Low-loss waveguiding structures, in particular modulators

We claim: 1. An optical modulator comprising: an input port for launching a beam of light; a first waveguide arm for transmitting at least a first portion of the beam of light, the first waveguide arm comprising first single mode waveguide sections and a first multimode waveguide section; a first set of electrodes for modulating the beam of light; an output port for outputting a modulated output beam of light; and adiabatic tapers for expanding one of the first single mode waveguide sections into the first multimode waveguide section, while maintaining the beam of light in fundamental TE or TM modes, and for tapering the first multimode waveguide section down to another one of the first single mode waveguide sections, wherein at least a portion of the first multimode waveguide section is disposed adjacent to the first set of electrodes. 2. An optical modulator comprising: an input port for launching a beam of light a first waveguide arm for transmitting at least a first portion of the beam of light a first set of electrodes for modulating the beam of light an output port for outputting a modulated output beam of light wherein the first waveguide arm comprises first single mode waveguide sections and a first multimode waveguide section, wherein at least a portion of the first multimode waveguide section is disposed adjacent to the first set of electrodes, and wherein the first waveguide arm further comprises a second multimode waveguide section coupled to the first multimode waveguide section by at least one first single mode waveguide section; and further comprising a second set of electrodes adjacent to at least a portion of the second multimode waveguide section. 3. The optical modulator according to claim 2 , wherein the at least one first single mode waveguide section comprises a single-mode waveguide bend in the first waveguide arm between the first multimode waveguide section and the second multimode waveguide section. 4. The optical modulator according to claim 3 , wherein the single-mode waveguide bend comprises a substantially 180° bend. 5. The optical modulator according to claim 3 , wherein the single-mode waveguide bend comprises a substantially 180° Euler bend. 6. The optical modulator according to claim 1 , wherein the first single mode waveguide sections and the first multimode waveguide section comprises an electro-optic material with an electro-optic constant>10 pm/V. 7. The optical modulator according to claim 1 , wherein the first single mode waveguide sections and the first multimode waveguide sections comprise Lithium Niobate or Lithium Tantalate. 8. The optical modulator according to claim 1 , wherein the first single mode waveguide sections comprise a cross sectional area<3 μm 2 . 9. The optical modulator according to claim 1 , wherein the first single mode waveguide sections comprise a cross sectional area<1 μm 2 . 10. The optical modulator according to claim 1 , where the first multimode waveguide section comprise a cross sectional area>0.2 μm 2 and <10 μm 2 . 11. An optical modulator comprising: an input port for launching a beam of light a first waveguide arm for transmitting at least a first portion of the beam of light a first set of electrodes for modulating the beam of light an output port for outputting a modulated output beam of light wherein the first waveguide arm comprises first single mode waveguide sections and a first multimode waveguide section, wherein at least a portion of the first multimode waveguide section is disposed adjacent to the first set of electrodes, and wherein the first single mode waveguide sections are configured to only support one TE mode and one TM mode with optical propagation loss<0.6 dB/cm, and optical propagation loss >1dB/cm for higher modes. 12. An optical modulator comprising: an input port for launching a beam of light a first waveguide arm for transmitting at least a first portion of the beam of light a first set of electrodes for modulating the beam of light an output port for outputting a modulated output beam of light wherein the first waveguide arm comprises first single mode waveguide sections and a first multimode waveguide section, wherein at least a portion of the first multimode waveguide section is disposed adjacent to the first set of electrodes, and wherein the first multimode waveguide section supports more than one TE mode and more than one TM mode with optical propagation loss<0.6 dB/cm for both TE and TM modes. 13. The optical modulator according to claim 1 , further comprising: a splitter configured to split the beam of light into a first sub-beam and a second sub-beam; a second waveguide arm coupled to the splitter for transmitting the second sub-beam, wherein the first waveguide arm is coupled to the splitter for transmitting the first sub-beam; and a combiner configured for combining the first sub-beam and the second sub-beam to form the modulated output beam; wherein the second waveguide arm comprises second single mode waveguide sections and a second multimode waveguide section; and wherein at least a portion of the second multimode waveguide section is disposed adjacent to the first set of electrodes. 14. The optical modulator according to claim 13 , wherein the first waveguide arm includes a third multimode waveguide section, and a first single mode waveguide bend between the first multimode waveguide section and the third multimode waveguide section; and wherein the second waveguide arm includes a fourth multimode waveguide section, and a second single mode waveguide bend between the second multimode waveguide section and the fourth multimode waveguide section. 15. The optical modulator according to claim 14 , further comprising: a second set of electrodes adjacent to at least a portion of the third multimode waveguide section and a portion of the fourth multimode waveguide section. 16. An optical modulator comprising: an input port for launching a beam of light a first waveguide arm for transmitting at least a first portion of the beam of light a first set of electrodes for modulating the beam of light an output port for outputting a modulated output beam of light a bus waveguide optically coupled to the input port at one end and to the output port at an opposite end; and a coupler configured to split the beam of light into a first sub-beam and a second sub-beam; wherein the first waveguide arm comprises first single mode waveguide sections and a first multimode waveguide section; wherein at least a portion of the first multimode waveguide section is disposed adjacent to the first set of electrodes; wherein the first waveguide arm comprises a ring resonator coupled to the coupler for transmitting the first sub-beam, and recombining the first sub-beam back into the bus waveguide; wherein the ring resonator includes curved sections and substantially straight or less curved sections; wherein at least a portion of some of the curved sections comprise the first single mode waveguide sections; and wherein one of the substantially straight or less curved sections comprise the first multimode waveguide section. 17. The optical modulator according to claim 16 , wherein another one of the substantially straight or less curved sections comprises a second multimode waveguide section disposed adjacent to the first set of electrodes. 18. The optical modulator according to claim 16 , further comprising adiabatic tapers for expanding one of the first single mode waveguide sections into the first multimode wa