Patents by Inventor Alan Liu
Alan Liu 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).
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Publication number: 20260135353Abstract: The present disclosure is directed to light-distribution systems on photonic integrated circuits (PIC) that split and amplify a light signal received from at least one remotely located laser into a plurality of amplified light signals, where amplification is provided by an integrated semiconductor optical amplifier (SOA). By locating the laser remotely with respect to the SOA-based PIC, the laser and PIC can be subjected to different ambient environmental conditions. Additionally, a lower-power laser can be used since the optical loss associated with splitting is compensated for by the amplification. As a result, lower current densities and optical powers can be used in both the source laser and the SOA. In some embodiments, the sequence of power splitting and amplification is repeated multiple times, thereby enabling system to scale gracefully.Type: ApplicationFiled: January 7, 2026Publication date: May 14, 2026Inventors: Brian KOCH, Alan LIU, Daniel Knight SPARACIN
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Patent number: 12626200Abstract: An electric vehicle (EV) charge management system is configured to monitor, manage, and optimize EV charging processes. The system can continuously monitor charge-related data from various sources, including the EVs themselves, charging infrastructure providers, schedule data, and/or other relevant systems, to identify charging issues in real-time. Users can define customized charge profiles for each EV or groups of EVs, such as target charge levels (e.g., 80%), low charge levels (e.g., 20%), charging schedules, maximum charging rates, and/or other criteria that are indicative of a potential charging issue. These charge profiles allow users to have greater control over the charging process, ensuring that their EVs are charged in a way that reduces fleet downtime (e.g., charging time in the middle of a driver's shift) and optimizes productivity of the fleet.Type: GrantFiled: April 19, 2024Date of Patent: May 12, 2026Assignee: Samsara Inc.Inventors: Alan Liu, Fatma Kevser Akcay, Andrii Sliusar, Paolo Caminiti, Andrea Harpprecht, Joe Downard, Deepti Yenireddy, Ethan Wood
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Patent number: 12549259Abstract: The present disclosure is directed toward architectures that combine DWDM and CWDM concepts in a single PIC. Transmitter stages in accordance with the present disclosure include a plurality of multiwavelength lasers having regions of separately grown epitaxial material whose gain peaks are centered at different wavelengths. Each laser launches a wavelength comb comprising a plurality of wavelength signals into a PLC, where the wavelengths within each wavelength comb are separated by a wavelength spacing that is smaller than that between adjacent wavelength combs. In some embodiments, the PLC includes modulator banks for encoding data on the wavelength signals and combining them to produce a composite DWDM output signal. In some embodiments, a receiver stage is included for demultiplexing a composite DWDM input signal and detecting each wavelength channel within it.Type: GrantFiled: July 3, 2023Date of Patent: February 10, 2026Assignee: Quintessent Inc.Inventors: Michael Davenport, Brian Koch, Alan Liu
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Patent number: 12537366Abstract: The present disclosure is directed to light-distribution systems on photonic integrated circuits (PIC) that split and amplify a light signal received from at least one remotely located laser into a plurality of amplified light signals, where amplification is provided by an integrated semiconductor optical amplifier (SOA). By locating the laser remotely with respect to the SOA-based PIC, the laser and PIC can be subjected to different ambient environmental conditions. Additionally, a lower-power laser can be used since the optical loss associated with splitting is compensated for by the amplification. As a result, lower current densities and optical powers can be used in both the source laser and the SOA. In some embodiments, the sequence of power splitting and amplification is repeated multiple times, thereby enabling system to scale gracefully.Type: GrantFiled: March 30, 2022Date of Patent: January 27, 2026Assignee: Quintessent Inc.Inventors: Brian Koch, Alan Liu, Daniel Knight Sparacin
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Patent number: 12526055Abstract: The present disclosure is directed toward architectures that combine DWDM and CWDM concepts in a single PIC. Transmitter stages in accordance with the present disclosure include a plurality of multiwavelength lasers having regions of separately grown epitaxial material whose gain peaks are centered at different wavelengths. Each laser launches a wavelength comb comprising a plurality of wavelength signals into a PLC, where the wavelengths within each wavelength comb are separated by a wavelength spacing that is smaller than that between adjacent wavelength combs. In some embodiments, the PLC includes modulator banks for encoding data on the wavelength signals and combining them to produce a composite DWDM output signal. In some embodiments, a receiver stage is included for demultiplexing a composite DWDM input signal and detecting each wavelength channel within it.Type: GrantFiled: January 18, 2023Date of Patent: January 13, 2026Assignee: Quintessent Inc.Inventors: Michael Davenport, Chris Cole, Brian Koch, Alan Liu
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Publication number: 20250279625Abstract: In accordance with a method, forming a semiconductor laser with a photonic integrated circuit (PIC) a laser die is provided that includes a semiconductor laser and a silicon-based photonic waveguide disposed on a silicon substrate. The silicon-based photonic waveguide is configured to receive optical energy generated by the semiconductor laser and provide the optical energy as output energy that is output from the laser die. The laser die is coupled with the PIC so that the optical energy output from the laser die is coupled to a photonic waveguide located on the PIC.Type: ApplicationFiled: March 4, 2025Publication date: September 4, 2025Inventors: Brian KOCH, Michael DAVENPORT, Alan LIU
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Patent number: 12046871Abstract: Integrated-optics systems are presented in which an optically active device is optically coupled with a silicon waveguide via a passive compound-semiconductor waveguide. In a first region, the passive waveguide and the optically active device collectively define a composite waveguide structure, where the optically active device functions as the central ridge portion of a rib-waveguide structure. The optically active device is configured to control the vertical position of an optical mode in the composite waveguide along its length such that the optical mode is optically coupled into the passive waveguide with low loss. The passive waveguide and the silicon waveguide collectively define a vertical coupler in a second region, where the passive and silicon waveguides are configured to control the distribution of the optical mode along the length of the coupler, thereby enabling the entire mode to transition between the passive and silicon waveguides with low loss.Type: GrantFiled: December 1, 2022Date of Patent: July 23, 2024Assignee: Quintessent Inc.Inventors: Brian Koch, Michael Davenport, Alan Liu, Justin Colby Norman
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Publication number: 20240072511Abstract: The present Specification is directed to the heterogeneous integration of compound-semiconductor devices on indirect-bandgap material substrates. A chip comprising compound-semiconductor layer stack disposed on a handle substrate of germanium is bonded, stack-side down, to a silicon layer disposed on a host substrate. The use of a germanium handle substrate enables the handle substrate to be removed after bonding using methods that are highly selective for germanium over the compound semiconductor layer stack. As a result, the compound-semiconductor layer stack does not need to be protected during handle substrate removal and the handle substrate can be completely removed without causing damage to the compound-semiconductor layer stack. As a result, after handle-substrate removal, the materials of the layer stack can be processed further to define one or more optically active devices in conventional fashion.Type: ApplicationFiled: August 9, 2023Publication date: February 29, 2024Inventors: Justin Colby NORMAN, Brian KOCH, Alan LIU
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Publication number: 20240007192Abstract: The present disclosure is directed toward architectures that combine DWDM and CWDM concepts in a single PIC. Transmitter stages in accordance with the present disclosure include a plurality of multiwavelength lasers having regions of separately grown epitaxial material whose gain peaks are centered at different wavelengths. Each laser launches a wavelength comb comprising a plurality of wavelength signals into a PLC, where the wavelengths within each wavelength comb are separated by a wavelength spacing that is smaller than that between adjacent wavelength combs. In some embodiments, the PLC includes modulator banks for encoding data on the wavelength signals and combining them to produce a composite DWDM output signal. In some embodiments, a receiver stage is included for demultiplexing a composite DWDM input signal and detecting each wavelength channel within it.Type: ApplicationFiled: January 18, 2023Publication date: January 4, 2024Inventors: Michael DAVENPORT, Chris COLE, Brian KOCH, Alan LIU
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Publication number: 20230353251Abstract: The present disclosure is directed toward architectures that combine DWDM and CWDM concepts in a single PIC. Transmitter stages in accordance with the present disclosure include a plurality of multiwavelength lasers having regions of separately grown epitaxial material whose gain peaks are centered at different wavelengths. Each laser launches a wavelength comb comprising a plurality of wavelength signals into a PLC, where the wavelengths within each wavelength comb are separated by a wavelength spacing that is smaller than that between adjacent wavelength combs. In some embodiments, the PLC includes modulator banks for encoding data on the wavelength signals and combining them to produce a composite DWDM output signal. In some embodiments, a receiver stage is included for demultiplexing a composite DWDM input signal and detecting each wavelength channel within it.Type: ApplicationFiled: July 3, 2023Publication date: November 2, 2023Inventors: Michael DAVENPORT, Brian KOCH, Alan LIU
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Patent number: 11741760Abstract: A management server system may obtain sensor data generated by a plurality of sensors from a plurality of gateway devices. The sensor data may be associated with a plurality of vehicles. The management server system may identify, for each vehicle of the plurality of vehicles, a subset of the sensor data associated with a particular vehicle. The management server system may generate, in real time, for each vehicle of the plurality of vehicles, a virtual representation of the particular vehicle based on the subset of the sensor data associated with the particular vehicle. The management server system may generate a user interface that includes visualizations of virtual representations of the plurality of vehicles. The management server system may update, in real time, the visualizations of the virtual representations of the plurality of vehicles based on obtaining additional sensor data from the plurality of gateway devices.Type: GrantFiled: May 18, 2022Date of Patent: August 29, 2023Assignee: Samsara Inc.Inventors: Hannah Dubin, Kevin Omwega, Jeremy Intal, Alan Liu, Ewelina Sieradzka
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Patent number: 11733457Abstract: Integrated-optics systems are presented in which an active-material stack is disposed on a coupling layer in a first region to collectively define an OA waveguide that supports an optical mode of a light signal. The coupling layer is patterned to define a coupling waveguide and a passive waveguide, which are formed as two abutting, optically coupled segments of the coupling layer. The lateral dimensions of the active-material stack are configured to control the shape and vertical position of the optical mode at any location along the length of the OA waveguide. The active-material stack includes a taper that narrows along its length such that the optical mode is located completely in the coupling waveguide where the coupling waveguide abuts the passive waveguide. In some embodiments, the passive layer is optically coupled with the OA waveguide and a silicon waveguide, thereby enabling light to propagate between them.Type: GrantFiled: September 22, 2021Date of Patent: August 22, 2023Assignee: Quintessent Inc.Inventors: Brian Koch, Michael Davenport, Alan Liu
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Patent number: 11647147Abstract: In one embodiment, a method includes an intelligent communication device detecting that a person is visible to a camera of the device, determining a first biometric characteristic of the person discernable by the device, associating the first biometric characteristic with a user identifier unique to the person, determining, while the person is identifiable based on the first biometric characteristic, a second biometric characteristic of the person discernable by the device, and associating the second biometric characteristic with the user identifier.Type: GrantFiled: December 28, 2020Date of Patent: May 9, 2023Assignee: Meta Platforms, Inc.Inventors: Eric W. Hwang, Saurabh Mitra, Jeffrey Zhang, Alan Liu, Rahul Nallamothu, Samuel Franklin Pepose
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Patent number: 11631967Abstract: Integrated-optics systems are presented in which an optically active device is optically coupled with a silicon waveguide via a passive compound-semiconductor waveguide. In a first region, the passive waveguide and the optically active device collectively define a composite waveguide structure, where the optically active device functions as the central ridge portion of a rib-waveguide structure. The optically active device is configured to control the vertical position of an optical mode in the composite waveguide along its length such that the optical mode is optically coupled into the passive waveguide with low loss. The passive waveguide and the silicon waveguide collectively define a vertical coupler in a second region, where the passive and silicon waveguides are configured to control the distribution of the optical mode along the length of the coupler, thereby enabling the entire mode to transition between the passive and silicon waveguides with low loss.Type: GrantFiled: September 24, 2021Date of Patent: April 18, 2023Assignee: Quintessent Inc.Inventors: Brian Koch, Michael Davenport, Alan Liu, Justin Colby Norman
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Publication number: 20230109277Abstract: Integrated-optics systems are presented in which an optically active device is optically coupled with a silicon waveguide via a passive compound-semiconductor waveguide. In a first region, the passive waveguide and the optically active device collectively define a composite waveguide structure, where the optically active device functions as the central ridge portion of a rib-waveguide structure. The optically active device is configured to control the vertical position of an optical mode in the composite waveguide along its length such that the optical mode is optically coupled into the passive waveguide with low loss. The passive waveguide and the silicon waveguide collectively define a vertical coupler in a second region, where the passive and silicon waveguides are configured to control the distribution of the optical mode along the length of the coupler, thereby enabling the entire mode to transition between the passive and silicon waveguides with low loss.Type: ApplicationFiled: December 1, 2022Publication date: April 6, 2023Inventors: Brian KOCH, Michael DAVENPORT, Alan LIU, Justin Colby NORMAN
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Patent number: 11514893Abstract: Techniques performed by a data processing system for processing voice content received from a user herein include receiving a first audio input from a user comprising spoken content, analyzing the first audio input using one or more natural language processing models to produce a first textual output comprising a textual representation of the first audio input, analyzing the first textual output using one or more machine learning models to determine first context information of the first textual output, and processing the first textual output in the application based on the first context information.Type: GrantFiled: March 13, 2020Date of Patent: November 29, 2022Assignee: Microsoft Technology Licensing, LLCInventors: Erez Kikin-Gil, Emily Tran, Benjamin David Smith, Alan Liu, Erik Thomas Oveson
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Publication number: 20220320832Abstract: The present disclosure is directed to light-distribution systems on photonic integrated circuits (PIC) that split and amplify a light signal received from at least one remotely located laser into a plurality of amplified light signals, where amplification is provided by an integrated semiconductor optical amplifier (SOA). By locating the laser remotely with respect to the SOA-based PIC, the laser and PIC can be subjected to different ambient environmental conditions. Additionally, a lower-power laser can be used since the optical loss associated with splitting is compensated for by the amplification. As a result, lower current densities and optical powers can be used in both the source laser and the SOA. In some embodiments, the sequence of power splitting and amplification is repeated multiple times, thereby enabling system to scale gracefully.Type: ApplicationFiled: March 30, 2022Publication date: October 6, 2022Inventors: Brian KOCH, Alan LIU, Daniel Knight SPARACIN
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Patent number: 11410770Abstract: A medical scan diagnosing system is operable to receive a medical scan. Diagnosis data of the medical scan is generated by performing a medical scan inference function on the medical scan. The first medical scan is transmitted to a first client device associated with a user of the medical scan diagnosing system in response to the diagnosis data indicating that the medical scan corresponds to a non-normal diagnosis. The medical scan is displayed to the user via an interactive interface displayed by a display device corresponding to the first client device. Review data is received from the first client device, where the review data is generated by the first client device in response to a prompt via the interactive interface. Updated diagnosis data is generated based on the review data. The updated diagnosis data is transmitted to a second client device associated with a requesting entity.Type: GrantFiled: August 20, 2020Date of Patent: August 9, 2022Inventors: Devon Bernard, Kevin Lyman, Li Yao, Alan Liu
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Publication number: 20220210341Abstract: In one embodiment, a method includes an intelligent communication device detecting that a person is visible to a camera of the device, determining a first biometric characteristic of the person discernable by the device, associating the first biometric characteristic with a user identifier unique to the person, determining, while the person is identifiable based on the first biometric characteristic, a second biometric characteristic of the person discernable by the device, and associating the second biometric characteristic with the user identifier.Type: ApplicationFiled: December 28, 2020Publication date: June 30, 2022Inventors: Eric W. Hwang, Saurabh Mitra, Jeffrey Zhang, Alan Liu, Rahul Nallamothu, Samuel Franklin Pepose
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Publication number: 20220076810Abstract: A medical scan interface feature evaluator system is operable to receive a set of responses from each of a set of client devices, where each set of responses is generated based on a corresponding client device displaying each of the set of medical scans in conjunction with at least one interface feature indicated in an image-to-prompt mapping. Response score data is generated for each response of the set of responses received from each of the set of client devices by comparing each response to truth annotation data of a corresponding medical scan of the set of medical scans indicated by the image-to-prompt mapping. Interface feature score data corresponding to each user interface feature in the set of user interface features is generated based on aggregating corresponding response score data. A ranking of the set of user interface features is generated based on the interface feature score data.Type: ApplicationFiled: November 16, 2021Publication date: March 10, 2022Applicant: Enlitic, Inc.Inventors: Kevin Lyman, Devon Bernard, Li Yao, Alan Liu, Brian Basham, Ben Covington