Relevant bibliographies by topics / Slots radiating element

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Academic literature on the topic 'Slots radiating element'

Author: Grafiati
Published: 4 June 2025
Last updated: 15 July 2025

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Journal articles on the topic "Slots radiating element"

1

Hasan, Bismah, and Kamran Raza. "Dual Band Slotted Printed Circular Patch Antenna With Superstrate and EBG Structure for 5G Applications." January 2019 38, no. 1 (2019): 227–38. http://dx.doi.org/10.22581/muet1982.1901.19.

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Slotted circular printed layered patch antenna is designed, simulated and fabricated for 5G (Fifth Generation) wireless communication applications. The antenna consists of slots in the main radiating circular patch element for miniaturizing the size of the radiating element and providing dual band radiation characteristics. The feed line is separated on bottom substrate layer with EBG (Electromagnetic Band-Gap) embedded for enhancing the gain characteristics of the antenna. Superstrate layer is also used for improving the gain of the antenna where the distance from the radiating antenna element is optimized for maximizing the impedance bandwidth and radiation characteristics. The feed realization and impedance matching of the radiating slotted circular patch antenna is done by inducing slot at the middle ground plane of the slot embedded circular patch antenna system. The proposed configuration provides power radiation gain values of more than 5 dB for the Ka band of communications, whereas the impedance bandwidth of the antenna is verified for the dual resonances at 27.5 and 28.5 GHz. Dual band radiation characteristics are attained by embedding and optimizing the slot length and width in the circular patch radiator element that is placed on the upper face of the substrate RT Rogers Duroid 5880 layer. The length of the microstrip feed line embedded in the lower layer of the substrate is optimized for providing required bandwidth characteristics for the dual frequency point radiations. The antenna configuration is designed, modeled and simulated in CST (Central Standard Time) Microwave studio. The antenna is fabricated and measured vs simulated frequency response, gain patterns and current density plots are presented for the verification of antenna operation in the desired frequency bands.
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Jetti, Chandrasekhar Rao, Tathababu Addepalli, Sreenivasa Rao Devireddy, et al. "Design and Analysis of Modified U-Shaped Four Element MIMO Antenna for Dual-Band 5G Millimeter Wave Applications." Micromachines 14, no. 8 (2023): 1545. http://dx.doi.org/10.3390/mi14081545.

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A novel compact-slotted four element multiple input multiple output (MIMO) planar monopole antenna is proposed for 5G mmWave N257/N258 and N262 band applications. The antenna, with dimensions of 12 mm × 11.6 mm × 0.508 mm (1.036λo ×1.001λo×0.043λo where λo is computed at lowest cutoff frequency), is fabricated on a Rogers RT/duroid 5880 (tm) substrate with a relative permittivity of 2.2 and a dielectric loss tangent of 0.0009. The suggested antenna consists of four U-shaped radiating elements (patches) on top of the dielectric material and a slotted ground on the bottom. The radiating elements are fed by a 50-ohm microstrip line feed. To improve the impedance performance of the MIMO antenna, a rectangular strip of 1.3 mm × 0.2 mm and a couple of rectangular slots are added to each radiating element. The first operating band at 27.1 GHz, ranging from 25.9 GHz to 27.8 GHz, is achieved by using slotted U-shaped radiating elements. The second operating band at 48.7 GHz, ranging from 47.1 GHz to 49.9 GHz, is obtained by etching hexagonal slots on the ground. The antenna design achieves an isolation of >27 dB through the orthogonal positioning of radiating elements and slots on the ground. The designed antenna operates at 27 GHz (N257/N258) and 48.7 GHz (N262) bands, exhibiting stable radiation patterns, a peak gain of >5.95 dBi, radiation efficiency of >90%, an envelope correlation coefficient of <10−6, a total active reflection coefficient of ≤−10 dB, channel capacity losses of <0.03 bits/s/Hz, and a mean effective gain of ≤−3 dB. The simulated and measured results of the antenna show good agreement, making it well-suited for 5G mmWave communication applications.
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Milijić, Marija, and Branka Jokanović. "Advanced high-gain slot antenna arrays for 5G and radar applications." Telfor Journal 13, no. 1 (2021): 29–34. http://dx.doi.org/10.5937/telfor2101029m.

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This paper presents an advanced design of high-gain slot antenna array at K-band using slots as radiating elements serially fed by coplanar waveguide (CPW). The arrays consist of identical slots of rectangular shape positioned symmetrically relative to the CPW feeding line. Firstly, the linear arrays of 14 slots are examined considering mainly their bandwidth and radiation characteristics. In addition, two identical linear sub - arrays of 14 slots are investigated when they have separate feeding in the form of two generators for each sub - array. Last, a CPW T-junction is employed to feed the antenna consisting of 2 x 14 slots which resulted in a wide operating bandwidth and maximum gain of 21.0 dBi which proved to be 2.25 dB less gain than with independent feeding. In order to enhance the antenna gain, both arrays are terminated with open-circuited stubs, so that the energy remaining after the last array element is reflected from the stub and re-radiated through the slot arrays. The length of the stubs is optimized to provide that the reflected wave is in phase with the forward-traveling waves at all the slot locations. In that way, very little energy is wasted and consequently the antenna gain is increased. The feed simplicity and uniplanar configuration of the slot arrays, designed for the frequency range 24.25-27.5 GHz, makes them attractive for radar sensors and high capacity 5G technology applications.
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Ravi Kumar Goyal. "Design of circular slots loaded MIMO antenna with DGS at 28 GHz for 5G wireless services." Journal of Electrical Systems 20, no. 2 (2024): 2363–72. http://dx.doi.org/10.52783/jes.2001.

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In this paper, a MIMO microstrip patch antenna with four radiating elements is designed and analyzed at 28 GHz. This paper addresses the problem of mutual coupling without adding a decoupling network. The decoupling method increases the complexity and volume of MIMO antennas. The CST Microwave simulator is used to simulate the MIMO antenna. The simulation and measurement results are compared to analyze the antenna's performance. The parameters of the MIMO patch antenna, including return loss, VSWR, gain, beam width, and radiation pattern, are evaluated at a center frequency of 28 GHz. The overall dimensions of the MIMO antenna are 60 × 42 × 1.6 mm3.An H-shaped slot is inserted in the middle of the ground plane to minimize mutual coupling among the radiating elements. The isolation amplitude between radiating elements is observed greater than 35 dB at 28 GHz frequency. A wide impedance bandwidth of 4 GHz (26.5 to 30.5) is achieved, by etching four small arcs into the patch’s corners. In this work, two circular slots are inserted on the radiating element to widen the bandwidth further by adjusting the surface current on each radiating patch. At the center frequency of 28 GHz, the Envelope Correlation Coefficient (ECC) is observed to be 0.0001, with a diversity gain of 10 dB. The antenna has a maximum radiation efficiency of 75% and a peak gain of 7.62 dB. This antenna can be used for 5G wireless services.
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Arya, Vivek, Tanuj Garg, and Hamza Mohammed Ridha Al-Khafaji. "SIW Leaky Wave Antenna for THz Applications." Electronics 12, no. 8 (2023): 1839. http://dx.doi.org/10.3390/electronics12081839.

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This paper proposes a new design of leaky wave antenna (LWA) based on substrate integrated waveguide (SIW) technology for THz applications. The suggested LWA structure has a combination of longitudinal and transverse slots and makes a 10-element linear array of radiating elements. To address the problem of open-stop-band (OSB), four additional smaller slots were etched on the corners of longitudinal and transversal slots. At the broadside, this LWA provided a gain of 12.33 dBi, and a continuous wide beam scanning range from +78° to −6° via the broadside while exhibiting efficient radiation performance over the operating frequency bands of 105 GHz to 109 GHz with a peak gain of 16.02 dBi.
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Davuluri, Akhila John, and P. Siddaiah. "Design of wide band slotted microstrip patch antenna with defective ground structure for ku band." International Journal of Electrical and Computer Engineering (IJECE) 11, no. 2 (2021): 1337. http://dx.doi.org/10.11591/ijece.v11i2.pp1337-1345.

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This paper proposes a microstrip patch antenna (MSPA) in the Ku band for satellite applications. The antenna is small in size with dimensions of about 40 mm×48 mm×1.59 mm and is fed with a coaxial cable of 50 Ω impedance. The proposed antenna has a wide bandwidth of 3.03 GHz ranging from 12.8 GHz to 15.8 GHz. To realize the characteristics of wideband the techniques of defective ground structure (DGS) and etching slots on the radiating element are adopted. The antenna is modeled on the FR4 substrate. A basic circular patch is selected for the design of a dual-frequency operation and in the next step DGS is introduced into the basic antenna and enhanced bandwidth is achieved at both the frequencies. To attain wider bandwidth two slots are etched on the radiating element of which one is a square ring slot and the second one is a circular ring slot. The novelty of the proposed antenna is a miniaturized design and unique response within the Ku band region which is applicable for wireless UWB applications with VSWR <2 and an average gain of 3.6 dB.
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Akhila, John Davuluri, and Siddaiah P. "Design of wide band slotted microstrip patch antenna with defective ground structure for ku band." International Journal of Electrical and Computer Engineering (IJECE) 11, no. 2 (2021): 1337–45. https://doi.org/10.11591/ijece.v11i2.pp1337-1345.

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This paper proposes a microstrip patch antenna (MSPA) in the Ku band for satellite applications. The antenna is small in size with dimensions of about 40 mm×48 mm×1.59 mm and is fed with a coaxial cable of 50 Ω impedance. The proposed antenna has a wide bandwidth of 3.03 GHz ranging from 12.8 GHz to 15.8 GHz. To realize the characteristics of wideband the techniques of defective ground structure (DGS) and etching slots on the radiating element are adopted. The antenna is modeled on the FR4 substrate. A basic circular patch is selected for the design of a dual-frequency operation and in the next step DGS is introduced into the basic antenna and enhanced bandwidth is achieved at both the frequencies. To attain wider bandwidth two slots are etched on the radiating element of which one is a square ring slot and the second one is a circular ring slot. The novelty of the proposed antenna is a miniaturized design and unique response within the Ku band region which is applicable for wireless UWB applications with VSWR <2 and an average gain of 3.6 dB.
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Rajagopal, Chithradevi, Nafiza Noorullakhan, Sreeja Balakrishnapillai Suseela, and Radha Sankararajan. "Compact modified circular patch quad-band MIMO antenna with high isolation and low correlation." International Journal of Microwave and Wireless Technologies 9, no. 3 (2016): 581–90. http://dx.doi.org/10.1017/s1759078715001737.

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A compact quad band slot antenna with high isolation suitable for multiple-input–multiple-output (MIMO) applications is developed. The quad bands are achieved by introducing slots in a modified, size reduced circular patch antenna. The single-antenna element consists of a substrate sandwiched between a modified circular patch with F shape slot, a feeder line and a via running between the radiating patch and the feeder line. The proposed design resonates at the frequencies of 1.8 GHz (1.7–1.88 GHz), 3.6 GHz (3.50–3.76 GHz), 5.4 GHz (5.25–5.38 GHz), and 7.2 GHz (7.15–7.35 GHz) covering the GSM II, WIMAX, wireless local area network (WLAN), and C-band applications, respectively. The independent tuning of frequency bands is achieved by varying the length of the slots. Orthogonally placed two- and four-element MIMO antenna system are fabricated, tested, and the measurement results are presented. The separation between each element is reduced to 0.085λ while introducing slotted and pulsed stubs to improve isolation between elements. A detailed analysis, including mutual coupling, low correlation, diversity gain, and total array reflection coefficient had been reported. The two- and four-element MIMO antennas achieved correlation as low as 0.005, mutual coupling ≤−15 dB, and diversity gain nearly 10 dB.
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Giri, K. K., R. K. Singh, and K. Mamta. "Effect of Symmetric Shaped Slot on Patch Antenna Design and Performance for 10 GHz 5G Applications." Journal of Scientific Research 14, no. 2 (2022): 405–17. http://dx.doi.org/10.3329/jsr.v14i2.55209.

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A microstrip patch antenna is considered the most suitable radiating and receiving element for millimeter-wave application due to its low cost, simple construction, low weight, and ease with which it is integrated into the circuits. In this paper, we have reported the effects of different symmetric shaped slots on millimeter-wave patch antenna design and its performance at 10 GHz frequency in the X band (8-12 GHZ). The rectangular, circular, and elliptical slots area is kept constant at 11.2 mm2. The radius of circular and spherical slots is the same. High-frequency simulation software (HFSS) simulation results in parameters like S11 (reflection coefficient), Y-parameter (driving point admittance), Radiation Pattern, 3D Polar plot and illustrate that the results are in good agreement with the desired value. A rectangular slot is found to achieve the target resonance frequency with a low voltage standing wave ratio (VSWR) towards a ‘good match.’ Circular, spherical, and elliptical-shaped slots have high VSWR values, indicating a larger degree of mismatch. Surprisingly, results are obtained for the spherical-shaped slot, implying that the antenna will work at the target resonance frequency and has a Dual-Resonance. The proposed antenna design is suitable for 5G device applications in the X band.
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Reddy, Ambavaram Pratap, and Pachiyaannan Muthusamy. "Bandwidth and Gain Enhancement of Parasitic Loaded Proximity Coupled Antenna for WLAN Applications." Transactions on Electromagnetic Spectrum 1, no. 2 (2022): 31–37. https://doi.org/10.5281/zenodo.7003620.

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Abstract: In this work, two different substrates were used for enhancing the bandwidth and gain of the designed antenna for the application of WLAN. The proposed design attained at 5.2 GHz frequency. The proposed structure consists of the five layers arranged in vertical direction. The lower layer is ground layer, fifth layer is the active patch, substrate one is FR-4, and substrate two is RT Duroid 5880 with equal height of 1.6 mm. The performance of the proposed antenna is improved by placing triangular slots on the patch. A non-contacting type proximity feed line method was proposed for excellent impedance matching. From the observation stage by stage, the radiating element enhances the bandwidth and gain. The proposed design simulated through CSTMW 2018. The measured S-parameters and radiation patterns results are observed from vector network analyzer and anechoic chamber. Finally, the proposed radiating element is well suited for WLAN applications.
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Book chapters on the topic "Slots radiating element"

1

Jetti, Chandrasekhar Rao, Srinivasa Rao U, Kamala Devi Kolavennu, Karthikesh Yangala, and Sai Teja Sanaka. "A NOVEL SLOTTED MIMO ANTENNA FOR 5 G MM-WAVES COMMUNICATION." In Futuristic Trends in Network & Communication Technologies Volume 3 Book 3. Iterative International Publishers, Selfypage Developers Pvt Ltd, 2024. http://dx.doi.org/10.58532/v3binc3p4ch2.

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A novel tiny two-element MIMO (multiple-input multiple-output) antenna is presented for 5G mm-wave communication. The antenna has dimensions of 4.8 × 12 × 0.508 mm3 and is composed of the Rogers RT/duroid 5880 (tm) substrate, which has a loss tangent of 0.0009 and a dielectric of 2.2. The proposed antenna features a slotted ground at the base and two U-shape patches on top of the substrate. To excite the patches, a 50-ohm microstrip line feed is used. For better impedance performance, each radiating patch has a 1.3 × 0.2 mm2 rectangular strip and a couple of rectangular slots. A U-shaped element enables the first operating band at 26.8GHz from 26.3 to 27.50GHz. Cutting hexagonal slots into the ground creates the next operating band at 48.7GHz, which spans 48.1 to 49.45GHz. The suggested MIMO antenna's isolation is improved by slots on the ground and radiating elements that are orthogonally positioned. The results manifests that the suggested antenna is appropriate candidate for 5G mm-wave communications.
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Alibakhshikenari, Mohammad, Peiman Parand, Bal Virdee, et al. "Advanced Wideband Antenna Arrays for 5G Millimeter-Wave Spectrum at K- and Ka-Bands." In Wideband Wave-Propagating Components for Wireless RF Communications [Working Title]. IntechOpen, 2025. https://doi.org/10.5772/intechopen.1009346.

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Millimeter-wave (mm-Wave) wireless communication systems play a central role in meeting the demands of next-generation wireless technologies such as 5G. This chapter presents the design and analysis of three advanced antenna arrays optimized for mm-Wave 5G wireless networks operating over K-band (18–27 GHz) and Ka-band (27–40 GHz). These structures feature radiation patches suspended above a common substrate, excited using three methods to achieve optimal performance. The first method utilizes a 50 Ω open-ended microstrip-line balun to slot-line transition for effective energy coupling and excitation. The second method employs a 50Ω-microstrip feed network, ensuring consistent power distribution across array elements. Lastly, metallic-rods passing through the substrate provide direct excitation, facilitating robust mechanical and electrical integration. To address challenges, innovative techniques were implemented. Vertical metallic-vias suppress unwanted surface currents, while the spacing between radiating elements was optimized as multiples of half-wavelength to minimize interference and maximize array performance. Additionally, antenna elements were enclosed with metallic-walls to further enhance isolation and ensure predictable performance. Further strategies such as bowtie-like dipoles were incorporated to provide wider radiation apertures and better impedance matching. Power dividers were used to split input signals into multiple equal-phase outputs, boosting overall gain. Furthermore, the patches were embedded with slots to exhibit metasurface characteristics, enhancing bandwidth and radiation performance while maintaining compactness. The design methodologies and optimizations result in antenna arrays with superior performance metrics. The detailed analysis, innovative techniques, and demonstrated performance of the proposed antenna arrays establish them as strong candidates for practical deployment in advanced 5G mm-Wave networks and beyond.
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Ghosal, Antara, Anurima Majumdar, Avali Ghosh, Sisir Kumar Das, and Annapurna Das. "AN ARRAY OF SPIRAL PATCH ANTENNA FOR WLAN, WIMAX AND WI-FI APPLICATION." In Futuristic Trends in Network & Communication Technologies Volume 3 Book 4. Iterative International Publishers, Selfypage Developers Pvt Ltd, 2024. http://dx.doi.org/10.58532/v3bfnc4p3ch1.

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In this chapter a microstrip patch antenna with array of spiral slots is analyzed. The slotted patch antenna can be used for WLAN, WiMAX, Wi-Fi, S-band application. The antenna is fed by a coaxial probe. The work comprises of two structures. First two square spiral patch antenna is introduced with tuning arms. Secondly, these slotted spiral patches are used as an array element for the final structure. There are four array elements on the final structure. The antenna is modeled and simulated using Ansoft HFSS Simulator software. The parametric study like the reflection coefficient, radiation pattern, gain and current distribution of the proposed structure is obtained. The simulated and experimental results are in good agreement with each other. Experimental results are obtained using Network Analyzer.
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Thommandru, Raju, Dr M. Purna Kishore, Desimala Prabhakara Rao, Arumalla Raja, and Shaik Mahaboob Subhani. "A NOVEL TWO ELEMENTS MIMO ANTENNA FOR 5G COMMUNICATION." In Futuristic Trends in IOT Volume 3 Book 8. Iterative International Publishers, Selfypage Developers Pvt Ltd, 2024. http://dx.doi.org/10.58532/v3baio8p5ch3.

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High speed data transfer, higher receive reception, and an improved bit error rate are requirements in the present age of communication technology. The next-generation technology known as 5G is quickly gaining attention because it increases capacity while also offering excellent service quality, very low latency, and fast data speeds. Antenna design and development are essential for the proper operation of any 5G devices. With increased bandwidth, gain, and reduced radiation losses, the antenna should be able to cover the proposed 5G bands. It also needs to be inexpensive and small in size. The desire for high-quality, continuous broad band communications is common, high data rates and bandwidth, in particular in countries that are developing like India. Wireless systems data rates, capacities, and connection dependability may all be significantly increased using MIMO (multiple input and multiple output) technology due to its ability to transmit and receive data over many paths. Currently used in 4G user equipment, the MIMO system is a promising technology for application in 5G mobile terminals. As a result, a novel two-element MIMO antenna for 5G communication is described in this work. To effectively isolate the antenna radiators from one another, two radiators are used in this design, each having slits. Compared to earlier 5G antennas, the MIMO antenna will keep a typical small size
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Conference papers on the topic "Slots radiating element"

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Berdnyk, Serhii, Victor Katrich, Yevhenii Antonenko, et al. "Combined Dipole-Slot Radiating Structures with Parasitic Impedance Dipoles as Functional Elements of Antennas and Antenna Arrays." In 2024 IEEE 29th International Seminar/Workshop on Direct and Inverse Problems of Electromagnetic and Acoustic Wave Theory (DIPED). IEEE, 2024. http://dx.doi.org/10.1109/diped63529.2024.10706196.

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Daliri, Ali, Chun H. Wang, Sabu John, et al. "FEA Evaluation of the Mechanical and Electromagnetic Performance of Slot Log-Spiral Antennas in Conformal Load-Bearing Antenna Structure (CLAS)." In ASME 2011 Conference on Smart Materials, Adaptive Structures and Intelligent Systems. ASMEDC, 2011. http://dx.doi.org/10.1115/smasis2011-5137.

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Conformal load-bearing antenna structures (CLAS) have been attracting the attention of aerospace industries in recent years. This type of multifunctional structures combines the features of conventional antennas with load-bearing capacity and has important applications in military and commercial airplanes especially for Unmanned Aerial Vehicles (UAVs). Equiangular slot spiral antennas are an alternative to traditional rectangular slots because of its wideband radiation characteristics. However, the mechanical characteristics of such a spiral antenna integrated into a structure are so far largely unexplored. In this paper, the electromagnetic (scattering parameter, radiation pattern and gain) and mechanical properties (stress concentration factor (SCF)) of spiral antennas is investigated using finite element analysis (FEA). The results lead to a recommendation for using this type of antenna for future CLAS concepts.
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Amendola, G., Emilio Arnieri, Luigi Boccia, and Volker Ziegler. "Annular ring slot radiating element for integrated millimeter wave arrays." In 2012 6th European Conference on Antennas and Propagation (EuCAP). IEEE, 2012. http://dx.doi.org/10.1109/eucap.2012.6206468.

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Ferrando-Rocher, Miguel, Jose I. Herranz-Herruzo, and Alejandro Valero-Nogueira. "Wideband Coffee-Bean Shaped Radiating Element for Circularly-Polarized Waveguide Slot Arrays." In 2021 15th European Conference on Antennas and Propagation (EuCAP). IEEE, 2021. http://dx.doi.org/10.23919/eucap51087.2021.9411069.

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Ying Shen, R. Fralich, Chen Wu, and J. Litva. "Active radiating element using FET source integrated with a multilayer slot coupled patch antenna." In IEEE Antennas and Propagation Society International Symposium 1992 Digest. IEEE, 1992. http://dx.doi.org/10.1109/aps.1992.221590.

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Mohammed, Maalim Qasim, and Assim Modhafar Fadhil. "New compact design of dual notched bands UWB antenna with slots in radiating and feeding elements." In 2013 IEEE Student Conference on Research and Development (SCOReD). IEEE, 2013. http://dx.doi.org/10.1109/scored.2013.7002612.

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Shepeleva, Elena, Artem Vilenskiy, Gennadiy Evtyushkin, and Anton Lukyanov. "Sub-THz U-Slot Coupled Stacked-Patch Radiating Elements for Dual-Polarized MIMO Array Antennas." In 2024 18th European Conference on Antennas and Propagation (EuCAP). IEEE, 2024. http://dx.doi.org/10.23919/eucap60739.2024.10501182.

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Mishra, Mohit, Rahul Sharma, and Raghvendra Kumar Chaudhary. "A Multilayer Slot Coupled Multi-element Monopole Radiator with End-fire Radiation Pattern for mmWave Applications." In 2023 IEEE Microwaves, Antennas, and Propagation Conference (MAPCON). IEEE, 2023. http://dx.doi.org/10.1109/mapcon58678.2023.10463772.

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