Enhanced Accuracy of Breast Cancer Detection Based on UWB Compact Slotted Monopole Antennas

Amdaouch, Ibtisam; Aghzout, Otman; Naghar, Azzeddin; Alejos, Ana Vázquez; Falcone, Francisco

doi:10.7716/aem.v8i5.673

Cited by 9 publications

(5 citation statements)

References 11 publications

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“…11,12 Diverse geometries of slots have been incorporated in the radiating elements, which considerably improves the impedance bandwidth of these antennas. 13 For particular applications, such as antenna radomes, microwave imaging detection systems, radar cross section (RCS) control, and ground-penetrating radar (GPR), to improve the precision and detection distance, it is imperative to utilize ultra-wideband (UWB) antennas that possess high gain and directivity, 14,15 and these characteristics can be improved using various approaches, including artificial magnetic conductors (AMCs), 16 reactive impedance surfaces (RISs), 17 the employment of antenna arrays, 18 and frequency selective surfaces (FSSs). 19 Remarkably, FSS keeps pace with the evolving requirements for more expanded bandwidth for wireless communication objectives and some other advanced functionalities that lean on a specific bandwidth to execute.…”

Section: Introductionmentioning

confidence: 99%

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A curved single‐layer FSS design for gain improvement of a compact size CPW‐fed UWB monopole antenna

Daira,

Lashab,

Berkani

et al. 2023

Micro & Optical Tech Letters

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A Novel design of a curved single‐layered frequency selective surface with an 11 × 11 array of a 13 × 13 mm‐sized unit cell has been merged with a miniaturized, CPW‐fed ultra‐wideband monopole of dimensions (20 × 25 mm2) for gain enhancement. The suggested prototype, crafted on an FR‐4 dielectric substrate and demonstrates a very broad bandwidth starting from 2.66 to 17.98 GHz (148%), which covers the entire UWB frequency band. The combined antenna‐curved FSS reflector shows a very important gain improvement from 0.2–5.4 dB to 8.8–14.9 dB, having a peak gain increase of 10 dB at 10.6 GHz. Basic design features were studied and discussed through simulations, yielding promising results The proposed structure can be used in UWB and GPR applications.

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Section: Introductionmentioning

confidence: 99%

“…To provide a wide impedance bandwidth, several radiating element shapes, including rectangular, circular, triangular, hexagonal, etc., have been evolved by mean research works 11,12 . Diverse geometries of slots have been incorporated in the radiating elements, which considerably improves the impedance bandwidth of these antennas 13 …”

Section: Introductionmentioning

confidence: 99%

A curved single‐layer FSS design for gain improvement of a compact size CPW‐fed UWB monopole antenna

Daira,

Lashab,

Berkani

et al. 2023

Micro & Optical Tech Letters

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“…X-ray mammography is currently the gold-standard method for breast cancer detection. However, it has the disadvantages of harmful radiation, uncomfortable compression of the breast during examination, and relatively high false-negative rates [ 1 , 2 ]. Recently, confocal microwave imaging has attracted the interest of a number of research groups as an effective alternative.…”

Section: Introductionmentioning

confidence: 99%

A Novel Approach of a Low-Cost UWB Microwave Imaging System with High Resolution Based on SAR and a New Fast Reconstruction Algorithm for Early-Stage Breast Cancer Detection

et al. 2022

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In this article, a new efficient and robust approach—the high-resolution microwave imaging system—for early breast cancer diagnosis is presented. The core concept of the proposed approach is to employ a combination of a newly proposed delay-and-sum (DAS) algorithm and the specific absorption rate (SAR) parameter to provide high image quality of breast tumors, along with fast image processing. The new algorithm enhances the tumor response by altering the parameter referring to the distance between the antenna and the tumor in the conventional DAS matrices. This adjustment entails a much clearer reconstructed image with short processing time. To achieve these aims, a high directional Vivaldi antenna is applied around a simulated hemispherical breast model with an embedded tumor. The detection of the tumor is carried out by calculating the maximum value of SAR inside the breast model. Consequently, the antenna position is relocated near the tumor region and is moved to nine positions in a trajectory path, leading to a shorter propagation distance in the image-creation process . At each position, the breast model is illuminated with short pulses of low power waves, and the back-scattered signals are recorded to produce a two-dimensional image of the scanned breast. Several simulations of testing scenarios for reconstruction imaging are investigated. These simulations involve different tumor sizes and materials. The influence of the number of antennas on the reconstructed images is also examined. Compared with the results from the conventional DAS, the proposed technique significantly improves the quality of the reconstructed images, and it detects and localizes the cancer inside the breast with high quality in a fast computing time, employing fewer antennas.

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“…In 2020, there are over 2.3 million new cases reported according to World Health Organization (WHO). However, early diagnosis reduces death and increases survival chances (2). A variety of screening methods are commonly used to detect breast cancer, including X-ray mammography, computed tomography (CT) scans, Ultra-Sonic imaging (US), and magnetic resonance imaging (MRI).…”

Section: Introductionmentioning

confidence: 99%

Multislot Rectangular Microstrip Patch Antenna Design to Detect Breast Cancer

Kabir

Ahmed

2022

ECS Trans.

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The most typical cancer among women is breast cancer. It has the highest rate of occurrence and death. Breast cancer has become the leading cause of death among women worldwide in recent years. To avoid significant effects, early detection of malignant tissue is the most crucial aspect. X-ray mammography, magnetic resonance imaging, and ultrasound scanning can all be used to detect cancer cells in the breast. Microwave imaging overcomes some of the disadvantages of these approaches. In this paper, we proposed a new design for a multislot rectangular microstrip patch antenna that can detect breast cancers in the required FCC range (3.1 GHz - 10.6 GHz). The antenna is made of FR4 epoxy, which has a dielectric permittivity of 4.4 and a loss tangent of 0.02. It is designed and simulated with high-frequency simulation software (HFSS). The results show that the proposed antenna is a good candidate for the detection of breast cancer.

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Enhanced Accuracy of Breast Cancer Detection Based on UWB Compact Slotted Monopole Antennas

Cited by 9 publications

References 11 publications

A curved single‐layer FSS design for gain improvement of a compact size CPW‐fed UWB monopole antenna

A curved single‐layer FSS design for gain improvement of a compact size CPW‐fed UWB monopole antenna

A Novel Approach of a Low-Cost UWB Microwave Imaging System with High Resolution Based on SAR and a New Fast Reconstruction Algorithm for Early-Stage Breast Cancer Detection

Multislot Rectangular Microstrip Patch Antenna Design to Detect Breast Cancer

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