Abstract: An arrangement for providing a vehicle with electric energy, wherein the arrangement includes a generating device for inducing an alternating electric current by magnetic induction in a corresponding receiving device, wherein the arrangement comprises a base to which the generating device is attached, the base defines a vehicle location an elevated region sideways of the vehicle location, wherein an upper surface of the elevated region is elevated compared to an upper surface of the base under the vehicle location, an elongated profile includes an electrically conducting material and/or a magnetizable material, wherein the elongated profile is attached to the elevated region and extends along an extension of the generating device in a longitudinal direction of the arrangement and wherein an elevated profile extends upwards towards a level of the upper surface of the elevated region and also extends towards the vehicle location.

Abstract: The present invention relates to technical field of analog integrated circuit design. TDI function is better realized by CMOS image sensor and it improves scanning frequency of the CMOS-TDI image sensor and extends application range of TDI technique. To this end, the present invention proposes a technical solution of a current accumulative pixel structure for CMOS-TDI image sensor which comprises a photodiode, four MOS transistors M1, M2, M3, M4, four switches S1, S2, S3, S4, and two capacitors C1, C2; the connection relationship thereof is denoted below: the anode of the photodiode D1 is connected to a ground wire, while the cathode thereof is connected to an input end; the drain and gate of the transistor M1 are both connected with the input end, while the source thereof is connected with a power source VDD. The current invention mainly finds its application in analog integration circuit design.

Abstract: The present invention relates to technical field of analog integrated circuit design. TDI function is better realized by CMOS image sensor and it improves scanning frequency of the CMOS-TDI image sensor and extends application range of TDI technique. To this end, the present invention proposes a technical solution of high scanning frequency CMOS-TDI image sensor. The pixels include a photodiode, an operational amplifier, integration capacitors C1 and C2 of the same capacitance, an offset voltage removing capacitor C3, and plural switches S1-S10. The anode of the photodiode is connected to a zero voltage ground wire, while the cathode thereof is connected to one end of the switch S9. The other end of the switch S9 is connected to a reference voltage Vref. The above pixels are cascaded and an output end of the last pixel is connected to a column-parallel ADC through a readout switch Read. The invention mainly applies to analog integration circuit design.

Abstract: An encryption method includes: converting a section of express information into a binary sequence, grouping the binary sequence into a plurality of group data, and aligning each group data into an information matrix; converting the information matrix into a corresponding a basic group information matrix; randomly choosing a reference DNA sequence from a gene library, and aligning the reference DNA sequence into a basic group transition matrix, using the basic group transition matrix to convert the basic group information matrix into an encrypted information matrix, and exploding the encrypted information matrix to obtain a basic group information sequence; generating a primer for the basic group information sequence, and adding the primer before and behind the primer generator to obtain a completed DNA sequence; and synthesizing a DNA matter based on the completed DNA sequence.

Abstract: An OLED array substrate, comprising a plurality of pixel units, the pixel unit at least comprising a first sub-pixel, a second sub-pixel and a third sub-pixel, further comprising: a substrate, a TFT array and a pixel electrode formed on the substrate, and at least two organic luminescent material layers that display different colors formed on the pixel electrode, wherein the first sub-pixel comprises a first pixel electrode, the second sub-pixel comprises a second pixel electrode, the third sub-pixel comprises a third pixel electrode, an organic luminescent material layer of a first color covers the adjacent first pixel electrode and second pixel electrode in the pixel unit, an organic luminescent material layer of a second color covers the adjacent second pixel electrode and third pixel electrode in the pixel unit.

Abstract: The present invention relates to a CMOS image sensor. The present invention provides a digital pixel sensor capable of maintaining consistency between two reference voltage changing rates. To this end, the invention proposes a technical solution in which a digital pixel exposure method by using multiple ramp voltage as reference voltage is provided.

Abstract: The present application discloses an organic light emitting diode array substrate comprising a base substrate; a first electrode; a second electrode; and a pixel definition layer. The pixel definition layer comprises a first insulating layer comprising a plurality of first insulating units; a second insulating layer comprising a plurality of second insulating units; and a conductive layer comprising a plurality of interconnected conductive units sandwiched by the first insulating layer and the second insulating layer.

Abstract: The present disclosure provides a mask plate, a mask exposure device and a mask exposure method, belongs to the field of display technology. The mask plate includes a tray with at least one mask locating slot, and a mask is arranged in each mask locating slot. By the mask plate, the mask exposure device and the mask exposure method provided by the present disclosure, an effective mask with a closed-loop shaped opening may be provided, thereby improving a quality of a film formed on a substrate.

Abstract: An array substrate and manufacturing method thereof, display panel and display device are disclosed. The array substrate includes a display region and a packaging region surrounding the display region. The packaging region is provided with a packaging planarization layer, the packaging planarization layer includes a plurality of packaging planarization units, and each of the packaging planarization units is formed as a ring shaped pattern in the packaging region and configured to surround the display region.

Abstract: In one embodiment, a computer-implemented method includes observing one or more entities by way of two or more data sources. A plurality of detection scores are computed by one or more detectors. Each detection score corresponds to an entity of the one or more entities, a detector of the one or more detectors, and a time. The plurality of detection scores are compiled into two or more tensors, where each tensor corresponds to a data source of the two or more data sources. The two or more tensors are compared to one another, by a computer processor. An inconsistency score is calculated for each of the one or more entities, based on comparing the two or more tensors to one another.

Abstract: The present disclosure provides an organic light-emitting diode packaging structure, a method for packaging an organic light-emitting diode and a display device. The packaging structure includes: a display area of an organic light-emitting diode arranged on a substrate; a cathode pattern arranged on the display area; a first inorganic blocking layer arranged on the cathode pattern; an organic buffer layer arranged on the first inorganic blocking layer, wherein the organic buffer layer is electrically connected at its edge to the cathode pattern in a peripheral area of the display area; and a second inorganic blocking layer, wherein the second inorganic blocking layer is connected directly at its edge to the substrate in the peripheral area of the display area, so as to cover all the other layers.

Abstract: The disclosure describes a flexible display apparatus and an encapsulation method thereof, which are capable of solving the problem of easily producing cracks with the existing encapsulating film layer and improving the performance of flex resistance of the flexible display apparatus. The flexible display apparatus according to the disclosure comprises: an LED device, and a protective layer arranged on a cathode of the OLED device, wherein the protective layer comprises a water oxygen barrier region and a multi-functional region, the multi-functional region has dual functions of a water oxygen barrier and stress blocking, and the thickness of the film layer in the multi-functional region is less than that of the film layer in the water oxygen barrier region, and/or the film texture in the multi-functional region is looser than that in the water oxygen barrier region.

Abstract: In one embodiment, a computer-implemented method includes observing one or more entities by way of two or more data sources. A plurality of detection scores are computed by one or more detectors. Each detection score corresponds to an entity of the one or more entities, a detector of the one or more detectors, and a time. The plurality of detection scores are compiled into two or more tensors, where each tensor corresponds to a data source of the two or more data sources. The two or more tensors are compared to one another, by a computer processor. An inconsistency score is calculated for each of the one or more entities, based on comparing the two or more tensors to one another.

Abstract: The invention relates to a vehicle. The vehicle includes at least one receiving device of a system for inductive power transfer, a cabin section, at least one shielding layer arranged between the receiving device and the cabin section, and a floor section. The at least one shielding layer is integrated into the floor section of the vehicle. The invention also relates to a method of manufacturing a vehicle.

Abstract: The present invention discloses a pixel unit and a method for manufacturing the same, a display panel, and a display apparatus. A pixel unit comprises a first electrode, a pixel defining layer, a light emitting layer and a second electrode, wherein the second electrode comprises a first portion and a second portion; the pixel defining layer defines a pixel region, the light emitting layer and the first portion of the second electrode are disposed successively within the pixel region, and an upper surface of the first portion of the second electrode is substantially in same plane with an upper surface of the pixel defining layer; and, the second portion of the second electrode is positioned over the first portion and is connected with a second electrode of an adjacent pixel unit.

Abstract: An OLED array substrate, comprising a plurality of pixel units, the pixel unit at least comprising a first sub-pixel, a second sub-pixel and a third sub-pixel, further comprising: a substrate, a TFT array and a pixel electrode formed on the substrate, and at least two organic luminescent material layers that display different colors formed on the pixel electrode, wherein the first sub-pixel comprises a first pixel electrode, the second sub-pixel comprises a second pixel electrode, the third sub-pixel comprises a third pixel electrode, an organic luminescent material layer of a first color covers the adjacent first pixel electrode and second pixel electrode in the pixel unit, an organic luminescent material layer of a second color covers the adjacent second pixel electrode and third pixel electrode in the pixel unit.

Abstract: A print method for making a bank card is provided, which includes the following steps: S10, determining print times and print designs each time according to the convex words and/or designs to be printed; S20, fixing the bank card to be printed to a print position; S30: printing the bank card to be printed several times according to the print times and print designs each time in order to form the convex words and/or designs on it. A print device is also provided for making a bank card. The print method and print device for making the bank card can print convex words and/or designs on the surface of the bank card cheaply and efficiently.

Abstract: A method and server for reallocating resources are provided. A resource reallocation instruction is received from a terminal corresponding to a user. The instruction carries first and second management platforms identifiers, a first amount of money for purchasing resources, and a first account identity registered by the user in the first management platform. A second account identity of the user in the second management platform is obtained, which corresponds to the second management platform identifier. The first amount of money is transferred from a resource management account to an account corresponding to the second account identity, and a request is made to the second management platform to allocate the resources to the account corresponding to the second account identity. A request is made to the first management platform to transfer the first amount of money from an account corresponding to the first account identity to the resource management account.

Abstract: A method for performing transactions is disclosed. The method is performed at a server device having one or more processors and memory for storing programs to be executed by the one or more processors. The method includes receiving, from a terminal device, a virtual resource transfer instruction associated with transferring virtual resource into a virtual account of a user. Virtual resource recorded in the virtual account corresponds to actual resource of the user used in a revenue-generation activity. The method also includes sending a resource transfer request to cause completion of an actual resource transfer in accordance with the virtual resource transfer instruction. The method further includes increasing an account balance of the virtual account in accordance with the virtual resource transfer instruction. The user can use the value of virtual resource transferred into the virtual account to perform commercial transactions from the terminal device.

Abstract: An in-situ testing equipment for testing micromechanical properties of a material in a multi-load and multi-physical field coupled condition is disclosed. The equipment comprises a frame supporting module, a tension/compression-low cycle fatigue module, a torsioning module (21), a three-point bending module (6), an impressing module (33), a thermal field and magnetic field application module (34), an in-situ observation module (32) and a clamp body module (22).