Evaluation of highly sensitive vibration states of nanomechanical resonators in liquid using a convolutional neural network

IF 2.8 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC Micro and Nano Engineering Pub Date : 2024-09-01 DOI:10.1016/j.mne.2024.100282
Kazuki Bessho, Shin’ichi Warisawa, Reo Kometani
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Abstract

Nanomechanical resonators can detect various small physical quantities with high sensitivity using changes in resonant properties. However, viscous damping in liquids significantly reduces the measurement sensitivity. This study proposes convolutional neural network (CNN) vibration spectrum analysis to evaluate the highly sensitive vibration states of nanomechanical resonators, which are useful for in-liquid measurements. This research was carried out through the measurement of acetone concentration. First, we compared the concentration classification ability between the proposed and conventional methods and determined that the proposed method of analyzing vibration spectral changes using the CNN model can provide higher measurement sensitivity than the conventional measurement method of observing resonance properties changes and comparing the values for each measurement condition. This result shows that CNN-based spectral analysis is effective for the vibration spectra of in-liquid measurements. Next, gradient-weighted class activation mapping (Grad-CAM) was applied to verify which frequency bands are important for concentration classification in CNN model decision-making. The vibration states in these frequency bands were analyzed in terms of oscillation modes. This analysis revealed significant oscillation modes of the nanomechanical resonator in the liquid environment. Notably, in addition to the resonance states utilized in the conventional method, several other oscillation modes were found to be significant for measurements. This finding suggests that these oscillation modes may be highly sensitive for measurements in liquid environments. Among these oscillation modes, the mode with very small amplitude is highly promising for achieving unprecedented levels of sensitivity in sensing technologies.

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利用卷积神经网络评估液体中纳米机械谐振器的高灵敏度振动状态
纳米机械谐振器可以利用谐振特性的变化,高灵敏度地探测各种微小物理量。然而,液体中的粘性阻尼会大大降低测量灵敏度。本研究提出了卷积神经网络(CNN)振动谱分析来评估纳米机械谐振器的高灵敏度振动状态,这对液体测量非常有用。本研究通过丙酮浓度测量进行。首先,我们比较了拟议方法和传统方法的浓度分类能力,结果表明,与观察共振特性变化并比较各种测量条件下的数值的传统测量方法相比,拟议的使用 CNN 模型分析振动频谱变化的方法能提供更高的测量灵敏度。这一结果表明,基于 CNN 的频谱分析对于液内测量的振动频谱非常有效。接着,应用梯度加权类激活映射(Grad-CAM)来验证 CNN 模型决策中哪些频段对浓度分类很重要。从振荡模式的角度分析了这些频段的振动状态。该分析揭示了纳米机械谐振器在液体环境中的重要振荡模式。值得注意的是,除了传统方法中使用的共振状态外,还发现其他几种振荡模式对测量也很重要。这一发现表明,这些振荡模式可能对液体环境中的测量高度敏感。在这些振荡模式中,振幅极小的模式很有希望在传感技术中实现前所未有的灵敏度。
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来源期刊
Micro and Nano Engineering
Micro and Nano Engineering Engineering-Electrical and Electronic Engineering
CiteScore
3.30
自引率
0.00%
发文量
67
审稿时长
80 days
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