一种自适应的二次调频小波变换OA
An Adaptive Quadratic Chirplet Transform Method
时频分析方法作为处理非平稳信号的有力工具被广泛应用于非平稳状态下的机械状态检测与系统参数识别.传统的时频分析方法难以有效处理频率组分相近甚至频率轨迹交叉的非线性多分量信号.本文致力于发展一种自适应的二次调频小波变换方法,首先计算信号包含二次调频参数的二次调频小波变换(Quadratic chirplet transform,QCT),在残差QCT中迭代提取幅值最大的信号分量,然后从残差QCT中移除已检测信号分量的QCT,最后根据检测到的全部信号分量特性构建信号的准确时频表示.仿真信号算例与三自由度弹簧阻尼系统模型验证结果表明:自适应二次调频小波变换方法可以清晰提取频率组分相近以及频率轨迹交叉的信号的时频表示,也克服了传统时频变换方法难以处理高阶频率变化信号的局限性.
Time-frequency analysis becomes a powerful tool for processing nonstationary signals and is widely used in mechanical condition monitoring and system parameter identification under nonstationary operating conditions.However,conventional time-frequency methods can hardly effectively handling nonlinear multicomponent signals with closely spaced frequency components or even crossing frequency trajectories.This work proposes an adaptive quadratic chirplet transform(AQCT)method.The approach computes the quadratic chirplet transform(QCT)of the signal,in which a quadratic frequency modulation parameter is explicitly incorporated.The maximum amplitude signal is then iteratively extracted from the residual QCT,and the QCT contribution of the detected component is removed from the residual representation.Finally,an accurate time-frequency representation of the signal is constructed based on all detected components.Simulation examples and a three-degree-of-freedom spring-damper system model demonstrate that the proposed AQCT method can clearly extract the time-frequency representations of signals with closely spaced frequency components and crossing frequency trajectories,and that it effectively overcomes the limitations of conventional time-frequency transforms in dealing with higher-order frequency variations.
陈劲轲;史治宇;彭徐俊
南京航空航天大学航空学院,南京 210016南京航空航天大学航空学院,南京 210016南京航空航天大学航空学院,南京 210016
数理科学
时频分析非平稳信号二次调频模态混叠抑制
time-frequency analysisnon-stationary signalsquadratic chirplet modulationmode-mixing suppression
《南京航空航天大学学报(自然科学版)》 2026 (3)
696-708,13
国家自然科学基金(12272172).
评论