Embodiments methods implemented by a server or a processor of a mobile communication device (e.g., a multi-standby communication device) reduce the redundancy information needed to achieve adequate reception service on a first radio access technology (RAT) sharing an RF resource with a second RAT. The device processor may implement at least one tune-away management strategy that mitigates the amount of data for the first RAT that is lost during the tune-away event. Thus, by implementing the one or more tune-away management strategies, the device processor may ensure that less redundancy information overhead is needed to correct or replace lost/partially received data, improving latency, channel usage, and the first RAT's overall reception performance. In some embodiments, a server may implement one or more strategies for including redundancy information into data that is sent to a first RAT to mitigate the negative effects of tune-aways on the first RAT.
The present invention relates to a method of preparing a mesoporous metal oxide, comprising the steps of: a) providing metal salt; b) providing a template; c) mixing the metal salt of step a) with the template of step b) in a solvent to form a precursor solution and heating the precursor solution to obtain a precipitate; and d) calcining the precipitate obtained from step c) to form the mesoporous metal oxide, wherein the template is N-C10-26 acyl-glutamic acid. The present invention further relates to a mesoporous metal oxide prepared by the method, and to a use of the mesoporous metal oxide as electrode material for electrochemical energy storage devices such as lithium-ion batteries.
The present invention relates to apparatuses and methods for exchange of signaling information in coordinated multi-point (CoMP). Partial embodiments of the present invention provide a method for exchange of signaling information in CoMP, where a first transmission point and a second transmission point provide CoMP for at least one user equipment (UE). The method includes: the first transmission point determining resource allocation for at least one of the first transmission point and the second transmission point, that is, the first transmission point notifying the second transmission point of the determined resource allocation. The resource allocation includes at least one of beamforming, power, and UE scheduling of the corresponding transmission point. The present invention can support CoMP under practical network conditions more effectively.
Monitoring an object to prevent an occurrence of an issue includes monitoring an object based on a number of parameters, categorizing messages of the object into categories while monitoring for a recurrence of a pattern of messages, detecting a potential issue with the object based on the recurrence of the pattern of messages, and alerting an operations manager agent of the potential issue to prevent an occurrence of the issue.
A method for removing SOx from gas using a polyol complex solution: mixing a polyol with an organic acid and/or organic acid salt to form a polyol complex solution; enabling the polyol complex solution to contact gas containing SOx, and absorbing SOx in the gas, x=2 and/or 3, and the polyol being an organic compound simultaneously comprising two or more hydroxyls in the same organic molecule in addition to ethanediol and polyethylene glycol.
A method used in a BS for scheduling a UE, and an associated BS is disclosed. The method includes: allocating one or more DL Resource Blocks (RBs) for transmitting DownLink (DL) data to the UE (S910); determining an UpLink (UL) control channel position for the UE transmitting a Hybrid Automatic Repeat Request (HARQ) feedback of the DL data, based on the allocated one or more DL RBs (S920); and transmitting the DL data to the UE by using the allocated one or more DL RBs (S930). Said method also relates to a method used in a UE for transmitting a HARQ feedback, and an associated UE.
Disclosed is a method for removing SOx in a gas by using an ethylene glycol complex solution. Ethylene glycol and/or polyethylene glycol is mixed with an organic acid or organic acid salt that does not contain nitrogen atoms in molecules, to form the ethylene glycol complex solution, and the ethylene glycol complex solution is made to be in contact with a gas containing Sox, to absorb SOx in the gas, wherein x is equal to 2 and/or 3. The ethylene glycol complex solution in which SOx is absorbed is regenerated by using one or more of a heating method, a vacuum method, a gas stripping method, an ultrasonic method, a microwave method and a radiation method, byproducts of sulfur dioxide and sulfur trioxide are released, and the regenerated ethylene glycol complex solution is recycled. The method can be applied to desulfurization of flue gases, incineration gases, coke furnace gases, synthetic waste gases in a dyestuff plant, sewage disposal gases in a chemical fiber factory, and other industrial raw material gases or waste gases containing SOx.
Provided is a method for removal of SOx from gas using a compound amine alcohol solution. Ethylene glycol and/or polyethylene glycol is/are mixed with a hydroxyl and/or carboxyl organic compound of a basic nitrogen-containing group to form a compound amine alcohol solution, which solution is caused to come into contact with a SOx-containing gas so as to absorb therefrom said SOx, wherein x = 2, and/or 3. The compound amine alcohol solution having absorbed the SOx is recovered by means of one or more of heating, vacuum, air-stripping, ultrasonic, microwave or radiation methods, releasing sulfur dioxide and sulfur trioxide as by-products and recycling the compound amine alcohol solution for reuse. The present method can be used for removal of SOx from flue gases, incinerator gases, coke oven gases, synthesis waste gases of dye plants, gaseous waste of chemical fiber plants, and from other industrial feed or exhaust gases containing SOx.
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