Abstract: Disclosed are a method for preparing a porcine-derived interferon-delta 5 (pIFN-?5) and an application of the pIFN-?5, where the method for preparing pIFN-?5 includes the following steps: step S1, obtaining a DNA fragment containing pIFN-?5 gene through reverse transcription-polymerase chain reaction (RT-PCR) amplification by using the total RNA of pretreated porcine small intestinal epithelial cells IPEC-J2; step S2, inserting the DNA fragment containing pIFN-?5 gene into an exogenous expression vector to construct a recombinant expression vector for expressing the pIFN-?5 gene; and step S3, introducing the recombinant expression vector into a suitable host cell, and driving the host cell to express the pIFN-?5 gene to obtain the pIFN-?5. The recombinant pIFN-?5 protein is used to prepare drugs or preparations for inhibiting infection of porcine epidemic diarrhea virus (PEDV), porcine transmissible gastroenteritis virus (TGEV), porcine delta coronavirus (PDCoV) and porcine rotavirus (PRoV).

Abstract: Provided is a simulation method of distribution of electric field or magnetic field values for two-phase conducting media, including: 1) setting a simulated computation area, setting electric field or magnetic field distribution nodes in the simulated computation area, and setting an artificial current source at the origin of coordinates; 2) selecting a shape function, and setting shape function parameters, Gaussian integral parameters, and electromagnetic parameters; 3) loading a node and searching for nodes in the radius of the support domain, discretizing the definite integral by a 4-point Gaussian integral equation, then interpolating and summing to obtain the fractional derivative of the shape function, assigning the shape function result to the corresponding position of the large sparse matrix in the spatial fractional electric field diffusion equation.

Abstract: Provided is a space-time fractional conductivity modeling and simulation method of two-phase conducting media, including: 1) setting a simulated computation area, setting electric field or magnetic field distribution nodes in the simulated computation area, and setting an artificial current source at the origin of coordinates; 2) selecting a shape function in the entire computation area by a meshless method, and setting shape function parameters, Gaussian integral parameters, electromagnetic parameters, distance between the transmitting system and the receiving system, and the range of the frozen soil layer; 3) loading a first computation point and searching for nodes in the radius of the support domain, discretizing the definite integral by a 4-point Gaussian integral equation, then interpolating and summing to obtain the fractional derivative of the shape function, assigning the shape function result to the corresponding position of the large sparse matrix in the spatial fractional electric field diffusion

Abstract: Provided are a method and a device for determining a clock frequency of a router card. The method includes steps A to D. In step A, a target average port traffic is obtained by using the number of ports and a total to-be-served traffic higher than zero of a target network node for each of neighboring network nodes. In step B, a clock frequency meeting the demand of the target average port traffic is determined as a clock frequency of any router card, the clock frequency of which has not been set, in the target network node. In step C, the total to-be-served traffic and the number of ports are updated. In step D, step A is performed, in a case that there is the updated total to-be-served traffic higher than zero.

Abstract: Provided are a method and a device for determining a clock frequency of a router card. The method includes steps A to D. In step A, a target average port traffic is obtained by using the number of ports and a total to-be-served traffic higher than zero of a target network node for each of neighboring network nodes. In step B, a clock frequency meeting the demand of the target average port traffic is determined as a clock frequency of any router card, the clock frequency of which has not been set, in the target network node. In step C, the total to-be-served traffic and the number of ports are updated. In step D, step A is performed, in a case that there is the updated total to-be-served traffic higher than zero.