利用低成本光谱仪估算微藻密度和质量：利用进化优化进行近红外-可见光谱建模

IF 2.2 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE Sensors Letters Pub Date : 2024-10-24 DOI:10.1109/LSENS.2024.3484432

W. K. Wong;Yuan Ju Teoh;Filbert H. Juwono;Jessica Ling;Sie Yon Lau

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引用次数: 0

摘要

由于高细胞密度下的非线性特性，估算微藻浓度并非易事。传统的估算方法是细胞计数，这种方法既耗时又会导致读数不准确。另一种方法是光谱反射法，通过使用与微藻中色素吸收直接对应的特定波长，可提供更精确的测量，从而更快地确定细胞密度和生物量。遗憾的是，该实验通常是在实验室中使用昂贵的高分辨率设备进行的。在这封信中，我们建立了一个低成本、基于物联网的实时光谱原型传感器，用于估算微藻的密度和质量。该设备使用的波长范围为 400-1000 纳米，因此分辨率较低。采用多重表达式编程为测量数据建模。结果表明，非线性模型性能更好，两种微藻的 R^{2}$ 值从 0.93 到 0.99 不等。

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Microalgal Density and Mass Estimation Using Low-Cost Spectrometer: NIR-VIS Modeling With Evolutionary Optimization

Estimating microalgal concentration can be a nontrivial endeavor due to their nonlinearity at high cell densities. The conventional estimation method is cell counting, which is time consuming and leads to inaccurate readings. Alternatively, spectral reflectance provides a more precise measurement by using specific wavelengths that correspond directly to pigment absorption in microalgae, allowing for faster determination of cell density and biomass. Unfortunately, the experiment is usually conducted in the laboratory with expensive and high-resolution devices. In this letter, we build a low-cost, real-time Internet-of-Things-based spectral prototype sensor for estimating density and mass of microalgae. The device uses wavelengths in the range of 400–1000 nm, making it low resolution. Multi expression programming is employed to model the measured data. Results show that nonlinear models perform better with

$R^{2}$

values spanning from 0.93 to 0.99 for two species of microalgae.

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来源期刊

IEEE Sensors Letters Engineering-Electrical and Electronic Engineering

CiteScore

3.50

自引率

7.10%

发文量

194