Abstract: The present disclosure provides compositions containing: 2-(3,4-dimethoxyphenyl)-5,6,7-trimethoxychromen-4-one (“sinensetin”); 3,5,6,7,8,3?,4?-heptamethoxyflavone (“heptamethoxyflavone” or “HMF”); 2-(3,4-dimethoxyphenyl)-5,6,7,8-tetramethoxy-chromen-4-one (“nobiletin”); 5,6,7,4?-tetramethoxyflavone (“tetra-O-methylscutellarein” or “TMS”); 3,5,6,7,3?,4?-hexamethoxyflavone (“hexamethoxyquercetogetin” or “HMQ”); 5,6,7,8-tetramethoxy-2-(4-methoxyphenyl)-4H-1-benzopyran-4-one (“tangeretin”); or any combinations thereof. The disclosure also provides uses of such compositions as mouthfeel enhancers or bitterness maskers of flavored articles, such as beverages.

Abstract: A device determines a scrambling sequence for a control channel, wherein the scrambling sequence includes a first set of bit string values for a set of downlink control information (DCI) candidates associated with the control channel, and wherein the scrambling sequence is determined based on an identifier that is exclusive to the device. The device determines, based on the scrambling sequence, a correlation sequence that includes a second set of bit string values. The device identifies, based on the correlation sequence, a subset of DCI candidates of the set of DCI candidates. The device selects at least a portion of the subset of DCI candidates. The device performs one or more actions based on one or more selected DCI candidates.

Abstract: A testing device may receive, via a receiving port of a radio frequency (RF) frontend of the testing device, a downlink pilot signal, and may determine a phase associated with the downlink pilot signal. The testing device may transmit, via a transmitting port of the RF frontend of the testing device, an uplink pilot signal. The testing device may receive, after transmitting the uplink pilot signal, the uplink pilot signal via the receiving port of the RF frontend of the testing device. The testing device may determine, after receiving the uplink pilot signal, a phase associated with the uplink pilot signal. The testing device may adjust, based on a phase difference between the phase of the downlink pilot signal and the phase of the uplink pilot signal, one or more transmission settings of the testing device.

Abstract: An autonomous vehicle that automatically responds to an emergency service vehicle. Perception data is captured or received by the autonomous vehicle (AV) cameras, sensors, and microphones. The perception data is used to detect lanes in a road, generate a list of objects, classify one or more of the objects, and determine a state for the classified objects. In response to detecting an emergency service vehicle such as a law enforcement vehicle, a responsive action may be planned by the AV. The responsive action may include sending an acknowledgement signal, notifying passengers of the AV, generating a planned trajectory based on the emergency service vehicle location, an emergency service vehicle detected intention, and other information. A safety check may be performed, and commands may be generated by a control module to navigate the AV along the planned trajectory. The commands may then be executed by a DBW module.

Abstract: Provided is an ? amylase variant obtained by the mutation or deletion of at least one amino acid residue in the amino acid sequence of a parent ? amylase, and at the same time, same is an ? amylase maintaining the capability of the parent to hydrolyse ?-1,4 glycosidic bond, wherein the amino acid sequence homology of the two reaches 95% or more. A series of ? amylase variants provided therein have a relatively high catalytic activity under acidic conditions of pH 5.0 and high temperatures of at least 100° C.

Abstract: A testing device may receive, via a receiving port of a radio frequency (RF) frontend of the testing device, a downlink pilot signal, and may determine a phase associated with the downlink pilot signal. The testing device may transmit, via a transmitting port of the RF frontend of the testing device, an uplink pilot signal. The testing device may receive, after transmitting the uplink pilot signal, the uplink pilot signal via the receiving port of the RF frontend of the testing device. The testing device may determine, after receiving the uplink pilot signal, a phase associated with the uplink pilot signal. The testing device may adjust, based on a phase difference between the phase of the downlink pilot signal and the phase of the uplink pilot signal, one or more transmission settings of the testing device.

Abstract: A device determines a scrambling sequence for a control channel, wherein the scrambling sequence includes a first set of bit string values for a set of downlink control information (DCI) candidates associated with the control channel, and wherein the scrambling sequence is determined based on an identifier that is exclusive to the device. The device determines, based on the scrambling sequence, a correlation sequence that includes a second set of bit string values. The device identifies, based on the correlation sequence, a subset of DCI candidates of the set of DCI candidates. The device selects at least a portion of the subset of DCI candidates. The device performs one or more actions based on one or more selected DCI candidates.

Abstract: A testing device may receive, via a receiving port of a radio frequency (RF) frontend of the testing device, a downlink pilot signal, and may determine a phase associated with the downlink pilot signal. The testing device may transmit, via a transmitting port of the RF frontend of the testing device, an uplink pilot signal. The testing device may receive, after transmitting the uplink pilot signal, the uplink pilot signal via the receiving port of the RF frontend of the testing device. The testing device may determine, after receiving the uplink pilot signal, a phase associated with the uplink pilot signal. The testing device may adjust, based on a phase difference between the phase of the downlink pilot signal and the phase of the uplink pilot signal, one or more transmission settings of the testing device.

Abstract: A scheduling method and a method for establishing a schedule list for user equipment (UE) of NB-IoT are provided. The method for establishing the schedule list includes the following steps: synchronizing to a cell; receiving at least one system information parameter from the cell, the at least one system information parameter including at least one system information type and a narrowband system information block type; establishing multiple sub-lists according to the distributions of the at least one system information type and the narrowband system information block type, each element of the sub-lists representing an available subframe; assigning a sub-list code to each sub-list; calculating the number of elements for each sub-list; and establishing a list according to the at least one system information parameter, the sub-list codes, and the numbers of the elements.

Abstract: A scheduling method for user equipment (UE) of NB-IoT is provided. The scheduling method includes: synchronizing to a cell; receiving from the cell at least one system information parameter that includes a maximum number of repetitions, periods, and offsets of NPDCCH search spaces; establishing a list according to the at least one system information parameter, the list recording multiple available subframes and each available subframe being labeled with an index; calculating a numeral of a start subframe of target NPDCCH repetitions according to a numeral of a target subframe, the period, and the offset; searching the list for a start index corresponding to the start subframe using the numeral of the start subframe; searching the list for a target index corresponding to the target subframe; determining whether the target subframe is within the interval of the target NPDCCH repetitions; and determining whether the target subframe is an NPDCCH candidate subframe.

Abstract: The invention relates to methods for increasing plant yield, and in particular grain yield by reducing or abolishing the expression and/or activity of OTUB1 in a plant. Also described are genetically altered plants characterised by the above phenotype and methods of producing such plants.

Abstract: Disclosed is an approach for implementing an editing tool that can effectively leverage the “contentEditable” feature, while reliably being able to work with structured objects within a document. The approach is particularly useful to implement tools that allow for collaboration with respect to the structured objects.

Abstract: An automated vehicle (AV) which automatically interacts with objects in a surrounding environment based on the objects determined intention and predicted actions determined based on their intention. Data is collected from an external environment by cameras, sensors, and optionally other devices on an AV. The data is processed to identify objects and a state for each object, and an interaction scenario is identified. For objects within the interaction scenario, an intention for each object is determined, and the action of the object is predicted. The AV generates a decision to perform an action to communicate the AV's action to one or more objects. Commands are generated to execute the decision, and the intention of the AV is implemented by executing the commands using one or more output mechanisms (horn, turn signal, display, and/or other mechanisms) for the AV.

Abstract: An autonomous vehicle that automatically responds to an emergency service vehicle. Perception data is captured or received by the autonomous vehicle (AV) cameras, sensors, and microphones. The perception data is used to detect lanes in a road, generate a list of objects, classify one or more of the objects, and determine a state for the classified objects. In response to detecting an emergency service vehicle such as a law enforcement vehicle, a responsive action may be planned by the AV. The responsive action may include sending an acknowledgement signal, notifying passengers of the AV, generating a planned trajectory based on the emergency service vehicle location, an emergency service vehicle detected intention, and other information. A safety check may be performed, and commands may be generated by a control module to navigate the AV along the planned trajectory. The commands may then be executed by a DBW module.

Abstract: Various arrangements are presented for determining a state of a traffic light. A first analysis of a scene may be performed that includes the traffic light. The first analysis may result in the output of a first classification result and a first confidence score. A second, different analysis of the scene may be performed that also outputs a classification result and a confidence score. A fusion process may be performed to fuse the classification results into a fused classification result based on the confidence scores and one or more weighting metrics. A vehicle may then be driven at least partially based on the fused classification result.

Abstract: A reagent kit used for detecting lipoprotein-associated phospholipase A2, and a preparation method for the reagent kit. The reagent kit comprises one or a plurality of first anti-lipoprotein-associated phospholipase A2 antibodies used for binding lipoprotein-associated phospholipase A2 to be measured, and one or a plurality of second anti-lipoprotein-associated phospholipase A2 antibodies marked with a trace marker and binding with the lipoprotein-associated phospholipase A2 to be measured at another site, different from the binding site of the lipoprotein-associated phospholipase A2 to be measured and the first anti-lipoprotein-associated phospholipase A2 antibodies. The reagent kit also comprises a displacing agent, so as to further increase the detection accuracy of the reagent kit.

Abstract: Various arrangements for imaging a traffic light are presented. A distance to the traffic light from a vehicle may be determined. A camera mode may be selected based on the determined distance to the traffic light. One or more images from one or more cameras may be captured and received based on the selected camera mode. A state of the traffic light within the one or more received images may then be determined. The vehicle may then be driven autonomously based on the determined state of the traffic light.

Abstract: Systems and methods for embedded content object collaboration. A server of a cloud-based content management system hosts an access point to a set of executable code. The executable code is configured to facilitate interaction with a user. The user initiates operations that are performed either at the cloud-based content management system or at the at least one user device, or both. The operations include (1) user interactions with a shared content object, (2) user selection of at least one embedded content object within the shared content object, (3) editing the embedded content object at the at least one user device, (4) replicating one or more changes performed on the embedded content object to a remotely-stored instance of the embedded content object, and (5) downloading at least a portion of the updated, remotely-stored instance of the embedded content object to the user device.

Abstract: Provided is an ? amylase variant obtained by the mutation or deletion of at least one amino acid residue in the amino acid sequence of a parent ? amylase, and at the same time, same is an ? amylase maintaining the capability of the parent to hydrolyse ?-1,4 glycosidic bond, wherein the amino acid sequence homology of the two reaches 95% or more. A series of ? amylase variants provided therein have a relatively high catalytic activity under acidic conditions of pH 5.0 and high temperatures of at least 100° C.

Abstract: Conducting a group buying advertising campaign. Receiving a specification for a group-buying offer. Creating a candidate ad campaign based on the received specification. The candidate ad campaign includes at least one campaign feature. The candidate ad is characterized by at least one generalized feature. Determining the expected effectiveness of the candidate ad campaign. For an expected effectiveness less than the aggregate effectiveness of a set of at least one previously run ad campaigns having a generalized feature in common with the candidate campaign, editing the candidate ad campaign to incorporate at least one feature of the set of at least one previously run ad campaigns. Running the edited ad campaign in an ad display network. Collecting effectiveness data for each run ad campaign.