); and wherein the actuator is configured to position the switching body relative to the waveguides with an accuracy in a range of 1-10 nanometers. 2. The switch of claim 1 , further comprising a position measuring device coupled to the switching body, the position measuring device measuring the position of the switching body relative to the one more waveguides with nanometer resolution. 3. The switch of claim 1 , wherein the actuator comprises a piezoelectric motor. 4. The switch of claim 2 , wherein the position measuring device comprises an optical linear encoder optically coupled to the switching body or a stage of the motor physically attached to the switching body. 5. The switch of claim 2 , wherein the actuator comprises a MEMS device including the switching body and the position measuring device comprises a scale or ruler having nanometer scale graduations on the switching body. 6. The switch of claim 2 , further comprising a circuit coupled to the actuator, the circuit applying a voltage controlling a position of the switching body using a feedback comprising a measurement of the position relative to a target position obtained using the position measuring device. 7. The switch of claim 6 , wherein the circuit comprises a feedback circuit comprising a feedback loop obtaining the measurement. 8. The switch of claim 1 , further comprising: the switching body comprising a metal switching element; the actuator comprising a piezoelectric motor coupled to the metal switching element; a circuit coupled to the piezoelectric motor, the piezoelectric motor moving a position of the metal switching element between a first position and a second position in response to one or more voltage signals applied by the circuit to the piezoelectric motor, wherein: the first position couples the metal switching element to at least one of the waveguides comprising a first waveguide or a second waveguide, the second position de-couples the metal switching element from the at least one of the first waveguide or the second waveguide; and wherein: the first waveguide and the second waveguide are configured and dimensioned to guide the electromagnetic wave comprising the frequency in a range of 100 gigahertz (GHz) to 1000 terahertz (THz). 9. The switch of claim 8 , further comprising: a feedback circuit providing feedback to the circuit, the feedback comprising at least one of: an error in the position, or the position, comprising a measured position, with respect to a target position. 10. The switch of claim 9 , further comprising an optical linear encoder optically coupled to the switching element for measuring the measured position. 11. The switch of claim 8 , wherein: the metal switching element comprises a curved connector waveguide configured and dimensioned to guide the electromagnetic wave, the curved connector waveguide having an input and an output; and the piezoelectric motor moves the input and the output along a linear direction between: the first position, coupling the input to the first waveguide via a gap and the output to the second waveguide via the gap, so that the electromagnetic wave is transmitted from the first waveguide to the second waveguide via the curved connector waveguide, and the second position, de-coupling the input from the first waveguide and the output from the second waveguide. 12. The switch of claim 11 , wherein the curved connector waveguide comprises a U-shaped waveguide. 13. The switch of claim 11 , further comprising: a metal waveguide block comprising the first waveguide and the second waveguide, the metal waveguide block having a first metal surface comprising an electromagnetic bandgap surface surrounding a first opening spaced from a second opening along the linear direction, wherein: the first opening comprises a first input to, or a first output from, the first waveguide; and the second opening comprises a second input to, or a second output from, the second waveguide; the metal switching element comprising a metal piece comprising a second metal surface including the input separated from the output along the linear direction; an electrically insulating spacer spacing the first metal surface from the second metal surface so as to fix the gap, comprising an electrically insulating gap of less than 60 microns between the first metal surface and the second metal surface, at: the first position, wherein, in a first direction of the gap, the first opening is aligned with the input and the second opening is aligned with the output, and the second position, wherein, in the first direction, the input is mis-aligned with the first opening and the output is misaligned with the second opening; alignment pins fixing a third position of the metal switching element relative to the metal waveguide block, the third position in a second direction perpendicular to the linear direction between the first position and the second position; and fixing pins securing the metal switching element to the piezoelectric motor. 14. The switch of claim 12 , wherein the first position and the second position are positionable with 1 nanometer resolution. 15. A device comprising the switch of claim 1 , further comprising an antenna and a calibration waveguide coupled to a receiver via the switch, wherein the waveguides comprise a first waveguide and a second waveguide, the calibration waveguide comprises or is coupled to the first waveguide (or the second waveguide), and the antenna is coupled to the second waveguide (or the first waveguide). 16. A transceiver, receiver, transmitter, or spectrometer comprising the switch of claim 1 . 17. The switch of claim 1 , wherein the waveguides comprise rectangular waveguides having a cross sectional area in a range of 100-5000 microns by 100-5000 microns and the switching body comprises a connector waveguide having a length in a range of 5-10 mm. 18. The switch of claim 1 , wherein: the switching element comprises a curved connector waveguide configured and dimensioned to guide the electromagnetic wave, the curved connector waveguide having an input and an output; the waveguides comprise a first waveguide and a second waveguide; and the actuator moves the input and the output along a direction between: a first position, coupling the input to the first waveguide via a gap and the output to the second waveguide via the gap, so that the electromagnetic wave is transmitted from the first waveguide to the second waveguide via the curved connector waveguide, and a second position, de-coupling the input from the first waveguide and the output from the second waveguide. 19. The switch of claim 18 , wherein the actuator comprises a piezoelectric motor. 20. The switch of claim 18 , wherein the curved connector waveguide comprises a U-shaped waveguide. 21. A method of making a waveguide integrated switch, comprising: coupling a switching body to one or more waveguides using an actuator, the actuator actuating the switching body to open or close transmission of an electromagnetic wave to the one or more wavegui