Abstract: A method for selecting a target cell by a user equipment (UE), includes: detecting a movement of the UE based on a change in a location of the UE and a change in a measured signal power of a serving cell; determining personalized data of a user based on a plurality of user contextual parameters; predicting a destination of the user, and one or more target cells across a path of the user to the destination based on the determined personalized data of the user and the detected movement of the UE; and selecting the target cell from the one or more target cells, based on an artificial intelligence (AI) model. The AI model is configured to update weights of one or more network quality parameters.

Abstract: The present invention relates to lithium ion cells and specifically to lower capacity (3-10 Ah) elliptic cylindrical lithium ion cells with individual positive and negative terminals projecting from the top of the cell. In particular, the present invention relates to lower capacity elliptic cylindrical lithium ion cells with plastic compression seals, and method of processing them. The cells of the present application exhibit good charge retention and low internal resistance and can be employed for mission critical applications viz. powering satellites, launch vehicles, military vehicles, submarines and electric vehicles.

Abstract: The present disclosure provides methods for inducing cell cycle reentry of postmitotic cell. The present disclosure further provides cells and compositions for treating diseases, such as cardiovascular diseases, neural disorders, hearing loss, and diabetes.

Abstract: The present invention relates to an artificial intelligence based smart hand sanitization system (100) for elderly is provided. The system (100) comprises an inlet pipe (102), a liquid chamber (104), a washing model (110), a collection chamber (106), and an outlet pipe (108). The washing model (110) comprises a plurality of sensors (112), a first scanner unit (116), and a plurality of moveable nozzles (114), a second scanner unit (118), a central processing unit (120), and an alert generating unit (122). The smart portable system (100) for hand-wash has a plurality of moveable nozzles (114) to wash the hands of the user without wetting the accessories and cloth of the user. The present invention is a detachable smart portable system (100) for hand wash that can detach from the wall and be re-fixed on the wall according to the user requirement.

Abstract: Described herein are methods for treating cardiac conditions that include modulating Meox1 enhancer activity, Meox1 transcription, Meox1 translation, MEOX1 protein function, or a combination thereof. Also described herein are methods for identifying agents that can modulate Meox1 enhancer activity.

Abstract: The present disclosure provides methods for inducing cell cycle reentry of postmitotic cell. The present disclosure further provides cells and compositions for treating diseases, such as cardiovascular diseases, neural disorders, hearing loss, and diabetes.

Abstract: The present disclosure provides methods of treating cardiac valve disease, e.g., calcific aortic valve disease (CAVD), by administering to a subject in need thereof a therapeutically effective amount of a compound of any one of Formulae I-X or a pharmaceutically acceptable salt, solvate or prodrug thereof. Also provided are methods of identifying a candidate compound for treatment of cardiac valve disease, e.g., CAVD.

Abstract: Methods and systems for predicting lithium battery properties are presented. In one embodiment, a method includes an operation for creating an equivalent circuit of a battery cell, where the equivalent circuit includes a cathode equivalent circuit and a remainder equivalent circuit. Further, parameters for the cathode equivalent circuit are calculated using Quantum Mechanical (QM) simulation. Also included in the method are operations for obtaining parameters for the remainder equivalent circuit via experimentation, and for calculating the lithium battery properties using the equivalent circuit.

Abstract: The present disclosure provides the development of engineered cardiomyocytes having mutations in transcription factor involved in vivo with cardiac development and/or function. These cell populations comprise mutations that are associated with deleterious effects in vivo in mammals. The mutations of the engineered cardiomyocytes of the disclosure thus are rationally designed based on demonstrated physiological effects in mammals, e.g., mice or humans.

Abstract: The present disclosure provides methods for generating induced cardiomyocytes. The present disclosure further provides methods and compositions for treating cardiovascular disease.

Abstract: The present disclosure provides methods for inducing cell cycle reentry of postmitotic cell. The present disclosure further provides cells and compositions for treating diseases, such as cardiovascular diseases, neural disorders, hearing loss, and diabetes.

Abstract: The present disclosure provides methods for inducing cell cycle reentry of postmitotic cell. The present disclosure further provides cells and compositions for treating diseases, such as cardiovascular diseases, neural disorders, hearing loss, and diabetes.

Abstract: Methods, systems, and computer programs for selecting electrode materials for a lithium battery are presented. In one embodiment, a method includes an operation for developing models for structural and energy analysis of battery stability, safety, cycling and performance, where the models are developed based on a selection of elements and compositions for the electrode materials. Properties of at least on cell performance parameter are estimated, and a cell discharge rate behavior is calculated. Another operation in the method is provided for selecting an electrode material composition based on the estimated properties and the cell discharge rate behavior. The method operations are performed by a computer system that includes a processor.

Abstract: Provided is a positive electrode for a lithium ion battery, the electrode comprising a nano-crystalline layered-layered composite structure of a material having the general formula xLi2MO3(1?x)LiM?O2 in which 0<x<1, where M? is one or more ion with an average oxidation state of three and with at least one ion being Mn or Ni, and where M is one or more ions with an average oxidation state of four. Another aspect provides a positive electrode for a lithium ion battery, the electrode comprising a nano-crystalline layered-spinel composite structure of a material having the general formula xLi2MnO3. (1?x)LiMn2?yMyO4 in which 0.5<x<1.0, 0?y<1, and where M is one or more metal cations. Also provided is the positive electrode which comprises a nano-coating of inert oxide, inert phosphate or inert fluoride on the nano-crystalline composite structure.

Abstract: Method, systems, and algorithms are provided to generate and deliver interactive jokes, comedy monologues, comedy dialogues and comedy routines i) to a user/group in-person, via an interactive comedic robot or ii) to the user/group remotely, via an animated robot, chat-bot, or chatter-bot on internet connected television-, or web-, or mobile-, or projector-interface. Methods include creating a database of topics, set-up comments, punch lines and audio- and video-recordings of canned laughter and emotions. Algorithms include the selection and delivery of the topics, the set-up comments, and the punch lines packaged with the canned laughter and emotions. The jokes/comedy are delivered in a synthesized/recorded robotic or human voice representing one or more than one personality of the robot. The disclosed robots are usable for interactive entertainment, companionship, education, training, greeting, guiding and customer service applications as well as for user feed-back, customization, and crowdsourcing.

Abstract: Methods and systems are provided to generate and exhibit multiple interactive personalities (MIP) in a robot capable of switching back and forth between the MIP (e.g., synthesized digital voice representing a robot personality, digitally recorded human voice representing a human personality) during a continuing interaction with a user, a group of users, or other robots depending upon the situation. The MIP of the robot are exhibited by the robot speaking in more than one voice type, accent, and emotion accompanied with a suitable facial expression. Corresponding animated multiple interactive personality (AMIP) chat-bot and chatter-bot software is also provided which uses a web/mobile interface to train the MIP using crowd-sourcing methods for a group of users and customization for an individual user. Trained MIPs are downloadable into the MIP robot, AMIP chat-bot and/or AMIP chatter-bot for uses including entertainment, social companionship, education and training, and customer service applications.

Abstract: Methods, systems, and computer programs for selecting electrode materials for a lithium battery are presented. In one embodiment, a method includes an operation for developing models for structural and energy analysis of battery stability, safety, cycling and performance, where the models are developed based on a selection of elements and compositions for the electrode materials. Properties of at least on cell performance parameter are estimated, and a cell discharge rate behavior is calculated. Another operation in the method is provided for selecting an electrode material composition based on the estimated properties and the cell discharge rate behavior. The method operations are performed by a computer system that includes a processor.

Abstract: The present disclosure provides method of generating cardiomyocytes from post-natal fibroblasts. The present disclosure further provides cells and compositions for use in generating cardiomyocytes.

Abstract: Provided are methods and computer programs for predicting lithium battery properties. One method includes operations for selecting candidate structures for the battery, and for obtaining a plurality of delithiated structures of the candidate structures with different lithium concentrations. The quantum mechanical (QM) energies of the delithiated structures are calculated, and a functional form is developed to obtain the voltage of the lithium battery. The functional form is a function of the lithium concentration and is based on the QM energies of the delithiated structures. Further, the capacity of the lithium battery is calculated based on a selected lithium concentration, where the functional form returns a cut-off voltage of the lithium battery when the lithium concentration is equal to the selected lithium concentration.

Abstract: The present disclosure provides methods for inducing cell cycle reentry of postmitotic cell. The present disclosure further provides cells and compositions for treating diseases, such as cardiovascular diseases, neural disorders, hearing loss, and diabetes.