Journal of Infrared and Millimeter Waves

ESIT 2024: Gathering of Global Minds to Hangzhou for Cutting-Edge Infrared and Terahertz Innovation
Welcome to our new Editorial Board Members Prof. Manijeh Razeghi
Welcome to our new Editorial Board Members Dr. He Zhiping
Welcome to our new Editorial Board Members Dr. Jun Ge
Welcome to our new Editorial Board Members Dr. Ye Zhenhua
Welcome to our new Editorial Board Members Dr. Chen Fansheng

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YOLO-Fastest-IR: Ultra-lightweight thermal infrared face detection method for infrared thermal camera

Xicai Li, Jiahe Zhu, Pengxiang Dong, and Yuanqing Wang

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This paper presents a high-speed and robust dual-band infrared thermal camera based on an ARM CPU. It is composed of a low-resolution long-wavelength infrared detector, a digital temperature and humidity sensor, and a CMOS sensor. In view of the phenomenon of large contrast between face and background in thermal infrared image, this paper we search for a suitable accuracy-latency tradeoff for thermal face detection and propose a tiny-lightweight detector named YOLO-Fastest-IR. Four different scale YOLO-Fastest-IR0 to IR3 thermal infrared face detectors based on YOLO-Fastest are designed. To train and test four tiny-lightweight models, a multi-user low-resolution thermal face database (RGBT-MLTF) is collected, and the four networks are trained. Experiments reveal that the lightweight convolutional neural network can also perform well in the thermal infrared face detection task. And the algorithm is superior to the existing face detection algorithms in positioning accuracy and speed, which is more suitable for deployment in mobile platforms or embedded devices. After obtaining the region of interest in the infrared image (IR), the RGB camera is guided by the results of thermal infrared face detection, to realize the fine positioning of RGB face. The experimental results show that YOLO-Fastest-IR has a frame rate of 92.9 FPS on a Raspberry Pi 4B and can successfully locate 97.4% of the face in the RGBT-MLTF test set. The integration of infrared temperature measurement system with low cost, strong robustness and high real-time performance was ultimately achieved, the temperature measurement accuracy can reach 0.3 degrees Celsius.
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Precise calculation of radiation heat of cryogenic infrared detector Dewar

zengchanghang, CHEN Jun, LI Si

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The thermal load of the cryogenic infrared detector Dewar is a comprehensive indicator characterizing the adiabatic capacity of the Dewar. Radiative heat is a part of the thermal load. When calculating the radiative heat ,the traditional approach typically simplifies the Dewar to a coaxial cylindrical model. This simplified model differs significantly from the actual one and the traditional approach is incapable of computing the radiative heat transfer between surfaces where emissivity, transmittance, and reflectance vary with wavelength. To enhance the calculation accuracy of the Dewar's radiative heat, based on the Monte Carlo principle, a 3D Studio Max modeling was employed, model information was extracted, and a program was developed, resulting in a set of general calculation programs for the Dewar's radiative heat based on the radiation transfer factor. To preliminarily verify the accuracy of the calculation program, the cold side radiative heat of two types of experimental Dewars was calculated under the gray body assumption and the errors between the calculated and experimental values were 19 mW and 8 mW. After the initial verification of the calculation program's accuracy, considering the variations of the material surface emissivity, transmittance, and reflectance with wavelength and the influence of temperature on the radiation wavelength, the cold side radiative heat of a typical 1K×1K long-wave Dewar for engineering applications was calculated. The error between the calculated and experimental values was 17 mW. Finally, the entire radiative heat of a typical 1K×1K long-wave Dewar, a typical 1K×1K medium-wave Dewar, and a typical 640×512 medium-wave Dewar when the window surface was facing a gray body with an emissivity of 0.9 was calculated. Among them, the calculated radiative heat of the 1K×1K long-wave Dewar was 176 mW, accounting for 52% of the thermal load; the calculated radiative heat of the 1K×1K medium-wave Dewar was 166 mW, accounting for 49% of the thermal load; and the calculated radiative heat of the 640×512 medium-wave Dewar was 74 mW, accounting for 37% of the thermal load.
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A novel photonic crystal waveguide multifunctional light-emitting beaming device

Liu Ze-Kun, Hua Chang-Zhou

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Based on two-dimensional triangular lattice photonic crystal, a multi-functional device of two-dimensional photonic crystal waveguide light-emitting beaming with integrated filtering function is designed, which can realize the fusion of outgoing light beaming and specific wavelength efficient filtering. The beam structure of the emitting light is similar to the grating structure, and the beam is in the state of clustering through the mutual interference principle between the multi-channel, which improves the radiation efficiency and distance of the emitting light. The finite difference time domain method can be used to obtain the effective propagation distance of 450 at the incident wavelength of 1.447. The structure design has a good beaming ability for incident light in the range of 1.435~1.465. At the same time, there are two hexagonal coupled filtering structures on either side of the waveguide, which are close to 98.4% and 97.3% transmission efficiency for incident light waves with a central wavelength of 1.490 and 1.510, respectively.The fusion structure successfully realizes the filtering and clustering functions.
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Research on infrared imaging technology of gas plumes based on the vibe gases algorithm

yangzhen

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When a gas leaks, it spreads in space by diffusion, and a dynamically stable plume of concentration usually forms near the leak source, presenting an approximate "static" region in the infrared image. This characteristic often leads to the accuracy of the commonly used moving object detection algorithm in these regions is reduced, and it is difficult to obtain the spatial concentration distribution of gas. To solve this problem, an adaptive threshold detection algorithm of Vibe Gases based on background subtraction method is proposed in this paper, and two key phases of gas plume imaging are improved. In the foreground extraction stage, the foreground difference matrix is constructed by gas detection logic and two-dimensional frequency mapping is carried out. Then the difference distribution function is fitted by least square method to calculate the optimal threshold of foreground and background separation. In the background update stage, the signal matrix of the foreground gas is constructed and two-dimensional frequency mapping is carried out. The main signal range is extracted by high-pass filtering, and the pixels located in the gas region and within the main signal range are delayed updated. The infrared detection imaging experiment shows that the detection accuracy index of ethylene at 20 meters is 91.0% and the intersection ratio index is 89.4% when the gas leakage reaches stability. The detection accuracy index of small leakage sulfur hexafluoride at 5 meters is 81.3%, and the intersection ratio index is 80.7%. The algorithm significantly improves the imaging quality of the gas plume, enhances the adaptability of detection to different gases and scenes, and effectively extracts the gas concentration distribution.
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Multimodal Remote Sensing Image Fusion Based on Self-supervised Pre-training and Cross-scale Contrastive Learning

LI Zhao-Wei, FENG Shi-Yang, 王斌

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Self-supervised pre-training methods have strong capabilities in feature extraction and model transfer. However, current pre-training methods in multimodal remote sensing image (RSI) fusion only perform simple fusion operations such as concatenation on the extracted multimodal features without designing dedicated modules for the integration of multimodal information, leading to insufficient fusion of complementary information across modalities. Secondly, these methods do not consider and utilize the cross-scale consistency priors within RSIs, resulting in limited extraction and integration of multimodal remote sensing information, and thus the performance of various downstream tasks needs to be improved. In response to the above issues, a multimodal RSI fusion method based on self-supervised pre-training and cross-scale contrastive learning is proposed, which mainly includes three parts: 1) By introducing a cross-attention fusion mechanism to preliminarily integrate features extracted from different modalities, and then using encoder modules to further extract features, explicit aggregation and extraction of complementary information from each modality are achieved; 2) By introducing a cross-modality fusion mechanism, each modality can extract useful supplementary information from the features of all modalities, and reconstruct each modality’s input after separate decoding; 3) Based on the cross-scale consistency constraints of RSIs, cross-scale contrastive learning is introduced to enhance the extraction of single-modality information, achieving more robust pre-training. Experimental results on multiple public multimodal RSI fusion datasets demonstrate that, compared with existing methods, the proposed algorithm has achieved significant performance improvements in various downstream tasks. On the Globe230k dataset, our method achieves an average intersection over union (mIoU) of 79.01%, an overall accuracy (OA) of 92.56%, and an average F1 score (mF1) of 88.05%, and it has the advantages of good scalability and easy hyperparameter setting.
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Research on key technologies of 220 GHz integrated T/R module

YAO Chang-Fei, WENG Lv-Tao, DONG Wen-Chao, CHEN Si-Yu, WANG Hao, WANG Wen-Wei, LIU Qiang, ZHU Ming

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A transceiver module operating at the 220 GHz frequency band was developed, consisting of three parts: a local oscillator chain, a transmitter chain, and a receiver chain, featuring high integration. A 218~226 GHz waveguide bandpass filter was designed to suppress spurious signals in the chain. The filter adopts a dual-mode resonant cavity structure to introduce a transmission zero on the left side of the passband, which suppresses the 214 GHz spurious signal by 60 dBc. An improved E-plane magic-T structure was used to form a four-way power combining amplifier to meet the requirement of transmit power. This module achieves a power combining efficiency of 72.5% and the output power is higher than 82 mW. The measured results show that in the 219.5~221 GHz frequency range, the transmit power is 82~95 mW, the noise figure of the receiver is less than 7.1 dB, the receive gain is 5.1~6.0 dB, and the volume of module is 65×70×30 mm3.
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Development of an active-detection mid-wave infrared search and track system based on "cat-eye effect"

ZHOU Pan-Wei, DING Xue-Zhuan, LI Fan-Ming, YE Xi-Sheng

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In order to meet the urgent need of infrared search and track applications for accurate identification and positioning of infrared guidance aircraft, an active-detection mid-wave infrared search and track system (ADMWIRSTS) based on "cat-eye effect" was developed. The ADMWIRSTS mainly consists of both a light beam control subsystem and an infrared search and track subsystem. The light beam control subsystem uses an integrated opto-mechanical two-dimensional pointing mirror to realize the control function of the azimuth and pitch directions of the system, which can cover the whole airspace range of 360°×90°. The infrared search and track subsystem uses two mid-wave infrared cooled 640×512 focal plane detectors for co-aperture beam expanding, infrared and illumination laser beam combining, infrared search, and two-stage track opto-mechanical design. In this work,the system integration design and structural finite-element analysis were conducted, the search imaging and two-stage track imaging for external scenes were performed, and the active-detection technologies were experimentally verified in the laboratory. The experimental investigation results show that the system can realize the infrared search and track imaging and the accurate identification and positioning of the mid-wave infrared guidance or infrared detection system through the echo of the illumination laser. The aforementioned work has important technical significance and practical application value for the development of compactly-integrated high-precision infrared search and track and laser suppression system, and has broad application prospects in the protection of equipment, assets and infrastructures.
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A Novel W-band Substrate Integrated Microstrip to Ultra-thin Cavity Filter Transition

CAO Yi, TANG Xiao-Hong, LIU Yong, CAI Zong-Qi

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Abstract—A novel substrate integrated microstrip to ultra-thin cavity filter transition operating in the W-band is proposed in this letter. The structure is a new method of connecting microstrip circuits and waveguide filters, and this new structure enables a planar integrated transition from microstrip lines to ultra-thin cavity filters, thereby reducing the size of the transition structure and achieving miniaturization. The structure includes a conventional tapered microstrip transition structure, which guides the electromagnetic field from the microstrip line to the reduced-height dielectric-filled waveguide, and an air-filled matching cavity which is placed between the dielectric-filled waveguide and the ultra-thin cavity filter. The height of the microstrip line, dielectric-filled waveguide and the ultra-thin cavity filter are the same, enabling seamless integration within a planar radio-frequency (RF) circuit. To facilitate testing, mature finline transition structures are integrated at both ends of the microstrip line during fabrication. The simulation results of the fabricated microstrip to ultra-thin cavity filter transition with the finline transition structure, with a passband of 91.5-96.5 GHz, has an insertion loss of less than 1.9 dB and a return loss lower than -20 dB. And the whole structure has also been measured which achieves an insertion loss less than 2.6 dB and a return loss lower than -15dB within the filter's passband, including the additional insertion loss introduced by the finline transitions. Finally, a W-band compact up-conversion module is designed, and the test results show that after using the proposed structure, the module achieves 95 dBc suppression of the 84 GHz local oscillator. It is also demonstrated that the structure proposed in this letter achieves miniaturization of the system integration without compromising the filter performance.
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Design of a wideband non-uniform microstrip line for complex impedance matching at automotive radar frequency

ZHANG Shuang-Gen, YU Tao, WANG Yu-Lan, CHENG Zhi-Hua, YAO Jian-Quan

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Microstrip transmission lines connecting to the millimeter wave radar chip and antenna significantly impacts on the radiation efficiency and bandwidth of the antenna. Here, a wideband non-uniform wavy microstrip line for complex impedance at automotive radar frequency range is proposed. Different to the gradient transmission line, the wavy structure is composed of periodically semi-circular segments. By adjusting the radius of the semi-circular, the surface current varied and concentrated on the semi-circular segments, allowing a wider tunability range of the resonant frequency. The results reveal that the bandwidth of the loaded wavy transmission line antenna improves up to 9.37 GHz, which is 5.81 GHz wider than that of the loaded gradient line. The gain and the half power beam width of the loaded antenna are about 14.69 dB and 9.58°, respectively. The proposed non-uniform microstrip line scheme may open up a route for realizing wideband millimeter wave automotive radar applications.
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Fabrication and characterization of InGaAs/InAlAs photoconductive terahertz detection antenna with dynamic range exceeding 75 dB

JIANG Qing-Nan, TAN Zhi-Yong, WAN Wen-Jian, FU Zhang-Long, XIA Yu, LI Min, CAO Jun-Cheng

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The photoconductive antenna is a very important device in the terahertz region and is widely used in terahertz time-domain spectroscopy technology. This article uses the molecular beam epitaxy method to grow Be-doped InGaAs/InAlAs superlattice as light absorbing materials for 1550 nm laser pumped photoconductive antenna for terahertz detection. The prepared materials have a sheet resistance greater than 106^{Ω/sq and an electron mobility of 216 cm}2^{/(Vs); The active} mesa and electrode structure of the detection antenna are prepared using wet etching and magnetron sputtering processes, and the antenna chip is packaged on a PCB board. A detection antenna measurement system is built by employing a domestically produced 1550 nm femtosecond pump laser, and the detection antennas with electrode gaps of 40 μm and 60 μm were characterized; The measurement results indicate that the 60 μm antenna has a wider spectral width and power dynamic range, reaching 4.0 THz and 77.0 dB, respectively.
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Volume 43,2024 Issue 6

Infrared Physics, Materials and Devices

Millimeter Waves and Terahertz Technology

Infrared Spectroscopy and Remote Sensing Technology

Infrared Optoelectronic System and Application Technology

Interdisciplinary Research on Infrared Science

红外物理与材料器件

Infrared Physics, Materials and Devices

Interdisciplinary Research on Infrared Science

红外物理与材料器件

Millimeter Waves and Terahertz Technology

Infrared Physics, Materials and Devices

红外物理与材料器件

Interdisciplinary Research on Infrared Science

红外物理与材料器件

Infrared Optoelectronic System and Application Technology

Interdisciplinary Research on Infrared Science

红外物理与材料器件

Infrared Physics, Materials and Devices

Interdisciplinary Research on Infrared Science

Millimeter Waves and Terahertz Technology

Application of Optical-Biomedical Fusion and Imaging Technology

红外物理与材料器件

毫米波与太赫兹技术

Interdisciplinary Research on Infrared Science

Infrared Physics, Materials and Devices

Infrared Optoelectronic System and Application Technology

Infrared Physics, Materials and Devices

Interdisciplinary Research on Infrared Science

Infrared Physics, Materials and Devices

Volume 43,2024 Issue 6

Infrared Spectroscopy and Remote Sensing Technology

Interdisciplinary Research on Infrared Science

Remote Sensing Technology and Application

Interdisciplinary Research on Infrared Science

Infrared Physics, Materials and Devices

Millimeter Waves and Terahertz Technology

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