Patents by Inventor Roelof Jansen
Roelof Jansen has filed for patents to protect the following inventions. This listing includes patent applications that are pending as well as patents that have already been granted by the United States Patent and Trademark Office (USPTO).
-
Patent number: 11822118Abstract: An integrated photonic device for wavelength division multiplexing comprises: a wavelength-splitting/combining component configured to be re-used for both splitting a single signal to be split, wherein the signal to be split comprises plural wavelengths, to plural split signals, wherein each of the plural split signals is related to a unique wavelength band, and combining plural signals to be combined, wherein each of the plural signals to be combined is related to a unique wavelength band, to a single combined signal, wherein the wavelength-splitting/combining component comprises at least one output channel for providing an output signal and at least one response channel for receiving a response input signal from a light interaction induced by the output signal, wherein the output channel and the response channel are connected to different ports of the wavelength-splitting/combining component.Type: GrantFiled: June 28, 2022Date of Patent: November 21, 2023Assignees: IMEC VZW, UNIVERSITEIT GENTInventors: Wim Bogaerts, Wouter Jan Westerveld, Roelof Jansen
-
Patent number: 11686682Abstract: There is provided a device (300;500;700) for collecting fluorescent light (322) emitted by particles (304) in a medium (302). The device (300;500;700) comprises a substrate (308) having a chamber (306) for holding the medium (302) including the particles (304) being capable of emitting fluorescent light (322). A first waveguide (310), which is arranged to receive and guide excitation light along a first direction (313), extends through the chamber (306). Fluorescent light (322) emitted by the particles (304) following an excitation is collected by the first waveguide (310). The device (300;500;700) further comprises a coupler (316;516) which includes a second waveguide (317) arranged to output collected fluorescent light (326) at one of its ends (318).Type: GrantFiled: December 12, 2017Date of Patent: June 27, 2023Assignee: miDiagnostics NVInventor: Roelof Jansen
-
Publication number: 20230194781Abstract: Example embodiments relate to multilevel coupling for phase front engineering. An example integrated optical structure for phase front engineering of optical beams includes a substrate. The integrated optical structure also includes a plurality of optical layers formed on the substrate. Each of the optical layers includes an optical phased array that includes a plurality of optical waveguides. Each of the optical layers also includes a coupling section for each of the optical waveguides. Each coupling section is configured to control the phase of an optical beam coupling out of the optical waveguide. Additionally, the integrated optical structure includes a slab waveguide formed on the substrate and between two of the optical layers. The slab waveguide is in optical communication with the coupling sections of the two optical layers. The slab waveguide includes a slab waveguide outcoupling structure.Type: ApplicationFiled: December 19, 2022Publication date: June 22, 2023Inventors: Bruno Figeys, Jon Kjellman, Roelof Jansen
-
Publication number: 20230003939Abstract: An integrated photonic device for wavelength division multiplexing comprises: a wavelength-splitting/combining component configured to be re-used for both splitting a single signal to be split, wherein the signal to be split comprises plural wavelengths, to plural split signals, wherein each of the plural split signals is related to a unique wavelength band, and combining plural signals to be combined, wherein each of the plural signals to be combined is related to a unique wavelength band, to a single combined signal, wherein the wavelength-splitting/combining component comprises at least one output channel for providing an output signal and at least one response channel for receiving a response input signal from a light interaction induced by the output signal, wherein the output channel and the response channel are connected to different ports of the wavelength-splitting/combining component.Type: ApplicationFiled: June 28, 2022Publication date: January 5, 2023Inventors: Wim BOGAERTS, Wouter Jan WESTERVELD, Roelof JANSEN
-
Patent number: 11408764Abstract: A sensor comprises: a thin structure, which is configured to receive a force for deforming a shape of the thin structure and which is arranged above a substrate; and a waveguide for guiding an electro-magnetic wave comprising: a first waveguide part; and a second waveguide part; wherein the second waveguide part has a larger width than the first waveguide part; and wherein the first and the second waveguide parts are spaced apart by a gap which is sufficiently small such that the first and second waveguide parts unitely form a single waveguide, wherein one of the first and the second waveguide part is arranged at least partly on the thin structure and another of the first and the second waveguide part is arranged on the substrate.Type: GrantFiled: December 4, 2019Date of Patent: August 9, 2022Assignees: IMEC VZW, KATHOLIEKE UNIVERSITEIT LEUVENInventors: Wouter Jan Westerveld, Veronique Rochus, Simone Severi, Roelof Jansen
-
Patent number: 11372158Abstract: A waveguide for guiding an electro-magnetic wave comprises: a first waveguide part; and a second waveguide part; wherein the first waveguide part has a first width in a first direction (Y) perpendicular to the direction of propagation of the electro-magnetic wave and the second waveguide part has a second width in the first direction (Y), wherein the second width is larger than the first width; and wherein the first and the second waveguide parts are spaced apart by a gap in a second direction (Z) perpendicular to the first and second planes in which the waveguide parts are formed, wherein the gap has a size which is sufficiently small such that the first and second waveguide parts unitely form a single waveguide for guiding the electro-magnetic wave. The waveguide may be used in numerous applications, such as in a photonic integrated circuit, in a sensor or in an actuator.Type: GrantFiled: December 4, 2019Date of Patent: June 28, 2022Assignees: IMEC VZW, KATHOLIEKE UNIVERSITEIT LEUVENInventors: Wouter Jan Westerveld, Veronique Rochus, Simone Severi, Roelof Jansen
-
Patent number: 11320303Abstract: Embodiments relate to a sensor structure for an acoustical pressure sensor and an opto-mechanical sensor and system that may be used for detecting acoustical pressure waves. Embodiments of a sensor structure for an acoustical pressure sensor include an optical waveguide closed-loop resonator and a plurality of sensor elements. The individual sensor elements of the plurality of sensor elements are configured to be affected by an acoustical pressure wave such that a physical property of the individual sensor element is changed. The optical waveguide closed-loop resonator is arranged at the plurality of sensor elements and associated with each of the individual sensor elements such that a resonance frequency of the optical waveguide closed-loop resonator is shifted due to the affected physical properties of all individual sensor elements. The sensor structure provides a high sensitivity from each sensor element, which is advantageous in e.g.Type: GrantFiled: April 3, 2020Date of Patent: May 3, 2022Assignees: IMEC VZW, KATHOLIEKE UNIVERSITEIT LEUVENInventors: Wouter Jan Westerveld, Roelof Jansen, Xavier Rottenberg, Veronique Rochus
-
Publication number: 20220082696Abstract: A system for determining a range of a scene is provided. In one aspect, the system includes an optical source to generate an input signal and a first optical coupler to tap a predetermined portion of the input signal as a local oscillator signal. The system includes an emitting unit to transmit a remaining portion of the input signal as an output signal onto the scene, and an imaging unit to receive return signals from the scene. The imaging unit includes an array of detectors directly coupled to one or more lenses. A position of each detector is associated with a unique direction of the return signals. Also, the lenses may receive and direct the return signals onto the detectors. Further, each detector of the array is configured to mix the local oscillator signal with a corresponding return signal thereby generating a RF beat signal that is further processed to determine the range of the scene.Type: ApplicationFiled: September 15, 2021Publication date: March 17, 2022Inventors: Jon Kjellman, Marcus Dahlem, Xavier Rottenberg, Roelof Jansen
-
Patent number: 11156780Abstract: There is provided an optical system comprising a photonic integrated circuit which is integrated on a platform and an element having a first surface being attached to the platform. The element has a groove in the first surface, and the groove is filled with a medium having a refractive index which is different from that of the element. The groove has a surface with a normal that forms an angle with respect to a predetermined light direction, thereby allowing changing a direction of light which is incident on the platform along the predetermined light direction. The element and the medium filling the groove are transparent for a wavelength range of the light which is incident on the platform.Type: GrantFiled: June 20, 2018Date of Patent: October 26, 2021Assignee: miDiagnostics NVInventors: Jeonghwan Song, Roelof Jansen, Xavier Rottenberg, Gil Linenberg, Kirill Zinoviev
-
Publication number: 20210063840Abstract: A phase difference measurement device comprises at least two optical waveguides arranged in parallel in a first plane. Each optical waveguide comprises a proximal portion and a distal portion. The proximal portion of at least one of the optical waveguides comprises a phase-shifting device configured to induce a phase shift of a light wave being transmitted in the phase difference measurement device. The device further comprises at least one phase interrogator device arranged in the first plane between two neighboring optical waveguides of the optical waveguides. The phase interrogator device is configured to couple light from the two neighboring optical waveguides to interfere in the phase interrogator to generate an interference light wave. At least one photodetector is arranged for detecting the interference light wave. The photodetector is arranged in a second plane other than the first plane.Type: ApplicationFiled: August 20, 2020Publication date: March 4, 2021Inventors: Bruno Figeys, Jon Kjellman, Xavier Rottenberg, Roelof Jansen
-
Patent number: 10921125Abstract: An optical gyroscope and a method for measuring an angular velocity of rotation are described. A closed-path optical cavity is configured for receiving at least a first optical signal circulating as at least one cavity mode of pre-determined orientation (inside the optical cavity. An extractor in optical communication with the optical cavity is configured for extracting a fraction of at least the circulating first optical signal from the optical cavity, wherein an amplitude of the extracted fraction increases when a resonance condition for the optical cavity in optical communication with the extractor is approached. A readout channel included in the optical gyroscope comprises an interferometric device adapted to spectrally modify the extracted fraction so as to produce a spectral Vernier effect. A difference between free spectral ranges of the interferometric device and the optical cavity is larger than the associated spectral widths.Type: GrantFiled: November 21, 2019Date of Patent: February 16, 2021Assignee: IMEC VZWInventors: Veronique Rochus, Roelof Jansen, Benedetto Troia
-
Publication number: 20200371030Abstract: There is provided a device (300;500;700) for collecting fluorescent light (322) emitted by particles (304) in a medium (302). The device (300;500;700) comprises a substrate (308) having a chamber (306) for holding the medium (302) including the particles (304) being capable of emitting fluorescent light (322). A first waveguide (310), which is is arranged to receive and guide excitation light along a first direction (313), extends through the chamber (306). Fluorescent light (322) emitted by the particles (304) following an excitation is collected by the first waveguide (310). The device (300;500;700) further comprises a coupler (316;516) which includes a second waveguide (317) arranged to output collected fluorescent light (326) at one of its ends (318).Type: ApplicationFiled: December 12, 2017Publication date: November 26, 2020Inventor: Roelof JANSEN
-
Publication number: 20200319019Abstract: A sensor structure for an acoustical pressure sensor. The structure comprises an optical waveguide closed-loop resonator and a plurality of sensor elements, wherein the individual sensor elements of the plurality of sensor elements are configured to be affected by an acoustical pressure wave such that a physical property of the individual sensor element is changed. Further, the optical waveguide closed-loop resonator is arranged at said plurality of sensor elements and associated with each of the individual sensor elements of the plurality of sensor elements such that a resonance frequency of the optical waveguide closed-loop resonator is shifted due to the affected physical properties of all individual sensor elements of the plurality of sensor elements.Type: ApplicationFiled: April 3, 2020Publication date: October 8, 2020Inventors: Wouter Jan WESTERVELD, Roelof JANSEN, Xavier ROTTENBERG, Veronique ROCHUS
-
Patent number: 10775254Abstract: A force sensing device comprises: a membrane (120), which is configured to deform upon receiving a force; a first Mach Zehnder-type interferometer device (110); a second Mach Zehnder-type interferometer device (130), wherein a first measurement propagation path (114) of the first Mach Zehnder-type interferometer device (110) and a second measurement propagation path (134) of the second Mach Zehnder-type interferometer device (130) are arranged on or in the membrane (120), and wherein the first measurement propagation path (114) and the second measurement propagation path (134) are differently sensitive to applied force on the membrane (120).Type: GrantFiled: June 12, 2018Date of Patent: September 15, 2020Assignee: IMEC VZWInventors: Roelof Jansen, Xavier Rottenberg, Veronique Rochus
-
Publication number: 20200173843Abstract: A sensor comprises: a thin structure, which is configured to receive a force for deforming a shape of the thin structure and which is arranged above a substrate; and a waveguide for guiding an electro-magnetic wave comprising: a first waveguide part; and a second waveguide part; wherein the second waveguide part has a larger width than the first waveguide part; and wherein the first and the second waveguide parts are spaced apart by a gap which is sufficiently small such that the first and second waveguide parts unitely form a single waveguide, wherein one of the first and the second waveguide part is arranged at least partly on the thin structure and another of the first and the second waveguide part is arranged on the substrate.Type: ApplicationFiled: December 4, 2019Publication date: June 4, 2020Inventors: Wouter Jan WESTERVELD, Veronique ROCHUS, Simone SEVERI, Roelof JANSEN
-
Publication number: 20200174186Abstract: A waveguide for guiding an electro-magnetic wave comprises: a first waveguide part; and a second waveguide part; wherein the first waveguide part has a first width in a first direction (Y) perpendicular to the direction of propagation of the electro-magnetic wave and the second waveguide part has a second width in the first direction (Y), wherein the second width is larger than the first width; and wherein the first and the second waveguide parts are spaced apart by a gap in a second direction (Z) perpendicular to the first and second planes in which the waveguide parts are formed, wherein the gap has a size which is sufficiently small such that the first and second waveguide parts unitely form a single waveguide for guiding the electro-magnetic wave. A photonic integrated circuit component, a sensor and an actuator comprising the waveguide are disclosed.Type: ApplicationFiled: December 4, 2019Publication date: June 4, 2020Inventors: Wouter Jan WESTERVELD, Veronique ROCHUS, Simone SEVERI, Roelof JANSEN
-
Publication number: 20200158506Abstract: An optical gyroscope and a method for measuring an angular velocity of rotation are described. A closed-path optical cavity is configured for receiving at least a first optical signal circulating as at least one cavity mode of pre-determined orientation (inside the optical cavity. An extractor in optical communication with the optical cavity is configured for extracting a fraction of at least the circulating first optical signal from the optical cavity, wherein an amplitude of the extracted fraction increases when a resonance condition for the optical cavity in optical communication with the extractor is approached. A readout channel included in the optical gyroscope comprises an interferometric device adapted to spectrally modify the extracted fraction so as to produce a spectral Vernier effect. A difference between free spectral ranges of the interferometric device and the optical cavity is larger than the associated spectral widths.Type: ApplicationFiled: November 21, 2019Publication date: May 21, 2020Inventors: Veronique Rochus, Roelof Jansen, Benedetto Troia
-
Patent number: 10520677Abstract: An integrated photonic device comprises: an input waveguide configured to extend in an input plane, and an output waveguide configured to extend in an output plane, wherein the output plane is parallel to or contained within the input plane; an input coupler optically coupled to the input waveguide, wherein the input coupler is configured to redirect a light signal out of the input waveguide and the input plane; a light property modifier configured to receive the light signal from the input coupler and reflect the light signal towards the output plane, wherein the light property modifier is configured to selectively adjust an optical path length of the light signal; and an output coupler optically coupled to the output waveguide, wherein the output coupler is configured to receive the reflected light signal from the light property modifier and redirect the light signal into the output waveguide and the output plane.Type: GrantFiled: December 22, 2018Date of Patent: December 31, 2019Assignee: IMEC VZWInventors: Bruno Figeys, Veronique Rochus, Roelof Jansen, Xavier Rottenberg
-
Publication number: 20190196111Abstract: An integrated photonic device comprises: an input waveguide configured to extend in an input plane, and an output waveguide configured to extend in an output plane, wherein the output plane is parallel to or contained within the input plane; an input coupler optically coupled to the input waveguide, wherein the input coupler is configured to redirect a light signal out of the input waveguide and the input plane; a light property modifier configured to receive the light signal from the input coupler and reflect the light signal towards the output plane, wherein the light property modifier is configured to selectively adjust an optical path length of the light signal; and an output coupler optically coupled to the output waveguide, wherein the output coupler is configured to receive the reflected light signal from the light property modifier and redirect the light signal into the output waveguide and the output plane.Type: ApplicationFiled: December 22, 2018Publication date: June 27, 2019Inventors: Bruno FIGEYS, Veronique ROCHUS, Roelof JANSEN, Xavier ROTTENBERG
-
Patent number: 10215924Abstract: An example embodiment may include an optical system for obtaining radiation coupling between two waveguides positioned in a non-coplanar configuration. The optical system may include a first waveguide positioned in a first plane and a second waveguide positioned in a second plane. The first waveguide may be stacked over the second waveguide at a distance adapted to allow evanescent coupling between the first waveguide and the second waveguide. The first waveguide and the second waveguide may be configured such that the coupling is at least partly tolerant to relative translation or rotation of the first waveguide and the second waveguide with respect to each other.Type: GrantFiled: December 21, 2017Date of Patent: February 26, 2019Assignee: IMEC VZWInventors: Roelof Jansen, Xavier Rottenberg