Patents by Inventor Rajeev J. Ram
Rajeev J. Ram 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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Patent number: 12158426Abstract: The present invention relates to the use of a Raman spectral signature for detection of plant metabolites, specifically carotenoids, in tissue of a plant leaf. Carotenoids are used as a biomarker for an early, real-time diagnosis of shade avoidance syndrome (SAS) in growing plants in a non-invasive or non-destructive way in order to detect the adverse effect of the SAS upon their health, and ultimately their yield. The early, real-time diagnosis of SAS provides a window period within which further adverse effects of SAS may be slowed or prevented without negatively affecting the yield of growing plants or leafy vegetables.Type: GrantFiled: May 20, 2021Date of Patent: December 3, 2024Assignees: TEMASEK LIFE SCIENCES LABORATORY LIMITED, MASSACHUSETTS INSTITUTE OF TECHNOLOGYInventors: In-Cheol Jang, Benny Jian Rong Sng, Gajendra Pratap Singh, Rajeev J. Ram
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Publication number: 20240369901Abstract: An integrated acousto-optic modulator operates with an extremely high extinction ratio (e.g.,>50 dB) thanks to two widely separated two-dimensional (2D) waveguides. These 2D waveguides are formed on or adjacent to a one-dimensional (ID) wave-guide far enough apart (e.g., 10-100 pm apart) to prevent evanescent coupling between them. An acoustic transducer formed on the surface of the ID waveguide switches light from one 2D waveguide to the other 2D waveguide via the ID waveguide. The acoustic wave emitted by the acoustic transducer forms a traveling grating that overlaps with one 2D waveguide. diffracting light from that 2D waveguide into the ID waveguide, which guides the light to the other 2D waveguide. A lateral grating coupler diffracts this light from the ID waveguide into a mode guided by the other 2D waveguide. This acoustic modulator acts as a switch suitable for use in quantum and atomic systems.Type: ApplicationFiled: April 15, 2022Publication date: November 7, 2024Applicant: Massachusetts Institute of TechnologyInventors: Gavin WEST, Rajeev J. RAM
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Publication number: 20240344991Abstract: The present invention relates to the use of Raman spectroscopy for the real time detection and quantitation of innate immunity response in plants. More specifically, the present invention provides Raman spectroscopy as a tool for rapid, non-invasive, and early detection and quantitation of plant innate immune response.Type: ApplicationFiled: August 19, 2022Publication date: October 17, 2024Applicants: TEMASEK LIFE SCIENCES LABORATORY LIMITED, MASSACHUSETTS INSTITUTE OF TECHNOLOGYInventors: Pil Joong CHUNG, Sayuj KOYYAPPURATH, Nam-Hai CHUA, Rajani SAROJAM, Gajendra Pratap SINGH, Rajeev J. RAM
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Patent number: 11756983Abstract: Light-emitting diodes having radiative recombination regions with deep sub-micron dimensions are described. The LEDs can be fabricated from indirect bandgap semiconductors and operated under forward bias conditions to produce intense light output from the indirect bandgap material. The light output per unit emission area can be over 500 W cm?2, exceeding the performance of even high brightness gallium nitride LEDs.Type: GrantFiled: December 10, 2021Date of Patent: September 12, 2023Assignee: Massachusetts Institute of TechnologyInventors: Rajeev J. Ram, Jaehwan Kim, Jin Xue, Zheng Li
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Publication number: 20230243750Abstract: The present invention relates to the use of a Raman spectral signature for detection of plant metabolites, specifically carotenoids, in tissue of a plant leaf. Carotenoids are used as a biomarker for an early, real-time diagnosis of shade avoidance syndrome (SAS) in growing plants in a non-invasive or non-destructive way in order to detect the adverse effect of the SAS upon their health, and ultimately their yield. The early, real-time diagnosis of SAS provides a window period within which further adverse effects of SAS may be slowed or prevented without negatively affecting the yield of growing plants or leafy vegetables.Type: ApplicationFiled: May 20, 2021Publication date: August 3, 2023Applicants: TEMASEK LIFE SCIENCES LABORATORY LIMITED, MASSACHUSETTS INSTITUTE OF TECHNOLOGYInventors: In-Cheol JANG, Benny Jian Rong SNG, Gajendra Pratap SINGH, Rajeev J. RAM
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Patent number: 11698301Abstract: Swept-source Raman spectroscopy uses a tunable laser and a fixed-wavelength detector instead of a spectrometer or interferometer to perform Raman spectroscopy with the throughput advantage of Fourier transform Raman spectroscopy without bulky optics or moving mirrors. Although the tunable laser can be larger and more costly than a fixed wavelength diode laser used in other Raman systems, it is possible to split and switch the laser light to multiple ports simultaneously and/or sequentially. Each site can be monitored by its own fixed-wavelength detector. This architecture can be scaled by cascading fiber switches and/or couplers between the tunable laser and measurement sites. By multiplexing measurements at different sites, it is possible to monitor many sites at once. Moreover, each site can be meters to kilometers from the tunable laser. This makes it possible to perform swept-source Raman spectroscopy at many points across a continuous flow manufacturing environment with a single laser.Type: GrantFiled: June 1, 2021Date of Patent: July 11, 2023Assignee: Massachusetts Institute of TechnologyInventors: Rajeev J. Ram, Amir H. Atabaki, Nili Persits, Jaehwan Kim
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Publication number: 20230184684Abstract: The present invention relates to the use of a Raman spectral signature of nitrate, as a biomarker for an early, real-time diagnosis of nitrogen status in growing plants in a non-invasive or non-destructive way in order to detect nitrogen deficiency before the onset of any visible symptoms. The early, real-time diagnosis of nitrogen deficiency in plants makes it possible to correct nitrogen deficiency for the avoidance of negative effects on the yield and biomass of growing plants or leafy vegetables.Type: ApplicationFiled: May 20, 2021Publication date: June 15, 2023Applicants: TEMASEK LIFE SCIENCES LABORATORY LIMITED, MASSACHUSETTS INSTITUTE OF TECHNOLOGYInventors: Bong Soo PARK, Rajeev J. RAM, Chung Hao HUANG, Gajendra Pratap SINGH, Nam-Hai CHUA
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Patent number: 11650440Abstract: A photovoltaic modulator utilizes free carriers generated by absorption of optical radiation passing through the modulator to achieve ultra-low energy modulation of the radiation. The photovoltaic modulator can also function as an electro-optic transducer for low-power, low-EMI, high-density sensing applications.Type: GrantFiled: June 21, 2021Date of Patent: May 16, 2023Assignee: Massachusetts Institute of TechnologyInventors: Marc De Cea Falco, Amir H. Atabaki, Rajeev J. Ram
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Publication number: 20230139185Abstract: Light-emitting diodes having radiative recombination regions with deep sub-micron dimensions are described. The LEDs can be fabricated from indirect bandgap semiconductors and operated under forward bias conditions to produce intense light output from the indirect bandgap material. The light output per unit emission area can be over 500 W cm?2, exceeding the performance of even high brightness gallium nitride LEDs.Type: ApplicationFiled: December 10, 2021Publication date: May 4, 2023Applicant: Massachusetts Institute of TechnologyInventors: Rajeev J. RAM, Jaehwan Kim, Jin Xue, Zheng Li
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Patent number: 11624941Abstract: Semiconductor optical modulators are described that utilize bipolar junction transistor (BJT) structure within the optical modulator. The junctions within the BJT can be designed and biased to increase modulator efficiency and speed. An optical mode may be located in a selected region of the BJT structure to improve modulation efficiency. The BJT structure can be included in optical waveguides of interferometers and resonators to form optical modulators.Type: GrantFiled: April 12, 2021Date of Patent: April 11, 2023Assignee: Massachusetts Institute of TechnologyInventors: Rajeev J. Ram, Marc De Cea Falco, Jin Xue
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Patent number: 11605752Abstract: Photodetectors using photonic crystals (PhCs) in polysilicon film that include an in-plane resonant defect. A biatomic photodetector includes an optical defect mode that is confined from all directions in the plane of the PhC by the photonic bandgap structure. The coupling of the resonance (or defect) mode to out-of-plane radiation can be adjusted by the design of the defect. Further, a “guided-mode resonance” (GMR) photodetector provides in-plane resonance through a second-order grating effect in the PhC. Absorption of an illumination field can be enhanced through this resonance.Type: GrantFiled: September 25, 2020Date of Patent: March 14, 2023Assignee: Massachusetts Institute of TechnologyInventors: Amir H. Atabaki, Rajeev J. Ram, Ebrahim Dakhil Al Johani
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Patent number: 11506951Abstract: Optical read-out of a cryogenic device (such as a superconducting logic or detector element) can be performed with a forward-biased optical modulator that is directly coupled to the cryogenic device without any intervening electrical amplifier. Forward-biasing at cryogenic temperatures enables very high modulation efficiency (1,000-10,000 pm/V) of the optical modulator, and allows for optical modulation with millivolt driving signals and microwatt power dissipation in the cryogenic environment. Modulated optical signals can be coupled out of the cryostat via an optical fiber, reducing the thermal load on the cryostat. Using optical fiber instead of electrical wires can increase the communication bandwidth between the cryogenic environment and room-temperature environment to bandwidth densities as high as Tbps/mm2 using wavelength division multiplexing.Type: GrantFiled: November 6, 2020Date of Patent: November 22, 2022Assignee: Massachusetts Institute of TechnologyInventors: Rajeev J. Ram, Dodd Joseph Gray, Amir H. Atabaki, Marc De Cea Falco
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Patent number: 11307092Abstract: In swept source Raman (SSR) spectroscopy, a swept laser beam illuminates a sample, which inelastically scatters some of the incident light. This inelastically scattered light is shifted in wavelength by an amount called the Raman shift. The Raman-shifted light can be measured with a fixed spectrally selective filter and a detector. The Raman spectrum can be obtained by sweeping the wavelength of the excitation source and, therefore, the Raman shift. The resolution of the Raman spectrum is determined by the filter bandwidth and the frequency resolution of the swept source. An SSR spectrometer can be smaller, more sensitive, and less expensive than a conventional Raman spectrometer because it uses a tunable laser and a fixed filter instead of free-space propagation for spectral separation. Its sensitivity depends on the size of the collection optics. And it can use a nonlinearly swept laser beam thanks to a wavemeter that measures the beam's absolute wavelength during Raman spectrum acquisition.Type: GrantFiled: April 21, 2020Date of Patent: April 19, 2022Assignee: Massachusetts Institute of TechnologyInventors: Amir H. Atabaki, Rajeev J. Ram, William F. Herrington
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Publication number: 20220034715Abstract: Swept-source Raman spectroscopy uses a tunable laser and a fixed-wavelength detector instead of a spectrometer or interferometer to perform Raman spectroscopy with the throughput advantage of Fourier transform Raman spectroscopy without bulky optics or moving mirrors. Although the tunable laser can be larger and more costly than a fixed wavelength diode laser used in other Raman systems, it is possible to split and switch the laser light to multiple ports simultaneously and/or sequentially. Each site can be monitored by its own fixed-wavelength detector. This architecture can be scaled by cascading fiber switches and/or couplers between the tunable laser and measurement sites. By multiplexing measurements at different sites, it is possible to monitor many sites at once. Moreover, each site can be meters to kilometers from the tunable laser. This makes it possible to perform swept-source Raman spectroscopy at many points across a continuous flow manufacturing environment with a single laser.Type: ApplicationFiled: June 1, 2021Publication date: February 3, 2022Inventors: Rajeev J. RAM, Amir H. Atabaki, Nili Persits, Jaehwan Kim
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Publication number: 20210389612Abstract: Semiconductor optical modulators are described that utilize bipolar junction transistor (BJT) structure within the optical modulator. The junctions within the BJT can be designed and biased to increase modulator efficiency and speed. An optical mode may be located in a selected region of the BJT structure to improve modulation efficiency. The BJT structure can be included in optical waveguides of interferometers and resonators to form optical modulators.Type: ApplicationFiled: April 12, 2021Publication date: December 16, 2021Applicant: Massachusetts Institute of TechnologyInventors: Rajeev J. Ram, Marc De Cea Falco, Jin Xue
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Publication number: 20210208470Abstract: Optical read-out of a cryogenic device (such as a superconducting logic or detector element) can be performed with a forward-biased optical modulator that is directly coupled to the cryogenic device without any intervening electrical amplifier. Forward-biasing at cryogenic temperatures enables very high modulation efficiency (1,000-10,000 pm/V) of the optical modulator, and allows for optical modulation with millivolt driving signals and microwatt power dissipation in the cryogenic environment. Modulated optical signals can be coupled out of the cryostat via an optical fiber, reducing the thermal load on the cryostat. Using optical fiber instead of electrical wires can increase the communication bandwidth between the cryogenic environment and room-temperature environment to bandwidth densities as high as Tbps/mm2 using wavelength division multiplexing.Type: ApplicationFiled: November 6, 2020Publication date: July 8, 2021Inventors: Rajeev J. RAM, Dodd Joseph GRAY, Amir H. Atabaki, Marc De Cea Falco
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Publication number: 20210116298Abstract: In swept source Raman (SSR) spectroscopy, a swept laser beam illuminates a sample, which inelastically scatters some of the incident light. This inelastically scattered light is shifted in wavelength by an amount called the Raman shift. The Raman-shifted light can be measured with a fixed spectrally selective filter and a detector. The Raman spectrum can be obtained by sweeping the wavelength of the excitation source and, therefore, the Raman shift. The resolution of the Raman spectrum is determined by the filter bandwidth and the frequency resolution of the swept source. An SSR spectrometer can be smaller, more sensitive, and less expensive than a conventional Raman spectrometer because it uses a tunable laser and a fixed filter instead of free-space propagation for spectral separation. Its sensitivity depends on the size of the collection optics. And it can use a nonlinearly swept laser beam thanks to a wavemeter that measures the beam's absolute wavelength during Raman spectrum acquisition.Type: ApplicationFiled: April 21, 2020Publication date: April 22, 2021Inventors: Amir H. Atabaki, Rajeev J. RAM, William F. Herrington
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Publication number: 20210091252Abstract: Photodetectors using photonic crystals (PhCs) in polysilicon film that include an in-plane resonant defect. A biatomic photodetector includes an optical defect mode that is confined from all directions in the plane of the PhC by the photonic bandgap structure. The coupling of the resonance (or defect) mode to out-of-plane radiation can be adjusted by the design of the defect. Further, a “guided-mode resonance” (GMR) photodetector provides in-plane resonance through a second-order grating effect in the PhC. Absorption of an illumination field can be enhanced through this resonance.Type: ApplicationFiled: September 25, 2020Publication date: March 25, 2021Inventors: Amir H. Atabaki, Rajeev J. RAM, Ebrahim Dakhil Al Johani
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Patent number: 10732044Abstract: A non-paraxial Talbot spectrometer includes a transmission grating to receive incident light. The grating period of the transmission grating is comparable to the wavelength of interest so as to allow the Talbot spectrometer to operate outside the paraxial limit. Light transmitted through the transmission grating forms periodic Talbot images. A tilted detector is employed to simultaneously sample the Talbot images at various distances along a direction perpendicular to the grating. Spectral information of the incident light can be calculated by taking Fourier transform of the measured Talbot images or by comparing the measured Talbot images with a library of intensity patterns acquired with light sources having known wavelengths.Type: GrantFiled: December 5, 2019Date of Patent: August 4, 2020Assignee: Massachusetts Institute of TechnologyInventors: Erika Ye, Amir H. Atabaki, Ningren Han, Rajeev J. Ram, William F. Herrington
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Patent number: 10656012Abstract: In swept source Raman (SSR) spectroscopy, a swept laser beam illuminates a sample, which inelastically scatters some of the incident light. This inelastically scattered light is shifted in wavelength by an amount called the Raman shift. The Raman-shifted light can be measured with a fixed spectrally selective filter and a detector. The Raman spectrum can be obtained by sweeping the wavelength of the excitation source and, therefore, the Raman shift. The resolution of the Raman spectrum is determined by the filter bandwidth and the frequency resolution of the swept source. An SSR spectrometer can be smaller, more sensitive, and less expensive than a conventional Raman spectrometer because it uses a tunable laser and a fixed filter instead of free-space propagation for spectral separation. Its sensitivity depends on the size of the collection optics. And it can use a nonlinearly swept laser beam thanks to a wavemeter that measures the beam's absolute wavelength during Raman spectrum acquisition.Type: GrantFiled: December 21, 2018Date of Patent: May 19, 2020Assignee: Massachusetts Institute of TechnologyInventors: Amir H. Atabaki, Rajeev J. Ram, William F. Herrington