Abstract: A method and system for generating an optical frequency comb that employs a dual parallel modulator that inputs an optical signal at a center frequency of a desired optical frequency comb and an RF signal at a frequency corresponding to a desired spacing of the teeth of the optical frequency comb. The amplitudes of the teeth of the optical frequency comb are controlled by controlling the amplitudes of the two RF inputs to the DPM and the phase shift between the two RF inputs. In some embodiments, the three bias voltages for the three interferometers in the DPM are also controlled. In some embodiments, all three interferometers are all biased at the same point (e.g., quadrature). Preferably, but not necessarily, the three interferometers of the DPM are formed on a single substrate.

Abstract: A method and system for generating an optical frequency comb that employs a dual parallel modulator that inputs an optical signal at a center frequency of a desired optical frequency comb and an RF signal at a frequency corresponding to a desired spacing of the teeth of the optical frequency comb. The amplitudes of the teeth of the optical frequency comb are controlled by controlling the amplitudes of the two RF inputs to the DPM and the phase shift between the two RF inputs. In some embodiments, the three bias voltages for the three interferometers in the DPM are also controlled. In some embodiments, all three interferometers are all biased at the same point (e.g, quadrature). Preferably, but not necessarily, the three interferometers of the DPM are formed on a single substrate.

Abstract: The present invention relates to an optical modulator including an optical waveguide, and at least one CPW-to-CPS transition. The CPW segments include a hot electrode; and a ground plane disposed on each side of the hot electrode, and they share a ground plane. The CPS segment extends along an interaction length of the modulator. In one embodiment, two driving signals are applied so that the modulator operates as a dual-drive modulator. In another embodiment, a domain-inverted region is formed in a substrate of the dual-drive modulator to overlap with one arm of the optical waveguide (MZI) and invert a sign of a phase shift induced in that arm. Finally, a fixed chirp can be introduced into the dual-drive modulator by asymmetrically positioning the interferometer arms into gaps of the CPW segments with respect to the hot electrode, and by employing unequal width gaps in the CPW segments.

Abstract: A programmable chirp optical modulator is provided having programs modes of chirp. The modulator includes an optical modulation chip substrate having an electrooptic property; a waveguide that runs across the optical modulation chip, wherein the waveguide includes a first main channel branching into separate parallel first and second waveguide arms that combine into a second main channel; a first coplanar-strip electrode overlying and running along the first waveguide arm; a second electrode overlying and running along the second waveguide arm; and at least one programmable electrode overlying the substrate and adjacent to the second electrode on a side of the second coplanar-strip electrode opposite a side of the second coplanar-strip electrode where the first coplanar-strip electrode is located. The at least one programmable electrode runs in parallel with the second electrode as the second electrode runs along the second waveguide arm.

Abstract: The present invention relates to an optical modulator including an optical waveguide, and at least one CPW-to-CPS transition. The CPW segments include a hot electrode; and a ground plane disposed on each side of the hot electrode, and they share a ground plane. The CPS segment extends along an interaction length of the modulator. In one embodiment, two driving signals are applied so that the modulator operates as a dual-drive modulator. In another embodiment, a domain-inverted region is formed in a substrate of the dual-drive modulator to overlap with one arm of the optical waveguide (MZI) and invert a sign of a phase shift induced in that arm. Finally, a fixed chirp can be introduced into the dual-drive modulator by asymmetrically positioning the interferometer arms into gaps of the CPW segments with respect to the hot electrode, and by employing unequal width gaps in the CPW segments.

Abstract: An optical device includes a grounded base and an optical modulator chip having a top surface, a back surface and side surfaces. The optical modulator chip includes a first ground electrode, a signal electrode and a second ground electrode located over the top surface of the optical modulator chip. A resistive paint is on the back surface of the optical modulator chip to reduce losses due to extraneous modes or bias instabilities.

Abstract: An optical device includes a grounded base and an optical modulator chip having a top surface, a back surface and side surfaces. The optical modulator chip is positioned on the grounded base with the back surface facing the grounded base. The optical modulator chip includes a first ground electrode, a signal electrode and a second ground electrode located over the top surface of the optical modulator chip. The first and second ground electrodes of the optical modulator chip are interconnected with resistive layers on a surface of the optical modulator chip.

Abstract: A programmable chirp optical modulator is provided having programs modes of chirp. The modulator includes an optical modulation chip substrate having an electrooptic property; a waveguide that runs across the optical modulation chip, wherein the waveguide includes a first main channel branching into separate parallel first and second waveguide arms that combine into a second main channel; a first coplanar-strip electrode overlying and running along the first waveguide arm; a second electrode overlying and running along the second waveguide arm; and at least one programmable electrode overlying the substrate and adjacent to the second electrode on a side of the second coplanar-strip electrode opposite a side of the second coplanar-strip electrode where the first coplanar-strip electrode is located. The at least one programmable electrode runs in parallel with the second electrode as the second electrode runs along the second waveguide arm.

Abstract: Selective removal of materials from the substrate of an integrated electro-optical device prevents coupling to substrate modes. The selective removal may be accomplished by laser ablation, mechanical removal such as grinding, chemical etching agents, or combinations thereof. The strength of the substrate is maintained by not removing materials from areas where removal is not needed.

Abstract: An external resonant optical modulator is provided by forming a waveguide electrode structure coupled to a coplanar strip or coplanar waveguide pattern including a ring resonator electrode and a ground electrode substantially surrounding the ring resonator electrode. These electrode patterns are disposed on an electrooptic substrate that includes an optical waveguide pattern. The waveguide electrode structure includes an RF feed line electrode coupled to the ring electrode. The RF feed line signal excites an inherent resonant mode of the ring to thereby cause an electric field to resonate between the ring electrode and ground electrode and pass into sections of the optical waveguide pattern. By appropriately positioning the ring and ground electrodes to overlay portions of the optical waveguide structure in the electrooptic substrate, a light beam launched into the waveguide pattern can be modulated to produce a pulse with zero chirp.

Abstract: An optical modulation system for externally modulating two independent optical signals with first, second, third and fourth electrical input signals with two modulators. The system includes a first modulator with a first electrode receiving the first electrical input signal, a second electrode receiving the second electrical input signal, a first optical signal path co-propagating the first optical input signal with the first electrical signal and counter-propagating the second optical input signal to generate a first modulated optical signal, and a second optical signal path co-propagating the second optical input signal with the second electrical input signal and counter-propagating the first optical input signal to generate a second modulated optical signal.

Abstract: An optical device includes a grounded base and an optical modulator chip having a top surface, a back surface and side surfaces. The optical modulator chip includes a first ground electrode, a signal electrode and a second ground electrode located over the top surface of the optical modulator chip. A resistive paint is on the back surface of the optical modulator chip to reduce losses due to extraneous modes or bias instabilities.

Abstract: An external resonant optical modulator is provided by forming a waveguide electrode structure coupled to a coplanar strip or coplanar waveguide pattern including a ring resonator electrode and a ground electrode substantially surrounding the ring resonator electrode. These electrode patterns are disposed on an electrooptic substrate that includes an optical waveguide pattern. The waveguide electrode structure includes an RF feed line electrode coupled to the ring electrode. The RF feed line signal excites an inherent resonant mode of the ring to thereby cause an electric field to resonate between the ring electrode and ground electrode and pass into sections of the optical waveguide pattern. By appropriately positioning the ring and ground electrodes to overlay portions of the optical waveguide structure in the electrooptic substrate, a light beam launched into the waveguide pattern can be modulated to produce a pulse with zero chirp.

Abstract: An optical modulator device that substantially prevents coupling of a desired coplanar waveguide (CPW) electromagnetic wave mode with other spurious modes within non-active sections the modulator structure without significantly impacting the modulation efficiency in an active section of the device. The modulator includes an electrooptic substrate and a buffer layer that is formed on a surface of the electrooptic substrate. The buffer layer includes a thin portion that occupies an active section of the electrooptic substrate where modulation occurs, and a thicker portion that overlies the electrooptic substrate in one or more non-active sections of the device. The thinner portion of the buffer layer allows significant electrical-optical overlap of the CPW electromagnetic wave with an optical wave propagating within a waveguide formed in the active section of the device substrate.

Abstract: An optical device includes a grounded base and an optical modulator chip having a top surface, a back surface and side surfaces. The optical modulator chip is positioned on the grounded base with the back surface facing the grounded base. The optical modulator chip includes a first ground electrode, a signal electrode and a second ground electrode located over the top surface of the optical modulator chip. The first and second ground electrodes of the optical modulator chip are interconnected on a surface of the optical modulator chip.

Abstract: An optical device includes a grounded base and an optical modulator chip having a top surface, a back surface and side surfaces. The optical modulator chip is positioned on the grounded base with the back surface facing the grounded base. The optical modulator chip includes a first ground electrode, a signal electrode and a second ground electrode located over the top surface of the optical modulator chip. The first and second ground electrodes of the optical modulator chip are interconnected on a surface of the optical modulator chip.

Abstract: An optical modulation system for externally modulating two independent optical signals with first, second, third and fourth electrical input signals with two modulators. The system includes a first modulator with a first electrode receiving the first electrical input signal, a second electrode receiving the second electrical input signal, a first optical signal path co-propagating the first optical input signal with the first electrical signal and counter-propagating the second optical input signal to generate a first modulated optical signal, and a second optical signal path co-propagating the second optical input signal with the second electrical input signal and counter-propagating the first optical input signal to generate a second modulated optical signal.

Abstract: An optical device includes a grounded base and an optical modulator chip having a top surface, a back surface and side surfaces. The optical modulator chip is positioned on the grounded base with the back surface facing the grounded base. The optical modulator chip includes a first ground electrode, a signal electrode and a second ground electrode located over the top surface of the optical modulator chip. The first and second ground electrodes of the optical modulator chip are interconnected with resistive layers on a surface of the optical modulator chip.

Abstract: A Mach-Zehnder interferometer-type modulator for externally modulating two independent optical signals with first and second electrical signals, the modulator includes a first electrode receiving the first electrical signal, a second electrode receiving the second electrical signal, a first optical signal path co-propagating the first optical signal with the first electrical signal and counter-propagating the first optical signal with the second electrical signal, to generate a first modulated optical signal corresponding to the first optical signal modulated with the first electrical signal, and a second optical signal path co-propagating the second optical signal with the second electrical signal and counter-propagating the second optical signal with the second electrical signal, to generate a second modulated optical signal corresponding to the second optical signal modulated with the second electrical signal.

Abstract: A resonantly enhanced external electro-optic modulator reduces required drive power. The modulator has a coupling structure that efficiently couples power from a feed line into the resonator and eliminates the need for a terminal impedance. The modulator can be driven by a RF signal that is designed to suppress Stimulated Brillouin Scattering (SBS) in a long haul, high power fiber optic link, such as that used to transmit analog CATV signals. The modulator can also be used to depolarize an optical signal. A ring resonator includes a portion located outside the active area of the modulator in order to provide a space-efficient structure. The ring resonator can include one or more coaxial cable portions that are tuned to provide resonance at one or more frequencies that are matched to the input RF drive signal.