Journal of Infrared and Millimeter Waves

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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A lightweight dark object detection network on infrared images

LI Zhao-xu, XU Qing-yu, AN Wei, HE Xu, GUO Gao-wei, LI Miao, LING Qiang, Wang Long-guang, XIAO Chao, LIN Zaiping

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Small object detection has been a classic problem in the field of infrared image processing, and the objects are usually brighter than the local background they are in. However, in some scenarios, the target brightness may be lower than the background brightness. For example, the civil aircrafts usually has low-temperature skin when cruising, appearing as dark points on medium spatial resolution thermal infrared satellite images. There are few features of these objects, so the current detection network structure has redundancy. Hence, we proposed a lightweight dark object detection network, AirFormer. It only has 37.1K parameters and 46.2M floating-point operations on a 256256 image. Considering the lack of infrared dark object detection dataset, we analyzed the characteristics of aircrafts on thermal infrared satellite images, and then developed a simulated flying aircraft detection dataset called IRAir. Our proposed AirFormer achieves 71.0% at recall and 82.6% at detection precision on the IRAir dataset. Based on simulated training data, AirFormer achieves detection of real flying aircrafts on the thermal infrared satellite images.
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The Research on Aircraft Altitude Estimate Method Based on Multispectral Feature Matching in Thermal Infrared

YANG Li-Feng, CHEN Zhuo, CHEN Fan-Sheng, WANG Jian-Yu

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Abstract:

The acquisition of aircraft altitude information is crucial for the aviation safety and traffic control applications. Infrared remote sensing technology can accurately measure the thermal radiation information of targets, which means the potential for quantitative observation of certain characteristics of aircraft target. A method for estimating the altitude of airborne targets based on infrared multi-channel feature matching is proposed in this paper. Firstly, a thermal infrared radiation characteristic observation model of aircraft is established, which based on the thermal infrared radiation characteristics of large aircraft and atmospheric radiative transfer models. Secondly, based on the observation model, a spectral database of aircrafts at different altitudes and flight states under different atmospheric condition can be obtained by simulating. Thirdly, target spectral information can be extracted from remote sensing images and the altitude information can be estimated with using spectral angle matching (SAM). Finally, verification and analysis were completed using simulation data and SDGSAT-1 in-orbit data. The results indicate that the proposed method can achieve kilometer-level estimation accuracy for aircraft at cruising altitude. This method provides a new solution for estimating the altitude of aircraft and has important application potential.
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Research on highly sensitive infrared imaging detection technology based on linear avalanche device

Lin Chang-qing, ZHOU Shuang-xi, LI Lu-fang, LIU Gao-rui, SUN Hai-bin, ZHANG Yu, LIN Jia-mu, SUN Sheng-li

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Abstract:

With the development of remote sensing technology, the detection sensitivity of infrared system is increasingly required. The infrared imaging detection technology based on linear avalanche device can effectively improve the detection sensitivity in high frame frequency applications. Based on the short-wave infrared linear avalanche detector assembly of 512X512, a small-aperture and lightweight infrared imaging system is designed and its performance is tested under low reverse bias. The test results show that the increase of SNR of the imaging system based on the linear avalanche infrared detector is basically linear with the multiplication factor M under short integration time, and the SNR of the system is 3 times that of the traditional camera of the same caliber.
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Infrared aircraft few-shot classification method based on cross-correlation network

HUANG Zhen, ZHANG Yong, Gong Jin-Fu

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In response to the scarcity of infrared aircraft samples and the tendency of traditional deep learning to overfit, a few-shot infrared aircraft classification method based on cross-correlation networks is proposed. This method combines two core modules: a simple parameter-free self-attention and cross-attention. By analyzing the self-correlation and cross-correlation between support images and query images, it achieves effective classification of infrared aircraft under few-shot conditions. The proposed cross-correlation network integrates these two modules and is trained in an end-to-end manner. The simple parameter-free self-attention is responsible for extracting the internal structure of the image while the cross-attention can calculate the cross-correlation between images further extracting and fusing the features between images. Compared with existing few-shot infrared target classification models, this model focuses on the geometric structure and thermal texture information of infrared images by modeling the semantic relevance between the features of the support set and query set, thus better attending to the target objects. Experimental results show that this method outperforms existing infrared aircraft classification methods in various classification tasks, with the highest classification accuracy improvement exceeding 3%. In addition, ablation experiments and comparative experiments also prove the effectiveness of the method.
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Design and validation of RLC equivalent circuit model based on long-wave infrared metamaterial absorber

ZHAO Ji-Cong, DANG Yan-Meng, HOU Hai-Yang, LIN Ye-Fan, SUN Hai-Yan, ZHANG Kun

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Abstract:

In this paper, we propose an RLC equivalent circuit model theory which can accurately predict the spectral response and resonance characteristics of metamaterial absorption structures, extend its design, and characterize the parameters of the model in detail. By employing this model, we conducted computations to characterize the response wavelength and bandwidth of variously sized metamaterial absorbers. A comparative analysis with Finite Difference Time Domain (FDTD) simulations demonstrated a remarkable level of consistency in the results. The designed absorbers were fabricated using micro-nano fabrication processes, and was experimentally tested demonstrate absorption rates exceeding 90% at a wavelength of 9.28 μm. The predicted results are then compared with test results. The comparison reveals good consistency in two aspects of the resonance responses, thereby confirming the rationality and accuracy of this model.
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Dual-band narrowband thermal emitter designed based on multi-objective particle swarm optimization

QIU Qianli, ZHANG Jinguo, ZHOU Dongjie, TAN Chong, SUN Yan, HAO Jiaming, DAI Ning

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Abstract:

Dual-band thermal emitters with narrow bandwidths are important in various applications in the infrared field, such as in infrared sensing and infrared imaging. However, conditions for narrowband emission in different wavelengths can conflict with each other, making it difficult to achieve dual-band emitter. In this paper, a new type of lithography-free infrared dual-band thermal emitter is proposed, which consists of alternately deposited Ge and YbF3 films on Al films. The narrowband emission characteristics stem from the Tamm plasmon polaritons (TPP) that can be excited by the distributed Bragg reflector and the Al substrate under certain conditions. The geometric parameters are optimized using multi-objective particle swarm optimization. The experiment results confirm thatSdual-band emitterScan simultaneously exhibit narrowband emitter characteristics in bothSmid-wave infrared (MWIR)SandSlong-wave infrared (LWIR)Sregions. The proposed method can be used in the design of multi-band emitssion modulation applications, which can be applied in the fields of multi-gas sensing and multi-band infrared camouflage.
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Synchronous Object Detection and Matching Network Based on Infrared Binocular Vision

ZENG Chang-Wen, YANG Zhi-Yu, DAI Zuo-Xiao, GU Ming-Jian

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Abstract:

The three-dimensional perception of road objects in challenging environments is crucial for the development of autonomous vehicles capable of operating in all conditions, at all hours. Infrared binocular vision mimics the human binocular system, facilitating stereoscopic perception of objects in challenging conditions such as dim or zero-light environments. The core technology for stereoscopic perception in binocular vision systems lies in accurate object detection and matching. In response to the inefficiency of the sequential implementation of object detection and matching, a synchronous object detection and matching network (SODMNet) is proposed, which is capable of synchronous detection and matching of infrared objects. SODMNet innovatively combines a object detection network with a object matching module, leveraging the deep features from the classification and regression branches as inputs for the object matching module. By concatenating these features with relative position encodings from the feature maps and processing them through a convolutional network, the network generates feature descriptors for the left and right images. The object matching is then achieved by calculating the Euclidean distances between these descriptors, thus facilitating synchronous object detection and matching in binocular vision. In addition, a novel nighttime infrared binocular dataset, annotated with targets such as pedestrians and vehicles, is presented to support the development and evaluation of the proposed network. Experimental results indicate that SODMNet achieves a significant improvement of over 84.9% in object detection mean average precision (mAP) on this dataset, with a object matching average precision (AP) of 0.5777. These results demonstrate that SODMNet is capable of high-precision, synchronized object detection and matching in infrared binocular vision, marking a significant advancement in the field.
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Wideband and High Power 3D Heterogeneous Integration Photoreceiver

XU Xiangqian, GONG Guangyu, SUN Lei, LI Yu, Kang Xiaochen, LI Simin, PAN Shilong

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In this study, we present an innovative three-dimensional (3D) heterogeneously integrated photoreceiver, which is optimized for analog microwave optical links that demand both wide bandwidth and high input optical power. The key of this design is the uni-traveling-carrier photodiode (UTC-PD), which has been flip-chip integrated onto a microwave integrated circuit submount. This integration approach enhances the photoreceiver"s overall performance, making it ideally suitful for applications requiring wide bandwidth and high power handling capabilities. The material doping and epitaxial processes of the UTC photodiode were optimized to augment its power endurance. Meanwhile, the responsivity of the photodiode was improved through the adoption of an integrated back-illuminated lens complemented by the addition of a metallic reflective layer. By establishing a precise model of the photodiode, we have refined the bandwidth characteristics of the photoreceiver using impedance compensation and broadband matching circuit design techniques. Flip-chip bonding the photodiode chip onto the microwave integrated circuit chip has substantially mitigated the impact of interconnect circuits on high-frequency performance. Furthermore, the thermal conductivity and high-power resilience of the detector chip were enhanced via gold-tin alloy micro-bump interconnections and the design of a high thermal conductivity substrate layer. The three-dimensional heterogeneous integrated photoreceiver features a 1-dB bandwidth of 42 GHz, an RF return loss exceeding 11 dB, a responsivity surpassing 0.85 A/W, a dark current below 50 nA, and a saturated input optical power of over 120 mW.By leveraging the distinctive properties of the UTC-PD, our three-dimensional (3D) heterogeneous integrated photoreceiver design achieves superior efficiency and responsiveness, positioning it as a leading solution for cutting-edge microwave photonics applications.
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Semi-Floating Gate Ferroelectric Phototransistor Optoelectronic Integrated Devices

SHANG Jia-Le, CHEN Yan, YAN Hao-Ran, DI Yun-xiang, HUANG Xin-Ning, Lin Tie, MENG Xiang-Jian, WANG Xu-Dong, CHU-Jun-Hao, WANG Jian-Lu

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Abstract:

In the realm of optoelectronics, photodetectors play a pivotal role, with applications spanning from high-speed data communication to precise environmental sensing. Despite the advancements, conventional photodetectors grapple with challenges with response speed and dark current. In this study, we present a photodetector based on a lateral MoTe₂ p-n junction, defined by a semi-floating ferroelectric gate. The strong ferroelectric field and the depletion region of the p-n junction in the device are notably compact, which serves to diminish the carrier transit time, thereby enhancing the speed of the photoelectric response. The non-volatile MoTe₂ homojunction, under the influence of external gate voltage pulses, can alter the orientation of the intrinsic electric field within the junction. As a photovoltaic detector, it achieves an ultra-low dark current of 20 pA, and a fast photo response of 2 μs. The spectral response is extended to the shortwave infrared range at 1550 nm. Furthermore, a logic computing system with light/no light as binary input is designed to convert the current signal to the voltage output. This research not only underscores the versatility of 2D materials in the realm of sophisticated photodetector design but also heralds new avenues for their application in energy-efficient, high-performance optoelectronic devices.
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Visible to near-infrared photodetector based on organic semiconductor single crystal

LI Xiang, HU Jin-Han, ZHONG Zhi-Peng, CHEN Yu-Zhong, WANG Zhi-Qiang, SONG Miao-Miao, WANG Yang, ZHANG Lei, LI Jian-Feng, HUANG Hai

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Abstract:

Organic semiconductor materials have shown unique advantages in the development of optoelectronic devices due to their ease of preparation, low cost, lightweight, and flexibility. In this work, we explored the application of the organic semiconductor Y6-1O single crystal in photodetection devices. Firstly, Y6-1O single crystal material was prepared on a silicon substrate using solution droplet casting method. The optical properties of Y6-1O material were characterized by polarized optical microscopy, fluorescence spectroscopy, etc., confirming its highly single crystalline performance and emission properties in the near-infrared region. Phototransistors based on Y6-1O materials with different thicknesses were then fabricated and tested. It was found that the devices exhibited good visible to near-infrared photoresponse, with the maximum photoresponse in the near-infrared region at 785 nm. The photocurrent on/off ratio reaches 10², and photoresponsivity reaches 16 mA/W. It was also found that the spectral response of the device could be regulated by gate voltage as well as the material thickness, providing important conditions for optimizing the performance of near-infrared photodetectors. This study not only demonstrates the excellent performance of organic phototransistors based on Y6-1O single crystal material in near-infrared detection but also provides new ideas and directions for the future development of infrared detectors.
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A HgTe/ZnO Quantum Dots Vertically Stacked Heterojunction Low dark current Photodetector

HUANG Xin-Ning, JIANG Teng-Teng, DI Yun-Xiang, XIE Mao-Bin, GUO Tian-Le, LIU Jing-Jing, WU Bin-Min, SHI Jing-Mei, Qin Qiang, DENG Gong-Rong, CHEN Yan, LIN Tie, SHEN Hong, MENG Xiang-jian, WANG Xu-Dong, CHU Jun-Hao, GE Jun, WANG Jian-lu

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Abstract:

Colloidal quantum dots (CQDs) are affected by the quantum confinement effect, which makes their bandgap tunable. This characteristic allows these materials to cover a broader infrared spectrum, providing a cost-effective alternative to traditional infrared detector technology. Recently, thanks to the solution processing properties of quantum dots and their ability to integrate with silicon-based readout circuits on a single chip, infrared detectors based on HgTe CQDs have shown great application prospects. However, facing the challenges of vertically stacked photovoltaic devices, such as barrier layer matching and film non-uniformity, most devices integrated with readout circuits still use a planar structure, which limits the efficiency of light absorption and the effective separation and collection of photo-generated carriers. Here, by synthesizing high-quality HgTe CQDs and precisely controlling the interface quality, we have successfully fabricated a photovoltaic detector based on HgTe and ZnO QDs. At a working temperature of 80 K, this detector achieved a low dark current of 5.23×10-9^A cm-², a high rectification ratio, and satisfactory detection sensitivity. This work paves a new way for the vertical integration of HgTe CQDs on silicon-based readout circuits, demonstrating their great potential in the field of high-performance infrared detection.
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Volume 43,2024 Issue 3

Infrared Materials and Devices

Terahertz and Millimeter Wave Technology

Remote Sensing Technology and Application

Infrared Photoelectric Technology and Application

Image Processing and Software Simulation

遥感技术与应用

红外材料与器件

遥感技术与应用

红外材料与器件

图像处理及软件仿真

红外材料与器件

红外及光电技术与应用

太赫兹与毫米波技术

图像处理及软件仿真

红外光谱与光谱分析

红外材料与器件

红外及光电技术与应用

红外材料与器件

太赫兹与毫米波技术

红外材料与器件

太赫兹与毫米波技术

红外材料与器件

红外光谱与光谱分析

红外材料与器件

太赫兹与毫米波技术

红外材料与器件

红外及光电技术与应用

遥感技术与应用

红外光谱与光谱分析

图像处理及软件仿真

红外材料与器件

太赫兹与毫米波技术

图像处理及软件仿真

红外材料与器件

红外及光电技术与应用

红外材料与器件

图像处理及软件仿真

红外材料与器件

太赫兹与毫米波技术

红外材料与器件

太赫兹与毫米波技术

红外及光电技术与应用

红外材料与器件

太赫兹与毫米波技术

Volume 43,2024 Issue 3

Infrared Spectroscopy and Spectral Analysis

Image Processing and Software Simulation

Remote Sensing Technology and Application

Infrared Materials and Devices

Terahertz and Millimeter Wave Technology

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