104 research outputs found
Double Asynchronous Switching Control for Takagi–Sugeno Fuzzy Markov Jump Systems via Adaptive Event-Triggered Mechanism
This article addresses the issue of adaptive event- triggered H∞ control for Markov jump systems based on Takagi-Sugeno (T-S) fuzzy model. Firstly, a new double asynchronous switching controller is presented to deal with the problem of the mismatch of premise variables and modes between the controller and the plant, which is widespread in real network environment. To further reduce the power consumption of communication, a switching adaptive event-triggered mechanism is adopted to relieve the network transmission pressure while ensuring the control effect. In addition, a new Lyapunov-Krasovskii functional (LKF) is constructed to reduce conservatism by introducing the membership functions (MFs) and time-varying delays informa- tion. Meanwhile, the invariant set is estimated to ensure the stability of the system. And the disturbance rejection ability is measured by the optimal H∞ performance index. Finally, two examples are presented to demonstrate the effectiveness of the proposed approach
Asynchronous switching control for fuzzy Markov jump systems with periodically varying delay and its application to electronic circuits
This article focuses on addressing the issue of asynchronous H∞ control for Takagi-Sugeno (T-S) fuzzy Markov jump systems with generally incomplete transition probabilities (TPs). The delay is assumed to vary periodically, resulting in one monotonically increasing interval and one monotonically decreasing interval during each period. Meanwhile, a new Lyapunov-Krasovskii functional (LKF) is devised, which depends on membership functions (MFs) and two looped functions formulated for the monotonic intervals. Since the modes and TPs of the original system are assumed to be unavailable, an asynchronous switching fuzzy controller on the basis of hidden Markov model is proposed to stabilize the fuzzy Markov jump systems (FMJSs) with generally incomplete TPs. Consequently, a stability criterion with improved practicality and reduced conservatism is derived, ensuring the stochastic stability and H∞ performance of the closed-loop system. Finally, this technique is employed to the tunnel diode circuit system, and a comparison example is given, which verifies the practicality and superiority of the method
WR-ONE2SET: Towards Well-Calibrated Keyphrase Generation
Keyphrase generation aims to automatically generate short phrases summarizing
an input document. The recently emerged ONE2SET paradigm (Ye et al., 2021)
generates keyphrases as a set and has achieved competitive performance.
Nevertheless, we observe serious calibration errors outputted by ONE2SET,
especially in the over-estimation of token (means "no
corresponding keyphrase"). In this paper, we deeply analyze this limitation and
identify two main reasons behind: 1) the parallel generation has to introduce
excessive as padding tokens into training instances; and 2) the
training mechanism assigning target to each slot is unstable and further
aggravates the token over-estimation. To make the model
well-calibrated, we propose WR-ONE2SET which extends ONE2SET with an adaptive
instance-level cost Weighting strategy and a target Re-assignment mechanism.
The former dynamically penalizes the over-estimated slots for different
instances thus smoothing the uneven training distribution. The latter refines
the original inappropriate assignment and reduces the supervisory signals of
over-estimated slots. Experimental results on commonly-used datasets
demonstrate the effectiveness and generality of our proposed paradigm.Comment: EMNLP202
The heme-p53 interaction: Linking iron metabolism to p53 signaling and tumorigenesis
Recently, we reported that heme binds to tumor suppressor p53 protein (TP53, best known as p53) and promotes its nuclear export and cytosolic degradation, whereas iron chelation stabilizes p53 protein and suppresses tumors in a p53-dependent manner. This not only provides mechanistic insights into tumorigenesis associated with iron excess, but also helps guide the administration of chemotherapy based on iron deprivation in the clinic
EMMA-X: An EM-like Multilingual Pre-training Algorithm for Cross-lingual Representation Learning
Expressing universal semantics common to all languages is helpful in
understanding the meanings of complex and culture-specific sentences. The
research theme underlying this scenario focuses on learning universal
representations across languages with the usage of massive parallel corpora.
However, due to the sparsity and scarcity of parallel data, there is still a
big challenge in learning authentic ``universals'' for any two languages. In
this paper, we propose EMMA-X: an EM-like Multilingual pre-training Algorithm,
to learn (X)Cross-lingual universals with the aid of excessive multilingual
non-parallel data. EMMA-X unifies the cross-lingual representation learning
task and an extra semantic relation prediction task within an EM framework.
Both the extra semantic classifier and the cross-lingual sentence encoder
approximate the semantic relation of two sentences, and supervise each other
until convergence. To evaluate EMMA-X, we conduct experiments on XRETE, a newly
introduced benchmark containing 12 widely studied cross-lingual tasks that
fully depend on sentence-level representations. Results reveal that EMMA-X
achieves state-of-the-art performance. Further geometric analysis of the built
representation space with three requirements demonstrates the superiority of
EMMA-X over advanced models.Comment: Accepted by NeurIPS 202
Resilient optimal defensive strategy of TSK fuzzy-model-based microgrids' system via a novel reinforcement learning approach
With consideration of false data injection (FDI) on the demand side, it brings a great challenge for the optimal defensive strategy with the security issue, voltage stability, power flow, and economic cost indexes. This article proposes a Takagi-Sugeuo-Kang (TSK) fuzzy system-based reinforcement learning approach for the resilient optimal defensive strategy of interconnected microgrids. Due to FDI uncertainty of the system load, TSK-based deep deterministic policy gradient (DDPG) is proposed to learn the actor network and the critic network, where multiple indexes' assessment occurs in the critic network, and the security switching control strategy is made in the actor network. Alternating direction method of multipliers (ADMM) method is improved for policy gradient with online coordination between the actor network and the critic network learning, and its convergence and optimality are proved properly. On the basis of security switching control strategy, the penalty-based boundary intersection (PBI)-based multiobjective optimization method is utilized to solve economic cost and emission issues simultaneously with considering voltage stability and rate-of-change of frequency (RoCoF) limits. According to simulation results, it reveals that the proposed resilient optimal defensive strategy can be a viable and promising alternative for tackling uncertain attack problems on interconnected microgrids.In part by the National Natural Science Fund, the Basic Research Project of
Leading Technology of Jiangsu Province, the National Key Research and Development Program of China and the National Natural Science Key Fund.https://ieeexplore.ieee.org/servlet/opac?punumber=5962385hj2023Electrical, Electronic and Computer Engineerin
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