Friday, June 28, 2019

Terahertz Imaging Deconvolution Method Proposed to Enhance Resolution


THz imaging of Human hair. From left: photo of hair sample, THz image before enhancement, THz image after enhancement. (Image by QI Feng)  
http://english.cas.cn/newsroom/research_news/201906/t20190627_212170.shtml

QI Feng and his team at Terahertz Imaging Laboratory, Shenyang Institute of Automation of the Chinese Academy of Sciences, demonstrated a terahertz (THz) imaging deconvolution method which is able to image at the sub-spot level to achieve high-resolution THz images.
Their finding, published in IEEE Access, showed that phase information of THz waves is fully utilized by making use of the wave nature of THz light. The study demonstrated that the reconstructed phase can also describe the shape of the object by applying such an approach.
THz imaging is quite promising in scientific and biomedical applications. Current spatial resolution of THz imaging systems is not perfect due to its much longer wavelength compared to visible light. Many scientists have been working on near-field imaging systems to achieve a high resolution image. However, in this system objects have to be placed extremely close to the sensors, which is difficult to achieve in practical applications.
How to extract information beyond the physical limit of the beam size is important. Generally, imaging is considered to be a convolution process and the point spread function essentially blurs the figure. THz light, as a kind of electromagnetic waves, has both amplitude and phase information. Optical image processing algorithms are based on geometrical optics and only intensities are considered.
To evaluate the spatial resolution quantitatively, the researchers in this study fabricated a periodic structure sample with three 0.8 mm bar patterns. This sample can be resolved well at 0.3 THz, and the resolution is 0.32 times of the physical size of the focused beam.
In addition, they successfully measured the diameter of human hair with a relative error of less than 10% at 3 THz.
This study demonstrates a promising method that will be helpful for providing clearer imaging for scientific and biomedical applications.

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