Fast Fourier Transform Approximation of Foreign Currency Option Pricing Based on Exponential Lévy Model

To study the approximation of foreign currency option prices when the underlying assets＇ price dynamics are described by exponential Lévy processes, the convolution representations for option pricing formulas were given, and then the fast Fourier transform （FFT） algorithm was used to get the approximate values of option prices. Finally, a numerical example was given to demonstrate the calculate steps to the option price by FFT.

基于混沌精英和Lévy飞行策略的鲸鱼优化算法

针对鲸鱼优化算法(Whale Optimization Algorithm,WOA)存在的收敛速度慢、精度低的问题,提出了基于Tent混沌精英和Lévy飞行策略的鲸鱼优化算法(TELWOA)。使用Tent混沌映射初始化鲸鱼种群,保持种群的多样性,并通过引入精英反向学习策略,对初始种群的精英个体生成反向解,选取适应度高的种群作为下一代鲸鱼种群,加快算法收敛速度。其次,通过使用非线性收敛因子,缓解算法全局搜索和局部搜索能力不平衡的现象。最后,在鲸鱼位置寻优过程中使用Lévy飞行策略,避免算法陷入局部最优,提升算法的全局搜索能力。通过对不同改进策略的有效性分析、与其他智能算法的对比分析,证明了TELWOA算法在收敛精度、算法稳定性和全局寻优能力上与对比算法有显著提升,具有一定的实际工程应用能力。

融合学习差异与Lévy飞行的动态平衡正余弦算法

为了提升正余弦算法的收敛性能,本文提出一种融合学习差异与Lévy飞行的动态平衡正余弦改进算法,定义为SCALLD算法。通过引入学习差异策略,减少搜索个体对其位置信息的依赖,增强全局探索能力;加入Lévy飞行机制,丰富种群多样性,提升探索能力;采用动态平衡策略,平衡探索与开发能力,提高收敛速度和稳定性。在CEC2022基准测试函数上的实验表明,与六种算法相比,SCALLD展现出更优的收敛性能和稳定性,Wilcoxon秩和检验进一步证明了SCALLD的竞争优势,为解决复杂优化问题提供参考。

由Lévy过程驱动的加权自排斥扩散的长时间行为和统计推断

假设是一个跳有界且界限为1的Lévy过程,生成三元组为。在本文中,我们考虑了由Lévy过程驱动的线性自排斥扩散方程,其中,和。这类过程是一类自交互扩散过程。我们研究了当t趋于无穷时解的长时间行为,发现它具有一种循环收敛性,这在此前的研究中尚未有类似的结论。进一步的,当w=0时在连续观测情况下,通过最小二乘法给出了方程参数的估计。我们证明了的估计量具有强相合性,并讨论了它的渐近分布。

乘性Lévy噪声驱动的随机传染病模型参数估计

利用最小二乘方法研究由乘性Lévy噪声驱动的随机易感潜伏—感染-治愈-易感(susceptible exposed-infectious-recovered-susceptible,SEIRS)传染病模型的参数估计问题.首先,基于模型的离散观测样本,得到模型中未知参数的最小二乘估计量;其次,讨论当噪声强度趋于0且离散观测样本量趋于无穷时估计量的渐近一致性,并给出估计量的极限分布;最后,选定不同的噪声强度和样本量进行数值模拟.结果表明:参数估计量的相对误差随样本量增多或噪声强度减小而不断降低,当样本量足够大且噪声强度足够小时估计量几乎接近真实值.

Presentation of the Berry-Tabor conjecture in Levy plates

The Berry-Tabor(BT)conjecture is a famous statistical inference in quantum chaos,which not only establishes the spectral fluctuations of quantum systems whose classical counterparts are integrable but can also be used to describe other wave phenomena.In this paper,the BT conjecture has been extended to Lévy plates.As predicted by the BT conjecture,level clustering is present in the spectra of Lévy plates.The consequence of level clustering is studied by introducing the distribution of nearest neighbor frequency level spacing ratios P(r),which is calculated through the analytical solution obtained by the Hamiltonian approach.Our work investigates the impact of varying foundation parameters,rotary inertia,and boundary conditions on the frequency spectra,and we find that P(r)conforms to a Poisson distribution in all cases.The reason for the occurrence of the Poisson distribution in the Lévy plates is the independence between modal frequencies,which can be understood through mode functions.

Symmetric Brownian motor subjected to Lévy noise

In the past few years,attention has mainly been focused on the symmetric Brownian motor(BM)with Gaussian noises,whose current and energy conversion efficiency are very low.Here,we investigate the operating performance of the symmetric BM subjected to Lévy noise.Through numerical simulations,it is found that the operating performance of the motor can be greatly improved in asymmetric Lévy noise.Without any load,the Lévy noises with smaller stable indexes can let the motor give rise to a much greater current.With a load,the energy conversion efficiency of the motor can be enhanced by adjusting the stable indexes of the Lévy noises with symmetry breaking.The results of this research are of great significance for opening up BM’s intrinsic physical mechanism and promoting the development of nanotechnology.

Identifying influential spreaders in social networks: A two-stage quantum-behaved particle swarm optimization with Lévy flight

The influence maximization problem aims to select a small set of influential nodes, termed a seed set, to maximize their influence coverage in social networks. Although the methods that are based on a greedy strategy can obtain good accuracy, they come at the cost of enormous computational time, and are therefore not applicable to practical scenarios in large-scale networks. In addition, the centrality heuristic algorithms that are based on network topology can be completed in relatively less time. However, they tend to fail to achieve satisfactory results because of drawbacks such as overlapped influence spread. In this work, we propose a discrete two-stage metaheuristic optimization combining quantum-behaved particle swarm optimization with Lévy flight to identify a set of the most influential spreaders. According to the framework,first, the particles in the population are tasked to conduct an exploration in the global solution space to eventually converge to an acceptable solution through the crossover and replacement operations. Second, the Lévy flight mechanism is used to perform a wandering walk on the optimal candidate solution in the population to exploit the potentially unidentified influential nodes in the network. Experiments on six real-world social networks show that the proposed algorithm achieves more satisfactory results when compared to other well-known algorithms.

LÉVY AREA ANALYSIS AND PARAMETER ESTIMATION FOR FOU PROCESSES VIA NON-GEOMETRIC ROUGH PATH THEORY

This paper addresses the estimation problem of an unknown drift parameter matrix for a fractional Ornstein-Uhlenbeck process in a multi-dimensional setting.To tackle this problem,we propose a novel approach based on rough path theory that allows us to construct pathwise rough path estimators from both continuous and discrete observations of a single path.Our approach is particularly suitable for high-frequency data.To formulate the parameter estimators,we introduce a theory of pathwise Itôintegrals with respect to fractional Brownian motion.By establishing the regularity of fractional Ornstein-Uhlenbeck processes and analyzing the long-term behavior of the associated Lévy area processes,we demonstrate that our estimators are strongly consistent and pathwise stable.Our findings offer a new perspective on estimating the drift parameter matrix for fractional Ornstein-Uhlenbeck processes in multi-dimensional settings,and may have practical implications for fields including finance,economics,and engineering.

Lévy噪声和高斯白噪声驱动的非对称三稳系统的相转移问题研究

讨论了非对称三稳系统在Lévy噪声和高斯白噪声共同驱动下的相转移问题。采用四阶Runge-Kutta算法,计算了系统的稳态概率密度函数,通过改变系统参数和噪声参数观察其稳态概率密度函数曲线形态的变化情况。研究发现,非对称参数、加性噪声强度、乘性噪声强度、稳定性指标、偏斜参数均可诱导系统相转移,当分别改变加性噪声强度和乘性噪声强度时,概率密度函数的峰数与高度的变化情况相反。此外,在相同的非对称参数下,随着偏斜参数正负取值的变化,概率密度曲线图中峰的结构亦呈现不同的现象。

具有Lévy跳的随机时滞食饵-捕食模型的最优收获

研究了一类带Lévy跳的时滞食饵-捕食模型的捕捞策略.利用比较原理分析物种平均持久性和灭绝性的充分条件,在一定假设条件下证明了该模型分布的稳定性,运用遍历法建立最优收获策略存在的条件,得到了最优捕捞努力量和最大持续产量.最后通过数值模拟验证理论结果.

具有Lévy跳跃驱动的Rosenzweig-MacArthur捕食者–食饵模型的渐近行为

本文主要利用随机分析等相关知识,根据进化稳定策略框架对Rosenzweig-MacArthur捕食者–食饵模型进行改进,证明了具有Lévy跳跃驱动的Rosenzweig-MacArthur捕食者–食饵模型解的存在唯一性和随机有界性,并探究了该模型的灭绝性、持久性和平稳分布。

Lévy飞行的正余弦乌燕鸥混合算法及应用

为解决标准乌燕鸥算法(STOA)易陷入局部最优和收敛速度慢等缺点,提出一种混合正余弦算法(SCA)和Lévy飞行的自适应乌燕鸥算法(SLSTOA)。采用正余弦算法的搜索方式,同时采用非线性递减自适应正弦因子,改进乌燕鸥算法的攻击搜索方式,来增强STOA算法的全局与局部探索能力。乌燕鸥个体和最优个体通过Lévy飞行策略进行变异,来增加种群多样性和扩大搜索空间,以达到提高跳出局部最优和全局探索能力。与四种先进的元启发式算法比较,SLSTOA算法性能通过6个基准测试函数进行评价,结果表明,相比其他四种元启发式算法,SLSTOA算法精度高、稳定性好和鲁棒性强。同时为验证SLSTOA算法的科学性与实用性,将其应用于解决32t/22.5m桥式起重机主梁结构优化设计中。

基于Lévy飞行的粒子群算法在大地电磁反演中的应用

粒子群优化算法在大地电磁测深反演中相较于一般的线性反演算法具有多种优点。然而标准粒子群算法在多维优化问题中存在早熟问题,为此,采用基于Lévy飞行随机游走策略的优化粒子群算法来处理局部最优解,增加寻优能力。通过对地电模型的反演对比表明,改进后的粒子群算法相较于标准粒子群算法适应度值下降速度更快、寻优能力更好。最后将该算法应用于已知钻孔旁实测数据,结果较好,表明该算法具有较好的实用性。

基于lévy噪声的随机SIRS模型的拟最优控制

建立了一类基于lévy跳跃的不确定参数随机SIRS传染病模型.利用该模型研究了疫苗接种条件下的拟最优控制问题,使得治疗疾病过程中所花费的成本尽可能地小.根据伴随方程,给出了易感人群、感染人群和恢复人群的先验估计,并利用Hamiltonian函数和Gronwall不等式建立了拟最优控制的充分条件.

基于量子行为和Lévy飞行改进野狗算法的SCR脱硝系统模型辨识

传统野狗优化算法搜索范围有局限性,寻优结果往往不是全局最优,针对此问题,提出一种基于量子行为和Lévy飞行的改进野狗优化算法(Quantum Dingo Optimization Algorithm,QDOA)。量子行为赋予种群移动轨迹和速度的不确定性,使算法的搜索范围可覆盖整个可行空间;Lévy飞行策略的随机步长性,克服算法迭代后期易陷入局部最优问题,提升了求解精度。通过基准测试函数进行性能测试,QDOA相较其他几种算法在准确性、精度方面表现突出。应用QDOA对宁夏某电厂660 MW燃煤机组选择性催化还原(Selective Catalytic Reduction,SCR)脱硝控制系统高负荷段、中低负荷段现场数据进行模型辨识,建立了SCR脱硝系统阀门开度与入口氨气流量、入口氨气流量与出口NOx质量浓度之间的传递函数,经检验辨识后的模型能较好地反映该SCR脱硝控制系统的动态特性,证明了该算法的可行性。

基于R-L分数阶定义的CCM Flyback变换器建模与分析

针对电容电感都为分数阶这一事实,利用分数阶微积分R-L定义和状态空间平均法,对工作在电感电流连续模式(CCM)下的分数阶Flyback变换器进行建模与分析。推导CCM分数阶Flyback变换器的静态工作点和小信号传递函数以及变换器工作在CCM模式下的条件。其次,讨论Caputo模型与R-L导数模型的区别,得出在R-L分数阶定义下直流静态工作点不仅与占空比相关,而且还与电感和电容的阶数以及负载有关。最后,在PSIM中搭建R-L分数阶CCM Flyback变换器电路模型,得到不同分数阶电感电容阶数下分数阶Flyback变换器输出电压和电感电流的仿真波形,通过仿真结果与理论计算结果对比,验证所建模型的正确性,得出分数阶电感电容的阶数会影响闭环控制器的设计和分数阶模型能更加精确地描述Flyback变换器的工作特性。

一类带Lévy跳的随机SEIQR传染病模型动力学分析

考虑不连续噪声对具有潜伏期疾病传播过程的影响,建立一类由Lévy噪声驱动的随机SEIQR传染病模型.先基于随机微分方程的相关理论,利用Lyapunov分析法证明随机SEIQR传染病模型全局正解的存在唯一性;然后通过构造恰当的Lyapunov函数,分别讨论该随机系统的解在相应确定性模型的无病平衡点和地方病平衡点处的渐近行为.

盐湖大气环境下316 L仪表管点蚀深度预测研究

为提高316 L仪表管在盐湖大气环境下点蚀深度的预测精度,采用变阶平均弱化缓冲算子、积分背景值和新陈代谢对分数阶累加灰色模型FGM(1,1,r)进行改进,首先通过改进Tent混沌映射、莱维飞行和区间自适应反向学习策略提高黏菌算法(SMA)的寻优能力和收敛速度,随后利用改进黏菌算法(ISMA)对FGM(1,1,r,ρ)中的参数r和ρ进行寻优,最后构建仪表管ISMA-FGM(1,1,r,ρ)点蚀深度预测模型。研究结果表明:经优化的新模型比原模型误差更小、拟合度更高,在仪表管点蚀深度预测方面具有更好的性能。研究结果可为仪表管道系统的完整性评价和风险预警提供参考。

Lévy飞行和热交换的混沌乌燕鸥算法及应用

为解决乌燕鸥算法对抗局部最优能力和寻优能力较低的问题,提出了一种混合Lévy飞行和热交换混沌乌燕鸥算法(LTCSTOA)。首先,采用Hénon混沌映射对算法种群初始化,保证算法种群多样性。其次,采用混合Lévy飞行和热交换算法的搜索策略,并在不同算法搜索阶段,引入自适应因子γ和自适应惯性权重,提高了算法的跳出局部区域的能力和收敛精度。最后,采用热交换算法对最优乌燕鸥个体进行扰动,提高算法的全局寻优能力。选用7个测试函数验证了不同改进策略的算法有效性,仿真结果表明:与其他算法相比,LTCSTOA算法收敛性能更优,具有较高的收敛精度、稳定性和鲁棒性。将LTCSTOA算法应用于二级斜齿圆柱齿轮传动机构可靠性轻量化设计,优化结果表明:与原设计相比,LTCSTOA算法获得的体积和重合度分别降低了约为51.86%和18.6%,实现了齿轮传动机构轻量化设计的目的。