Abstract: Disclosed is an apparatus for diagnosing vertigo and balance related ailment using Craniocorpography (CCG) technique. The apparatus includes a helmet adapted to be worn over a head of a patient. The helmet includes a plurality of light emitting diodes (LEDs). Further, the apparatus includes a camera placed directionally above at a vertical distance from the helmet while the helmet is being worn over the head of the patient. The camera is adapted to track movement of the patient when the CCG is performed on the patient. Furthermore, the apparatus includes an interface card adapted to connect the camera. The interface card is adapted to relay images captured by the camera. A computing system in communication with the interface card is also provided. The computing system is adapted to analyze and present at least a plurality of patient alignment parameters based on the images captured by the camera.

Abstract: The invention provides a system for growth of one or more crystalline materials, specifically diamonds. The system comprises a microwave generator integrated with a pressure controller and an Optical Emission Spectrometer (OES) to form an Integrated Microwave Generator System (IMGS). The OES provides a real-time feedback loop to an IMGS controller based on microwave plasma input from a microwave plasma reactor, to control one or more parameters (power, pressure, power density, and pulsed power) in a closed loop and maintain required proposition of plasma constituents for the growth of diamonds in the microwave plasma reactor. The OES monitors real-time concentration of plasma constituents just above the growing surface of diamonds and feeds the real-time information to the IMGS controller to automatically adjust power density to maintain the concentration of plasma constituents on the growing surface of diamonds.

Abstract: A method and system for assessing balance and posture of a subject by employing virtual reality (VR) or augmented reality (AR) headgear is provided. The system includes memory, a processor, and the VR/AR headgear, providing an immersive environment. The VR/AR headgear includes a display for providing a plurality of visual stimuli. A gyroscope and an inertial measurement unit detect head movements and body sway of the subject in response to the plurality of visual stimuli. An eye tracking unit tracks eye movement of the subject in response to the plurality of visual stimuli. A base plate with sensors can measure center of gravity of the subject in response to movements of the base plate. A machine learning model then deciphers patterns based on measurement data from the gyroscope, inertial measurement unit, eye tracking unit, and base plate. A comprehensive report pertaining to the subject's posture and balance is then generated.

Abstract: Disclosed is an apparatus and method for identifying the gaze stability of a patient. The apparatus includes a head mounted device configured to a patient head, wherein the head mounted device is adapted to track the movement of the patient head. Further, the apparatus includes a display adapted to display a graphic pattern, a perception module adapted to receive perception information regarding the patient's call out of the graphic and a data processing device adapted to control and execute the function of the display, the head mounted device, the perception module based on the inputs received from the perception module.

Abstract: The invention provides a method and system for assessing a balance and posture of a subject by employing a virtual reality (VR)/augmented reality (AR) headgear (108). The system includes a memory (102), a processor (104) and the VR/AR headgear (108) for providing an immersive environment to the subject. The VR/AR headgear (108) includes a display (110) for providing a plurality of visual stimuli to the subject. A gyroscope (112) and an inertial measurement unit (114) detect head movements and body sway of the subject in response to the plurality of visual stimuli. An eye tracking unit (116) tracks eye movement of the subject in response to the plurality of visual stimuli. A machine learning model (118) is then used to decipher normal patterns and abnormal patterns based on measurement data from the gyroscope (112), inertial measurement unit (114), and eye tracking unit (116). A comprehensive report pertaining to the subject's posture and balance is then generated.

Abstract: The present invention provides an apparatus for evaluating otolith dysfunction through the subjective horizontal and vertical testing (SHVT) of a patient. The present apparatus includes a projector adapted to project a luminous line on a test wall of a test room at an initial predetermined position, a controller operated by a patient that adjusts the position of luminous line w.r.t. patient's input. The said input is analyzed by a computing system included in present apparatus which computes subjective visual parameters of patient based on the said input. The subjective visual parameters are calculated by distinguishing deviation of the luminous line (patient's input) from the predetermined reference position. This reference position is installed in the computing device and not visible to the patient. Further, the projector is adapted to add a static, dynamic or real life background.

Abstract: Disclosed is an apparatus for diagnosing vertigo and balance related ailment using Craniocorpography (CCG) technique. The apparatus includes a helmet adapted to be worn over a head of a patient. The helmet includes a plurality of light emitting diodes (LEDs). Further, the apparatus includes a camera placed directionally above at a vertical distance from the helmet while the helmet is being worn over the head of the patient. The camera is adapted to track movement of the patient when the CCG is performed on the patient. Furthermore, the apparatus includes an interface card adapted to connect the camera. The interface card is adapted to relay images captured by the camera. A computing system in communication with the interface card is also provided. The computing system is adapted to analyze and present at least a plurality of patient alignment parameters based on the images captured by the camera.

Abstract: The invention provides a method and system for navigating a user based on a type of maneuver for correction of a vestibular condition. The method and system collects sensor data regarding orientation of head and body of a person for creating a three-dimensional model of the person. The method and system then generates a sequence of steps corresponding to the type of maneuver along with an instruction set and a time duration for performing each step of the sequence of steps, thus enabling the user to perform each step of the sequence of steps corresponding to the type of maneuver, on the person for correcting the vestibular condition.

Abstract: Disclosed is an apparatus and method for identifying the gaze stability of a patient. The apparatus includes a head mounted device configured to a patient head, wherein the head mounted device is adapted to track the movement of the patient head. Further, the apparatus includes a display adapted to display a graphic pattern, a perception module adapted to receive perception information regarding the patient's call out of the graphic and a data processing device adapted to control and execute the function of the display, the head mounted device, the perception module based on the inputs received from the perception module.

Abstract: A method for producing one or more single crystalline diamonds. The method comprises placing one or more substrates on a substrate holder in chemical vapor vaporization (CVD) chamber. A mixture of gases including at least one gas having a carbon component is provided adjacent to the one or more substrates in the CVD chamber. Thereafter, the mixture of gases is exposed to microwave radiation to generate a plasma. Reactive species of nitrogen produced in a remote reactive gas generator are introduced in the plasma. Then, the one or more substrates are exposed to the plasma, such that diamond growth occurs at a rate of 10 to 100 microns per hour, to produce one or more single crystalline diamonds.

Abstract: A method for changing the color of a diamond. The method comprises placing the diamond in a substrate holder in a chemical vapor deposition (CVD) equipment. The CVD equipment is maintained at pressures near or below atmospheric pressure. A mixture of gases including hydrogen is introduced inside the CVD equipment. The introduced mixture of gases is energized by using microwave radiation to heat the diamond to temperatures above 1400° C. Then, the diamond is maintained at temperatures above 1400° C. for few seconds to few hours.

Abstract: A method for producing one or more single crystalline diamonds. The method comprises placing one or more substrates on a substrate holder in chemical vapor vaporization (CVD) chamber. A mixture of gases including at least one gas having a carbon component is provided adjacent to the one or more substrates in the CVD chamber. Thereafter, the mixture of gases is exposed to microwave radiation to generate a plasma. Reactive species of nitrogen produced in a remote reactive gas generator are introduced in the plasma. Then, the one or more substrates are exposed to the plasma, such that diamond growth occurs at a rate of 10 to 100 microns per hour, to produce one or more single crystalline diamonds.

Abstract: A method and an apparatus for producing one or more single crystalline diamonds. One or more diamond seeds are placed in a substrate holder in a chemical vapor deposition (CVD) chamber. One or more metal discs are then positioned in the chemical vapor deposition chamber such that high temperature is generated at low microwave power. A diamond forming gas is then provided adjacent to the one or more diamond seeds. Plasma is then generated from the diamond forming gas by exposing the diamond forming gas to microwave radiation. The one or more diamond seeds are then exposed to the plasma under certain conditions to form single crystalline diamonds. The position of the plasma is manipulated to provide uniform growth conditions at the growth surface of the one or more diamond seeds.

Abstract: A synthetic fire opal and a process for its preparation. Synthetic fire opals have similar physical and chemical properties as natural fire opals. Synthetic fire opals are colored, hard, and transparent. The process of preparation of synthetic fire opal includes; mixing TEOS with absolute ethanol (99.9%), distilled water, concentrated nitric acid, and an inorganic salt to form a clear sol, storing the clear sol to obtain a gel, drying the gel and sintering the dried gel to obtain a synthetic fire opal.

Abstract: A synthetic fire opal having similar physical and chemical properties as natural fire opal. The synthetic fire opal is colored, hard, and transparent. The synthetic fire opal comprises SiO2 and water.

Abstract: A method and an apparatus for producing one or more single crystalline diamonds. One or more diamond seeds are placed in a substrate holder in a chemical vapor deposition (CVD) chamber. One or more metal discs are then positioned in the chemical vapor deposition chamber such that high temperature is generated at low microwave power. A diamond forming gas is then provided adjacent to the one or more diamond seeds. Plasma is then generated from the diamond forming gas by exposing the diamond forming gas to microwave radiation. The one or more diamond seeds are then exposed to the plasma under certain conditions to form single crystalline diamonds. The position of the plasma is manipulated to provide uniform growth conditions at the growth surface of the one or more diamond seeds.

Abstract: A method for producing a large homoepitaxial monocrystalline diamond. The method comprises placing at least two substrates in a substrate holder in a chemical vapor deposition (CVD) chamber. The substrates are positioned in such a manner that the growth faces of the substrates form a wedge. A diamond forming gas is provided adjacent to the substrates in the CVD chamber. The diamond forming gas is exposed to microwave radiation to generate a plasma. Then, the substrates are exposed to the plasma under such conditions that diamond growth occurs in the wedge between the substrates, to form a large homoepitaxial monocrystalline diamond.

Abstract: A synthetic fire opal having similar physical and chemical properties as natural fire opal. The synthetic fire opal is colored, hard, and transparent. The synthetic fire opal comprises SiO2 and water.

Abstract: A method for producing a large homoepitaxial monocrystalline diamond. The method comprises placing at least two substrates in a substrate holder in a chemical vapor deposition (CVD) chamber. The substrates are positioned in such a manner that the growth faces of the substrates form a wedge. A diamond forming gas is provided adjacent to the substrates in the CVD chamber. The diamond forming gas is exposed to microwave radiation to generate a plasma. Then, the substrates are exposed to the plasma under such conditions that diamond growth occurs in the wedge between the substrates, to form a large homoepitaxial monocrystalline diamond.

Abstract: A synthetic fire opal and a process for its preparation. Synthetic fire opals have similar physical and chemical properties as natural fire opals. Synthetic fire opals are colored, hard, and transparent. The process of preparation of synthetic fire opal includes; mixing TEOS with absolute ethanol (99.9%), distilled water, concentrated nitric acid, and an inorganic salt to form a clear sol, storing the clear sol to obtain a gel, drying the gel and sintering the dried gel to obtain a synthetic fire opal.