Abstract: A method carried out in a radio node of a wireless network for facilitating joint channel estimation in communication with a User Equipment, UE, the method comprising: providing (702), to the UE, radio configuration for a channel (PUSCH, PUCCH) identifying resources for Uplink, UL, transmission within a first frequency domain allocation (83); configuring (704) the UE to transmit, in reference signal resources associated with the radio configuration, a reference signal (DMRS) for use in the radio node for joint channel estimation, wherein said reference signal resources comprise first reference signal resources (81) allocated within said first frequency domain allocation, and second reference signal resources (82) outside said first frequency domain allocation to facilitate joint channel estimation over a transmission disruption within the first frequency domain allocation.

Abstract: Method, carried out in a radio terminal, for configuring uplink output power of radio transmission from the radio terminal, comprising determining a demand power reduction (P-MPR1) based on a maximum power level associated with a first uplink duty cycle (UDC1); transmitting, to a radio network node, an indication of the demand power reduction; receiving, from the network node, an indication of a target power reduction (P-MPR2) associated with an actual uplink duty cycle (UDC2); and configuring the output power based on the target power reduction.

Abstract: A high-brightness picosecond laser system, comprising a fully polarization-maintaining fiber picosecond seed laser (1), a fiber collimator (2), a space isolator (3), a polarization splitting prism (5), a first-stage solid traveling wave amplifier (6), a second-stage solid traveling wave amplifier (7), and a third-stage solid traveling wave amplifier (8) which are sequentially arranged in the laser transmission direction. The first-stage solid traveling wave amplifier (6) is located on the transmission light side of the polarization splitting prism (5), the second-stage solid traveling wave amplifier (7) is located on the reflected light side of the polarization splitting prism (5), and the fiber collimator (2) is connected to the fully polarization-maintaining fiber picosecond seed laser (1) by means of a tail fiber.

Abstract: An array substrate includes a substrate, the array substrate includes a display region and a detection region. And the detection region includes a thin film transistor located on the substrate and a photodiode located on one side of the thin film transistor away from the substrate, and the array substrate further includes a first inorganic protective layer, an organic protective layer and a second inorganic protective layer located between the thin film transistor and the photodiode. And the first inorganic protective layer, the organic protective layer and the second inorganic protective layer are stacked in sequence in a direction away from the substrate, and an orthographic projection of the photodiode on the substrate is within the range of the orthographic projection of the organic protective layer on the substrate.

Abstract: Provided are a thin film transistor, a display substrate and a display device, the thin film transistor includes: a gate on a base substrate; an active layer between the gate and the base substrate, the active layer includes a source contact portion, a drain contact portion and a middle portion therebetween, orthographic projections of the middle portion and the gate on the base substrate overlaps to form a first overlapping region, a material of the middle portion includes a metal oxide containing a doped element, a dissociation energy of the doped element from an oxygen element is greater than 500 Kj/mol; a source connected to the source contact portion and a drain connected to the drain contact portion, a ratio of an area of the orthographic projection of the gate on the base substrate to an area of the first overlapping region is less than or equal to 3.

Abstract: Provided is a micro-nano fluidic substrate, a chip, a preparation method, and a system. The micro-nano fluidic substrate includes: a base; an electrode layer located on the base, the electrode layer includes a first electrode, a second electrode, and a control electrode; and a film layer located on the electrode layer and far away from the base, the film layer includes a groove layer, a nano-channel and a micro-channel, the groove layer includes a first groove, the nano-channel is located in the first groove, an orthographic projection of the nano-channel on the base at least partially coincides with an orthographic projection of the control electrode on the base, and the micro-channel is in communication with the nano-channel, the micro-channel includes a first micro-channel and a second micro-channel, and the first micro-channel is in communication with the first electrode, the second micro-channel is in communication with the second electrode.

Abstract: A multi-layer frequency selective surface is disclosed that exhibits a frequency response having a passband and one or more stopbands.

Abstract: A computer implemented method for determining weights for an attention based trajectory prediction comprises the following steps carried out by computer hardware components: receiving a sequence of a plurality of captures taken by a sensor; determining an unnormalized weight for a first capture of the sequence based on the first capture of the sequence; and determining a normalized weight for the first capture of the sequence based on the unnormalized weight for the first capture of the sequence and a normalized weight for a second capture of the sequence.

Abstract: The present disclosure provides a metal oxide thin film transistor, an array substrate and a display device. A metal oxide thin film transistor in the present disclosure includes: a substrate, a first metal oxide semiconductor layer on the substrate, and a second metal oxide semiconductor layer on a side of the first metal oxide semiconductor layer away from the substrate; a carrier mobility of the first metal oxide semiconductor layer is higher than that of the second metal oxide semiconductor layer; a material of the first metal oxide semiconductor layer includes: a first metal oxide doped with a rear earth element; a difference between an electronegativity of the rare earth element and an electronegativity of oxygen element is greater than or equal to a difference between an electronegativity of a metal element in the first metal oxide and the electronegativity of oxygen element.

Abstract: A wiring board includes a base substrate and first connection pads disposed on the base substrate. The first connection pads each include electrical connection layer(s); each electrical connection layer includes a main material layer and protective layer(s) disposed on a side of the main material layer away from the base substrate; the protective layer(s) include a first reference protective layer, which is a protective layer farthest away from the base substrate in the protective layer(s); and a material of the main material layer includes copper. The electrical connection layer(s) includes a first electrical connection layer, which is an electrical connection layer farthest away from the base substrate in the electrical connection layer(s); and in protective layer(s) in the first electrical connection layer, at least a material of the first reference protective layer is capable of forming a first intermetallic compound with a first solder.

Abstract: A method of operating a first wireless communication device (101) communicating with a second wireless communication device (102) on a device-to-device link (114) in accordance with a pre-established beam pair is provided. The method includes communicating at least one message (4101-4103) indicative of an activation of at least one of a first transmission (181) of first reference signals (191) from the first wireless communication device (101) to the second wireless communication device (102), or a second transmission (182) of second reference signals (192) from the second wireless communication device (102) to the first wireless communication device (101). The activation of the at least one of the first transmission (181) or the second transmission (182) is for use in beam adjustment of the pre-established beam pair at the first wireless communication device (101).

Abstract: A method of operating a wireless communication device (102) in a wireless communication system (100) comprises transmitting a control signal to a node (102) of the wireless communication system (100). The control signal is indicative of a mapping between at least one antenna port (5031-5033) and at least one antenna panel (5023, 5024) of the wireless communication device (102).

Abstract: A reconfigurable device for influencing spatial properties of an incident radio wave comprises a first sheet having characteristics that vary along a first length direction of the first sheet, the characteristics relating to a first influencing of a spatial propagation of an incident radio wave, and a second sheet having characteristics that vary along a second length direction of the second sheet, the characteristics relating to a second influencing of a spatial propagation of an incident radio wave. A first actuator is coupled to the first sheet and configured to move the first sheet along the first length direction so as to selectively place a section of the first sheet in an exposed area of the reconfigurable device. A second actuator is coupled to the second sheet and configured to move the second sheet along the second length direction so as to selectively place a section of the second sheet in the exposed area.

Abstract: A wiring board includes a substrate, conductive pads and at least one protective layer group. The conductive pads are disposed on the substrate. The at least one protective layer group is disposed on a side of the conductive pads away from the substrate; a protective layer group includes an oxidation protective layer and a palladium alloy layer that are stacked, and the oxidation protective layer is closer to the substrate than the palladium alloy layer. A material of the oxidation protective layer includes a nickel-based alloy.

Abstract: The present disclosure provides a TFT, a manufacturing method and a display substrate, and it relates to the field of TFT technology. The TFT includes: a base substrate; a gate electrode arranged on the base substrate; an active layer arranged at a side of the gate electrode away from the base substrate, an orthogonal projection of the active layer onto the base substrate overlapping with an orthogonal projection of the gate electrode onto the base substrate; and a source electrode and a drain electrode arranged at a side of the active layer away from the base substrate and coupled to the active layer. A resistance between the gate electrode and the drain electrode is greater than a resistance between the gate electrode and the source electrode. According to the present disclosure, it is able to increase a withstand voltage range of the TFT.

Abstract: A thin film transistor, an array substrate and a manufacturing method of the thin film transistor are provided, the thin film transistor includes a base substrate; and a first active layer, a first insulating layer and a second active layer, which are sequentially arranged on the base substrate, the first active layer is in contact with the second active layer through a first via hole structure located in the first insulating layer, and non-contacted portions of the first active layer and the second active layer are separated by the first insulating layer, the thin film transistor has a plurality of active layer structures, so that the charges are gathered on two surfaces of each of the active layers, and the number of the charges gathered on the surfaces of the active layers is multiplied, and the open state current of the thin film transistor is multiplied.

Abstract: According to a first aspect, examples provide a method of operating a first communication node (CN) wherein the first CN is configurable for transmitting, to a second CN on a radio channel, orthogonal frequency-division multiplexing (OFDM) symbols via a first propagation path and a second propagation path, wherein each OFDM symbol comprises a prefix, in particular a cyclic prefix, wherein transmitting the OFDM symbols via the first propagation path comprises transmitting the OFDM symbols to the second CN via a coverage enhancing device, wherein the method comprises providing, to the CED, a message indicative of a delay which is to be applied, by the CED, to incident signals, wherein the first CN selects the delay which is to be applied, by the CED, to the incident signals, to result in an arrival, at the second CN, of a first signal portion transmitted via the first propagation path of a first OFDM symbol being aligned with an arrival, at the second CN, of a second signal portion transmitted via the second pr

Abstract: The present disclosure provides a display substrate and a preparation method thereof, and a display apparatus. The display substrate includes a circuit layer disposed on a base substrate, an emitting structure layer and a photoelectric structure layer disposed on a side of the circuit layer away from the base substrate, the circuit layer includes at least one impurity absorption layer and at least one transistor, the transistor includes an active layer, and at least one insulation layer is provided between the impurity absorption layer and the active layer; an atomic ratio of a silicon element to a nitrogen element in the impurity absorption layer is 1:5 to 1:35.

Abstract: According to a first aspect, examples provide a method of operating a first communication node (CN), wherein the first CN is configurable for exchanging, with a second CN on a radio channel, signals via a first propagation path and a second propagation path, wherein exchanging the signals via the first propagation path comprises exchanging the signals via a coverage enhancing device (CED), wherein the method comprises providing, to the CED, a message indicative of an activity pattern for establishing the first propagation path. Further examples provide a method of operating a CED, a first CN, a CED and a second CN.

Abstract: Provided are a thin-film transistor and a manufacturing method thereof, and a display substrate, belonging to the technical field of thin-film transistors. The thin-film transistor includes: a base substrate; a gate electrode on the base substrate; an active layer on a side of the gate electrode away from the base substrate, an orthographic projection of the active layer onto the base substrate overlapping with an orthographic projection of the gate electrode onto the base substrate; and a first electrode and a second electrode on a side of the active layer away from the base substrate, the first electrode being one of a source electrode and a drain electrode, and the second electrode being the other of the source electrode and the drain electrode.