See How Multiphysics Simulation Is Used in Research and Development
Engineers, researchers, and scientists across industries use multiphysics simulation to research and develop innovative product designs and processes. Find inspiration in technical papers and presentations they have presented at the COMSOL Conference. Browse the selection below or use the Quick Search tool to find a specific presentation or filter by application area.
View the COMSOL Conference 2023 Collection
Analysis and Development of Koch Fractal Dipole Antennas
Devices of mobile communication require smallest sizes of antennas. This is one of the applications of fractal antennas which have reduced size or are multiband and can be used for mobile phone, RFID, Wi-Fi, digital TV, among other applications. The Koch fractal geometry allows better ... Read More
Analysis of 1D, 2D, and 3D Marine CSEM in COMSOL Multiphysics® Software
The Marine Controlled Source ElectroMagnetic (marine CSEM) is a geophysical method used by the oil industry to investigate resistive targets in the sediments under the ocean floor. In this work we simulate marine CSEM data including 1D, 2.5D and 3D modeling. The results obtained with ... Read More
Simulations of Negative Curvature Hollow-core Fiber
COMSOL Multiphysics® software was used to simulate and analyze the transmission attenuation spectra of the negative curvature hollow-core fiber (NCHCF) over the wavelength from 2.7 μm to 4.2 μm. The effect of thickness of capillaries and the effect of the distance between the capillaries ... Read More
The Simulation of Motion of a Slider upon a Stator Due to Frictional Force Using COMSOL Multiphysics® Software
The Surface Acoustic Wave (SAW) linear motor was studied which is developed utilizing the friction principle for driving. The principle says that, when a slider is placed on the Rayleigh waves generated on a stator, the slider moves in reverse direction of the wave due to friction ... Read More
Electromagnetic Well Logs Simulated with the COMSOL® RF Module on a Cluster
Introduction Computer simulations are widely used for the interpretation and inversion of electromagnetic measurements in well logging. Until recently, simulated logs have been computed with approximate 1D or 2D models. By using the COMSOL® RF Module installed on a cluster, we show that ... Read More
基于变换光学算法的薄壁结构微波加热优化
在微波加热的多物理场仿真中,如果被加热物体的几何区域太小或者太薄,会造成整个模型网格剖分困难、网格数量多且计算消耗内存大等问题。本文针对微波加热时薄壁容器的网格剖分困难,网格数量大,且占用计算机内存资源多的问题,提出了一种基于变换光学算法的微波薄壁加热模型计算优化方法。利用变换光学算法将薄壁区域空间扩大,通过改变薄壁区域内的介质参数来与原模型进行空间映射,从而避免网格剖分过程中的薄壁问题出现,这样可以在同样的网格剖分设置下减少整个模型的网格数量,节省计算时间,减少计算机内存资源的占用。通过相应的公式推导,在二维模型中实现了薄壁变换光学算法的计算 ... Read More
基于金属波导的结构色散实现各向异性超材料
近年来,一些研究人员基于金属波导的结构色散实现了各向同性的波导超材料,并研究了其各种各样的应用。然而,各向异性的波导超材料却没有得到深入的研究。我们利用金属平板/矩形波导在TEm模式下的结构色散,并在波导内部周期性交替填充两种不同的电介质A和B,并辅以细金属线连接上下金属板,从而可以将整个波导系统等效成二维TM偏振下的各向异性有效介质。我们发现在金属波导内沿着A-B多层介质的两个光轴方向存在两个不同的截止频率。当工作频率处在这两个截止频率范围内时,整个波导系统等效后的有效介质等频率曲线呈现出双曲函数的形式,即实现了双曲型波导超材料;当工作频率在较高的截止频率附近时 ... Read More
金属隔板对谐振腔加热效率及加热均匀性影响研究
在微波加热中,其加热效率及加热均匀性一直是研究的热点问题。本文利用COMSOL Multiphysics多物理场仿真软件的RF模块对一个长方体谐振腔的电磁功率分布进行仿真研究。对谐振腔内环氧树脂材料负载上的电磁功率、功率变异系数以及归一化体积等特征值进行对比分析,研究改变腔内金属隔板的几何形状、尺寸对负载加热效率及加热均匀性的影响。仿真结果表明:在谐振腔内部增加金属板能够提高加热效率,隔板几何的变化会影响加热效率和加热均匀性。最终文中给出了当隔板分别为正方形、圆形时,获取加热效率较高同时加热均匀性较稳定对应的隔板参数设置。研究结论可以为谐振腔的设计提供指导意见。 Read More
基于光学零空间介质的角反射器
基于光学零空间介质定向投影性质,提出了设计形状任意的角反射器的方法。设计过程中仅需对角反射器入射面和出射面形状进行设计,然后利用光学零空间介质进行填充哦,只要保证入射面和出射面上的点经过零空间介质投影后满足80度的反转对应关系,即可实现角反射器的效果。角反射器可以被设计为各种不同形状,比如超薄平板结构(厚度为波长的2/3),所有不同形状的角反射器都只需要一种均匀的各向同性材料(光学零空间介质)即可实现。借助于COMSOL波动光学模块对提出的角反射器的性质进行了验证和模拟分析。模拟结果表明,在宽入射角范围角反射器都具有很高的角反射效率。 Read More
微波腔自旋电子学——基于微磁学模块和射频模块的多物理场仿真
微波腔自旋电子学(Spin Cavitronics)是自旋电子学与腔量子电动力学之间的交叉领域。微波腔量子电动力学的应用之一就是利用光与物质的相互作用实现量子信息的处理,而自旋波在量子尺度下即是磁振子,是一种玻色子,磁振子与微波腔内的光子能够强耦合,实现信息在两种不同媒质中的交换。微波腔自旋电子学的一种典型的研究方法为将磁性小球置于微波腔中,通过调节施加在磁性小球上的外加磁场大小来使其与微波腔内的电磁波驻波模式(亦称为腔模)实现强耦合。这种自旋波与电磁波之间的相互作用(磁振子与光子的耦合)为自旋流的调控以及研究磁矩的非线性动力学行为提供了新的方法。在微波腔中 ... Read More