Abstract: The invention provides a method and a device for detecting breakage of window glass. The device includes a signal generator and a signal receiver. The method includes: controlling the control signal generator to send out a source signal if the door is locked; using the signal receiver for receiving the source signal at the first time; determining whether a signal strength of the source signal exceeds a first threshold; controlling the device to enter a window breakage monitoring mode if the first threshold is exceeded; using the signal receiver for receiving the source signal which is sent by the signal generator at the second time; determining whether a signal strength of the source signal sent at the second time exceeds a second threshold; performing a preset first alarm operation if the second threshold is exceeded. This method has high accuracy and high reliability.

Abstract: An anti-tumor drug composition, including IL 12 proteins, GMCSF proteins, and IL 2 proteins.

Abstract: This disclosure provides a clustering storage method and apparatus. The method includes: storing to-be-stored first data row by row into a local memory in a database system; determining a first sorting column, where the first sorting column is used to sort data that has been cached in the local memory; sorting second data according to the first sorting column if the second data that has been cached in the local memory meets a preset condition, where the second data is data, which has been cached into the local memory, in the first data; and storing the sorted second data in a clustering manner into a storage medium in the database system.

Abstract: The present disclosure relates to a collimator and a collimator mounting device and method, which belong to the technical field of accessories of the X-ray security inspection machine. The collimator comprises a T-shaped base plate and two lead plates, wherein the two lead plates are arranged side by side and in parallel to each other, and are fixed on a longitudinal plate of the T-shaped base plate and extends to a transverse plate of the T-shaped base plate. The collimator is inserted obliquely into a shielding box, with a gap between the two lead plates in the collimator aligned with a first ray opening.

Abstract: A communication device including a first directional antenna and a second directional antenna which may each be set to any one of a plurality of main beam directions for radio communication, a transceiver configured to determine a reception quality for at least some of the plurality of main beam directions using the first directional antenna and for at least some of the plurality of main beam directions using the second directional antenna, select a main beam direction of the plurality of main beam directions based on the reception qualities determined by the first directional antenna and based on the reception qualities determined by the second directional antenna, and perform communication using the selected main beam direction.

Abstract: An MEMS microphone is provided, including a base having a back cavity, and a capacitor system disposed on the base, the capacitor system including a backplate and a diaphragm disposed oppositely to the backplate. The diaphragm includes a body portion and a plurality of venting portions connected to the body portion, each of the plurality of venting portions includes a venting aperture penetrating through the diaphragm and a membrane flap partially fixed to the diaphragm and located in the venting aperture. The MEMS microphone further includes an insulation connecting pillar having one end fixedly connected to the backplate and another end fixedly connected to the membrane flap. Compared with the related art, the venting portion is fixedly connected to the backplate through the insulation connecting pillar, so that the venting portion is not easily warped, thereby improving reliability of the MEMS microphone.

Abstract: Machine-readable media, methods, apparatus and system for beam acquisition in a wireless system are disclosed. In some aspects, a base station may include a transceiver configured to map beam reference signals onto a plurality of transmission beams. The base station may further include a control module configured to divide the transmission beams into a plurality of groups, based at least in part on a plurality of logical indexes assigned to the transmission beams. The control module may be further be configured to divide the transmission beams of each of the groups into a plurality of sub-groups. The control module may be further configured to change a transmission beam order in at least one of the groups, in order to equalize and maximize logical index differences between transmission beams, which are adjacent to one another in a respective sub-group.

Abstract: An MENS microphone is provided in the present disclosure. The MENS microphone includes a fixing pole plate, a vibrating pole plate, an elastic arm; the fixing pole plate comprises a first fixing electrode, an insulating layer, a second fixing electrode that are superimposed sequentially, a through hole penetrating through the first fixing pole plate, the insulating layer and the second fixing pole plate; the vibrating pole plate is embedded in the through hole, comprises a main body and a plurality of spaced protrusions provided on two opposite side walls of the main body; the fixing pole plate comprises a plurality of spaced grooves recessed from two opposite inner walls of the fixing pole plate respectively toward corresponding outer walls, the grooves penetrates through the first fixing electrode, the insulating layer, the second fixing electrode; the protrusions are inserted into the grooves and correspond to the grooves one to one.

Abstract: The present application discloses a MEMS microphone, including: a substrate having a cavity; and a capacitor system mounted on the substrate. The capacitor includes a back plate connected to the substrate; and a diaphragm forming a capacitor with the back plate. The back plate includes a back plate main body and a first connecting portion extending from the back plate main body toward the substrate, the first connecting portion connects with the substrate, and the diaphragm connects to the back plate main body. The vibration or the stress from the substrate will not transferred to the diaphragm, but released via the first connecting portion.

Abstract: Provided is a cytokine combination for treating a tumor and/or preventing recurrence or metastasis of the tumor. The cytokine combination comprising at least three cytokines selected from the following groups: IL12 or a functional variant thereof, GMCSF or a functional variant thereof, FLT3L or a functional variant thereof, IL2 or a functional variant thereof, IL15 or a functional variant thereof, IL21 or a functional variant thereof, and IL7 or a functional variant thereof. Also provided is a nucleic acid molecule encoding the cytokine combination and a vector thereof, a cell, a pharmaceutical composition, and a application thereof for the manufacture of a drug for treating the tumor and/or preventing recurrence or metastasis of the tumor.

Abstract: Technology for a user equipment (UE) operable to decode grant Self-defer less downlink control information (G-D 5 CI) received from a Next Generation NodeB (gNB) is disclosed. The UE can decode the G-DCI received from the gNB in a MulteFire system. The UE can identify grant less uplink DCI components included in the G-DCI. The UE can perform a grant less uplink transmission with the gNB based on the grant less uplink DCI components in the G-DCI received from the gNB.

Abstract: An MEMS microphone, including a base having a back cavity, and a capacitor system fixedly supported on the base, the capacitor system including a diaphragm and a back-plate spaced from the diaphragm. The diaphragm is provided with a venting portion passing through an edge thereof, and the base includes an inner side surface surrounding the back cavity and at least one venting groove formed by recessing from an inner side surface in a direction away from the back cavity direction. The at least one venting groove is disposed corresponding to the venting portion and is in communication with the venting portion and the back cavity, respectively. The base is provided with a venting groove, so that the back cavity has larger space for venting, and the airflow can easily pass through, thereby reducing the probability of breaking the diaphragm. Thus, the MEMS microphone can have a higher reliability.

Abstract: Described is an apparatus of a User Equipment (UE). The apparatus may comprise a first circuitry and a second circuitry. The first circuitry may be operable to process a first Downlink Control Information (DCI) format 0A transmission indicating a Grant-less Uplink (GUL) activation. The first circuitry may also be operable to process a second DCI format 0A transmission indicating a GUL release. The second circuitry may be operable to generate one or more Uplink (UL) transmissions for an unlicensed spectrum of the wireless network after the GUL activation and before the GUL release.

Abstract: Embodiments of the present disclosure describe methods and apparatuses for wireless communications using grantless uplink (GUL) transmissions.

Abstract: An MEMS microphone is provided, including a base having a back cavity, and a capacitor system disposed on the base, the capacitor system including a backplate and a diaphragm disposed oppositely to the backplate. The diaphragm includes a body portion and a plurality of venting portions connected to the body portion, each of the plurality of venting portions includes a venting aperture penetrating through the diaphragm and a membrane flap partially fixed to the diaphragm and located in the venting aperture. The MEMS microphone further includes an insulation connecting pillar having one end fixedly connected to the backplate and another end fixedly connected to the membrane flap. Compared with the related art, the venting portion is fixedly connected to the backplate through the insulation connecting pillar, so that the venting portion is not easily warped, thereby improving reliability of the MEMS microphone.

Abstract: A communication device including a first directional antenna and a second directional antenna which may each be set to any one of a plurality of main beam directions for radio communication, a transceiver configured to determine a reception quality for at least some of the plurality of main beam directions using the first directional antenna and for at least some of the plurality of main beam directions using the second directional antenna, select a main beam direction of the plurality of main beam directions based on the reception qualities determined by the first directional antenna and based on the reception qualities determined by the second directional antenna, and perform communication using the selected main beam direction.

Abstract: Described is an apparatus of an Evolved Node-B (eNB) operable to communicate with a User Equipment (UE) on a wireless network. The apparatus may comprise a first circuitry, a second circuitry, and a third circuitry. The first circuitry may be operable to process one or more configuration transmissions from the eNB carrying one or more parameters for Grantless Uplink (GUL) transmission. The second circuitry may be operable to determine one or more GUL subframes of an acquired Maximum Channel Occupancy Time (MCOT) on time-domain resources allocated for GUL transmission from the UE. The third circuitry may be operable to generate a GUL transmission during the one or more GUL subframes of the acquired MCOT in accordance with the one or more parameters for GUL transmission.

Abstract: A microphone is provided, including a backplate, a base supporting the backplate, and a diaphragm spaced apart from the backplate and forming a capacitor with the backplate. The base includes a top surface abutting against the backplate and a recess recessed from the top surface in a direction facing away from the backplate, the diaphragm is arranged in the recess, and the recess has a recess bottom. The base further includes a through hole penetrating through the recess bottom. The microphone provided by the present disclosure has an advantage of high reliability.

Abstract: An MEMS microphone, including a base having a back cavity, and a capacitor system fixedly supported on the base, the capacitor system including a diaphragm and a back-plate spaced from the diaphragm. The diaphragm is provided with a venting portion passing through an edge thereof, and the base includes an inner side surface surrounding the back cavity and at least one venting groove formed by recessing from an inner side surface in a direction away from the back cavity direction. The at least one venting groove is disposed corresponding to the venting portion and is in communication with the venting portion and the back cavity, respectively. The base is provided with a venting groove, so that the back cavity has larger space for venting, and the airflow can easily pass through, thereby reducing the probability of breaking the diaphragm. Thus, the MEMS microphone can have a higher reliability.

Abstract: A microphone is provided, including a backplate, a base supporting the backplate, and a diaphragm spaced apart from the backplate and forming a capacitor with the backplate. The base includes a top surface abutting against the backplate and a recess recessed from the top surface in a direction facing away from the backplate, the diaphragm is arranged in the recess, and the recess has a recess bottom. The base further includes a through hole penetrating through the recess bottom. The microphone provided by the present disclosure has an advantage of high reliability.