Abstract: Therapeutic methods and vaccinia virus therefor are provided. The viruses are designed so that they accumulate in immunoprivileged tissues and cells, such as in tumors and other proliferating tissue and in inflamed tissues, compared to other tissues, cells and organs, so that they exhibit relatively low toxicity to host organisms. Combinations of the viruses and anti-cancer agents and uses thereof for treating cancer also are provided.

Abstract: A grayscale voltage adjusting method includes: receiving luminance values of grayscales corresponding to three primary colors under at least one binding point, and receiving grayscale voltages corresponding to the three primary colors under the corresponding binding point; fitting the luminance values of grayscales corresponding to three primary colors under the plurality of binding points and the grayscale voltages corresponding to the three primary colors under the corresponding binding point, to obtain a luminance-grayscale voltage fitting result; and based on the luminance-grayscale voltage fitting result, according to a target luminance Lg of each grayscale corresponding to three primary colors in a target image, acquiring a target grayscale voltage corresponding to the target luminance of each grayscale corresponding to three primary colors in the target image from the luminance-grayscale voltage fitting result, such that a display apparatus displays the target image according to the target grayscale vo

Abstract: The preset disclosure provides a data burning method and a data burning device. The data burning method comprises receiving a differential signal data packet, which is transmitted by a signal generator, by a driver IC through a differential signal interface, the differential signal data packet including grayscale data; parsing the differential signal data packet by the driver IC to obtain the grayscale data; and burning the grayscale data to a memory by the driver IC.

Abstract: Provided are a method and apparatus for transmitting a synchronization signal, and a method and apparatus for receiving the synchronization signal. The method for transmitting the synchronization signal includes: determining, by a transmitting end, the synchronization signal, transmitting, by the transmitting end, the synchronization signal determined to a receiving end, and notifying the receiving end of configuration information related to the synchronization signal determined. Compared with the related art where performance of the synchronization and coverage of the synchronization signal are affected due to low flexibility of the synchronization, the flexibility of the synchronization is improved, thereby reducing effects on performance of the synchronization and coverage of the synchronization signal.

Abstract: The present invention relates to a method for forming a nanocomposite having a core-shell structure, the method comprising the steps of: forming a core comprising a first fluorophore capable of aggregation induced emission, and depositing a second fluorophore capable of aggregation caused quenching onto the surface of the core to form a shell at least partially surrounding the core. The present invention also relates to a nanocomposite obtained by said method, and a method of altering the fluorescence of said nanocomposite. The nanocomposite may exhibit dual emission colours and opposite aggregation fluorescent behaviours.

Abstract: A shift register includes a gate driving signal generating sub-circuit, a plurality of first signal output control sub-circuits, second signal output control sub-circuits, and signal output terminals. Each first signal output control sub-circuit and the corresponding one of the second signal output control sub-circuits coupled thereto are configured to: during one or more time periods in a period of displaying one frame of image, transmit a gate driving signal output by the gate driving signal generating sub-circuit to a corresponding one of the signal output terminals and output the gate driving signal through the corresponding one of the signal output terminals, and during other time periods, transmit the first input signal received by the first signal input terminal to a corresponding one of the signal output terminals and output the first input signal through the corresponding one of the signal output terminals.

Abstract: A photodiode having a reduced dark current includes a semiconductor layer, a first contact part, a second contact part, and an active region. The first contact part disposed in a first region of the semiconductor layer includes an interlayer and at least one metal layer. The second contact part disposed in a second region of the semiconductor layer includes at least one metal layer. The active region is disposed between the first contact part and the second contact part. The first contact part and the second contact part are arranged asymmetrical to each other.

Abstract: Aspects for forward propagation of a multilayer neural network (MNN) in a neural network processor are described herein. As an example, the aspects may include a computation module that includes a master computation module and one or more slave computation modules. The master computation module may be configured to receive one or more groups of MNN data. The one or more groups of MNN data may include input data and one or more weight values and wherein at least a portion of the input data and the weight values are stored as discrete values. The one or more slave computation modules may be configured to calculate one or more groups of slave output values based on a data type of each of the one or more groups of MNN data.

Abstract: Aspects for backpropagation of a multilayer neural network (MNN) in a neural network processor are described herein. The aspects may include a computation module configured to receive one or more groups of MNN data. The computation module may further include a master computation module configured to calculate an input gradient vector based on a first output gradient vector from an adjacent layer and based on a data type of each of the one or more groups of MNN data. Further still, the computation module may include one or more slave computation modules configured to parallelly calculate portions of a second output vector based on the input gradient vector calculated by the master computation module and based on the data type of each of the one or more groups of MNN data.

Abstract: Aspects for backpropagation of a multilayer neural network (MNN) in a neural network processor are described herein. The aspects may include a computation module configured to receive one or more groups of MNN data. The computation module may further include a master computation module configured to calculate an input gradient vector based on a first output gradient vector from an adjacent layer and based on a data type of each of the one or more groups of MNN data. Further still, the computation module may include one or more slave computation modules configured to parallelly calculate portions of a second output vector based on the input gradient vector calculated by the master computation module and based on the data type of each of the one or more groups of MNN data.

Abstract: Aspects for forward propagation of a multilayer neural network (MNN) in a neural network processor are described herein. As an example, the aspects may include a computation module that includes a master computation module and one or more slave computation modules. The master computation module may be configured to receive one or more groups of MNN data. The one or more groups of MNN data may include input data and one or more weight values and wherein at least a portion of the input data and the weight values are stored as discrete values. The one or more slave computation modules may be configured to calculate one or more groups of slave output values based on a data type of each of the one or more groups of MNN data.

Abstract: A grayscale voltage adjusting method includes: receiving luminance values of grayscales corresponding to three primary colors under at least one binding point, and receiving grayscale voltages corresponding to the three primary colors under the corresponding binding point; fitting the luminance values of grayscales corresponding to three primary colors under the plurality of binding points and the grayscale voltages corresponding to the three primary colors under the corresponding binding point, to obtain a luminance-grayscale voltage fitting result; and based on the luminance-grayscale voltage fitting result, according to a target luminance Lg of each grayscale corresponding to three primary colors in a target image, acquiring a target grayscale voltage corresponding to the target luminance of each grayscale corresponding to three primary colors in the target image from the luminance-grayscale voltage fitting result, such that a display apparatus displays the target image according to the target grayscale vo

Abstract: An off-grid energy storage system includes n energy storage inverters identified by P1, P2, . . . , Pn sequentially, direct current sides of the inverters are connected to storage batteries, and alternate current sides of the inverters are connected in parallel. The storage battery connected to the direct current side of Pj is identified by Bj, where j=2, 3, . . . , n. A control system for an output waveform of P1 has a voltage-current double loop control structure, and a control system for an output waveform of Pj has a current loop control structure. A current loop given value of Pj is obtained by adding a current correction value of Pj to a current loop given value of P1. The current correction value of Pj is used for causing Bj to have the same operating parameter as B1.

Abstract: A photodiode having a reduced dark current includes a semiconductor layer, a first contact part, a second contact part, and an active region. The first contact part disposed in a first region of the semiconductor layer includes an interlayer and at least one metal layer. The second contact part disposed in a second region of the semiconductor layer includes at least one metal layer. The active region is disposed between the first contact part and the second contact part. The first contact part and the second contact part are arranged asymmetrical to each other.

Abstract: Modified viruses and methods for preparing the modified viruses are provided. Vaccines that contain the viruses are provided. The viruses can be used in methods of treatment of diseases, such as proliferative and inflammatory disorders, including cancer, and as anti-tumor and/or antiangiogenic agents. The viruses also can be used in diagnostic methods.

Abstract: Disclosed are a retransmission control method and apparatus in a multi-user shared access (MUSA) process, a UE and a storage medium. The method comprises: allocating an MUSA number for a UE (101); receiving an MUSA data packet sent by the UE in an uplink MUSA resource range indicated by a base station (102): using a multi-user shared access radio network temporary identifier (MUSA-RNTI) to indicate a segment of radio resource block used for transmitting acknowledgement information (103); broadcasting the MUSA number of the UE, the data packet of which is correctly received, in the indicated radio resource block, so that the UE determines, according to the MUSA number, whether to retransmit the MUSA data packet which has been sent (104).

Abstract: Disclosed is a supporting assembly and an unmanned aerial vehicle using the same, the supporting assembly includes a first base, a second base, a plurality of arms, and a damping element disposed between the first base and the second base. The second base is disposed on the first base. Each of the plurality of arms includes a proximal end and a distal end opposite to the proximal end, the proximal end is secured to the first base, and the distal end is configured for mounting a vibration source.

Abstract: Methods and devices are provided in which generation of an error is identified while a function of a program is performed. A message is displayed relating to existence of a solution corresponding to the error.

Abstract: A positive active material, a method of preparing the same, and a lithium battery including the positive active material, the positive active material including a core, the core including an overlithiated lithium transition metal oxide; and a coating layer on the core, the coating layer including Li3VO4.