Narrow Results

There is a growing need for the lightweight acquisition, tracking, and pointing (APT) system during satellite launches due to the escalating demand in space missions. The APT system may work under multiple loading cases during different launch steps. Hence, this study introduces an innovative amalgamation of genetic operation and bi-directional evolutionary structural optimization (BESO) to fulfill the multi-objective requirements through the attainment of Pareto optimal fronts. A typical instance in two dimensions illustrates the effectiveness of the innovative multi-objective approach by contrasting the outcomes acquired from a solitary fulfillment requirement under two distinct burdens. Furthermore, the novel multi-objective method is utilized to remove inefficient material from the APT system by 20.12%. To ensure the safety of the lightweight design, the simulation and experiment of random vibration are both investigated according to the fundamental natural frequency of the launcher.

Advanced Persistent Threat (APT) is a multi-stage and multi-step attack process. The reconstruction of the APT attack scene can start with discrete stage attack detection. However, due to the strong characteristic of concealment of APT attacks, some discrete events in the attack scenarios may not be detected. Therefore, to reconstruct the APT attack scene, we need to mine the hidden attack events according to the APT attack target and the detected discrete attack events, describe the action sequence according to the time sequence or the conditions reached by the attack, and finally reconstruct the attack path. In this paper, we depend on the EP-IKC attack cooperation model, we take the total target of APT attack as the pyramid vertex, and the alerted network entities and potential attacked entities related to the vertex as the facet nodes, this paper introduces the hidden Markov model (HMM), and uses the methods of data association and advanced probability theory to mine the hidden APT attack stages, Finally, the detection of APT attack process and the reconstruction of attack scene are realized.

A brief review is given of the development of linacs, cyclotrons, synchrotrons (also accumulators) and FFAG accelerators for a variety of high power hadron beam applications.

A brief review is given of the development of linacs, cyclotrons, synchrotrons (also accumulators) and FFAG accelerators for a variety of high power hadron beam applications.