Bibliographies thématiques / MICRO STRIP PATCH ANTENNA

Littérature scientifique sur le sujet « MICRO STRIP PATCH ANTENNA »

Auteur : Grafiati
Publié le 11 septembre 2023

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Articles de revues sur le sujet "MICRO STRIP PATCH ANTENNA"

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RameshBabu, Dr K. « CPWG Fed with Octagonal Patch Antenna ». International Journal for Research in Applied Science and Engineering Technology 9, no VI (20 juin 2021) : 2086–94. http://dx.doi.org/10.22214/ijraset.2021.35313.

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A Co planner Wave Guide (CPWG) fed with octagonal patch antenna is modified from their respective rectangular patch are presented for WLAN application. The dielectric material applied in the design process for both co planar and micro strip patch antenna is FR4 Epoxy Glass, which has relative permittivity of 4.4 and substrate height 1.6mm. Antenna parameters used to check the performance. A comparison is made between the octagonal co-planar antenna and octagonal micro strip antenna available. Ansys HFSS is used for antenna design and analysis. Both designed antennas are suitable for wireless local area network application and the design parameters of the antenna are optimized to resonate at 3GHz frequencies for WLAN applications. It has been found that octagonal micro strip patch antennas have lower return loss and are more directive than co planar patch antenna. High directivity of octagonal micro strip antenna is due to the presence of ground plane under the substrate of antenna. The results obtained by simulations have also shown that octagonal co planar patch antennas have high radiation efficiency (a measure of the power radiated through the antenna as an electromagnetic wave to the power fed to the antenna terminals) and which implies a wider bandwidth as compared to an octagonal micro strip patch antennas. The radiation efficiency obtained for micro strip patch antenna is 24% and that for co planar patch antenna is 67%, the directivity for micro strip patch antenna is 3.75 dB and that for a co-planar patch antenna is 3.25 dB.
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Srinivasa Rao, V., K. V. V. S. Reddy et A. M. Prasad. « Bandwidth Enhancement of Metamaterial Loaded Microstrip Antenna using Double Layered Substrate ». Indonesian Journal of Electrical Engineering and Computer Science 5, no 3 (1 mars 2017) : 661. http://dx.doi.org/10.11591/ijeecs.v5.i3.pp661-665.

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<p class="Abstract">Communication has become a key aspect of our daily life, becoming increasingly portable and mobile. This would need the use of micro strip antennas. The rapid growth has led to the need of antennas with smaller size, increased bandwidth and high gain. In this paper, a new version of micro strip patch antenna is designed by adopting double layered substrate concept and adding a layer of metamaterial structure to a square micro strip antenna. The antenna properties gain, return loss and bandwidth are studied to achieve better performance. The designed patch antenna has an improved bandwidth of 60% at a resonant frequency of 2.47 GHz. This antenna is designed and simulated by using HFSS software.</p>
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P, Subramanian, et Sujatha Therese P. « A 28-GHz U-slot Micro Strip Patch Antenna ». Journal of Advanced Research in Dynamical and Control Systems 11, no 0009-SPECIAL ISSUE (25 septembre 2019) : 509–16. http://dx.doi.org/10.5373/jardcs/v11/20192599.

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Baskar, Karthik, Pavithra Krishnamoorthy, Nehrujee Vishalinee, Padmavarshini Sivakumar, Anita . et Varshini Karthik. « Investigation on interaction of radiofrequency waves (microwaves) with saphenous veins ». International Journal of Engineering & ; Technology 7, no 2.8 (19 mars 2018) : 63. http://dx.doi.org/10.14419/ijet.v7i2.8.10328.

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Varicose veins contract when heated through microwave ablation. Heat application through microwave ablation, the collagen tends to regain its elasticity. In this paper, we propose simulation of the varicose vein with a wearable micro strip patch antenna. ANSYS HFSS 17.2 is an electromagnetic finite element method solver. The phantom model of human skin with normal vein and varicose vein with a wearable micro strip patch antenna was designed using this software. The wearable micro strip patch antenna is designed so that this approach is minimally invasive. The wearable micro strip patch antenna is modelled with a resonant frequency of 9.8 GHz. The temperature of about 45°C is proposed as the treatment for varicose vein.
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ZITOUNI, Mohamed, Tahar BENMESSOUD, Samir AIDOUD et Abdelaziz Hachem BENHADJ. « Modeling and Simulation of a Micro-Strip Patch Antenna in Pentagonal Fractal Geometry ». All Sciences Abstracts 1, no 2 (25 juillet 2023) : 29. http://dx.doi.org/10.59287/as-abstracts.1219.

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The antenna is an important element in the field of communication for transmitting and receivinginformation in the form of electromagnetic waves, it is also used in several fields such as detection systems, satellites and surveillance aircraft, communications networks and GPS automobiles and satellite communications through the system. The design of the antennas using the A-HFSS software "Ansoft- High Frequency Structure Simulator" is essentially based on the variation of the shape of the antenna and its conductive material, the nature and the thickness of the substrate in order to have a structure that resonates in the desired frequencies for applications precise.The goal of this work is to study and design a micro strip patch antenna in fractal geometry, regarding thecharacteristics such as the reflection coefficients, the gain and the radiation implemented in the environment HFSS software. The patch antenna is characterized by its small size, low cost, easy manufacturing and network connectivity. Despite its space-saving appearance, it retains the electromagnetic properties that ensure the device connectivity. We have compared the patch antenna in pentagonal and fractal pentagonal geometry in 1D to 3D pentagonal antenna array on the resonance frequency fed by a micro-strip line in order to have the best characteristics of these antennas; the bandwidth and the directivity of this antenna, using the electromagnetic simulation tool in the frequency domain CST MICROWAVE STUDIO.The information’s will reach: -The resonance frequency is higher for a normal patch antenna compared to that of a fractal patch antenna.- There is a presence of interferences due to the correctly destination.- The gain radiation pattern is a dipole (isotropic antenna) in the fractal antenna.– The bandwidth is wider for a fractal patch antenna compared to that of a normal patch antenna.
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Singhal, P. K., et Arun Kant Kadam. « Analysis and Design of Rectangular Resonant Microstrip Patch Antenna Loaded with SLOTTED RHOMBUS Shaped Left-Handed Inspired Metamaterial Structure ». International Journal of Electrical and Electronics Research 3, no 2 (30 juin 2015) : 27–30. http://dx.doi.org/10.37391/ijeer.030205.

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Authors analyzed and explored a significant concept of micro-strip patch antenna configured by double negative left handed metamaterial structure. Basic aim of this paper is to explain the general properties of rectangular micro-strip patch antenna with metamaterial structure like return loss, bandwidth, directivity and Smith chart. In this paper authors have compared the return loss of the micro-strip patch antenna at a frequency of 2.26 GHz and height of 3.2 mm from the ground plane with “SLOTTED RHOMBUS” Shaped left-handed structure. It has been observed that the return loss has reduced by 25 dB approximately.
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H. V., Pallavi, A. P. Jagadeesh Chandra et Paramesha Paramesha. « Design and Performance Analysis of MIMO Patch Antenna Using Superstrate for Minimization of Mutual Coupling ». WSEAS TRANSACTIONS ON COMMUNICATIONS 21 (28 juin 2022) : 204–14. http://dx.doi.org/10.37394/23204.2022.21.25.

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For 5G communications, An different types Antennas are plays major role to minimize mutual couplings and here MIMO is important technology which uses patch antenna’s. Where the existing design focuses only on frequency reconfiguration, but it does not take advantage of the entire frequency and power spectrum. Therefore, the honeycomb-shaped Metamaterial cells used in the suggested antenna design serve as a superstrate for micro-strip patch antennas with a extensive range of actual negative permittivity and permeability, as well as a refractive index feature. Also, to reduce mutual coupling in current printed and other antennas. A metamaterial superstrate-based micro-strip antenna with RF MEMS Varactor diode switching is proposed in this paper. Based on a micro-strip antenna, metamaterials in the shape of circular and hexagonal arrays are employed as the superstrate. Also, the superstrate layers serve as a random, providing strength to the entire structure while also improving other antenna metrics such as gain and bandwidth. The design outputs for several metamaterial superstrates in terms of reflection coefficient (S11), gain, and bandwidth are compared by adding varactor diode switches to the metamaterial superstrate, which also allows for frequency reconfiguration. As a result, the suggested antenna was designed to reduce mutual coupling and improve system performance in 5G technology, specifically in mm-wave applications. The obtained results for metamaterial superstrate designs demonstrate high bandwidth and gain behavior.
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H. V., Pallavi, A. P. Jagadeesh Chandra et Paramesha Paramesha. « Design and Performance Analysis of MIMO Patch Antenna Using Superstrate for Minimization of Mutual Coupling ». WSEAS TRANSACTIONS ON CIRCUITS AND SYSTEMS 21 (4 juillet 2022) : 142–53. http://dx.doi.org/10.37394/23201.2022.21.15.

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For 5G communications, An different types Antennas are plays major role to minimize mutual couplings and here MIMO is important technology which uses patch antenna’s. Where the existing design focuses only on frequency reconfiguration, but it does not take advantage of the entire frequency and power spectrum. Therefore, the honeycomb-shaped Metamaterial cells used in the suggested antenna design serve as a superstrate for micro-strip patch antennas with a extensive range of actual negative permittivity and permeability, as well as a refractive index feature. Also, to reduce mutual coupling in current printed and other antennas. A metamaterial superstrate-based micro-strip antenna with RF MEMS Varactor diode switching is proposed in this paper. Based on a micro-strip antenna, metamaterials in the shape of circular and hexagonal arrays are employed as the superstrate. Also, the superstrate layers serve as a random, providing strength to the entire structure while also improving other antenna metrics such as gain and bandwidth. The design outputs for several metamaterial superstrates in terms of reflection coefficient (S11), gain, and bandwidth are compared by adding varactor diode switches to the metamaterial superstrate, which also allows for frequency reconfiguration. As a result, the suggested antenna was designed to reduce mutual coupling and improve system performance in 5G technology, specifically in mm-wave applications. The obtained results for metamaterial superstrate designs demonstrate high bandwidth and gain behavior.
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ARDIANTO, FAJAR WAHYU, SETYAWAN RENALDY, FARHAN FATHIR LANANG et TRASMA YUNITA. « Desain Antena Mikrostrip Rectangular Patch Array 1x2 dengan U-Slot Frekuensi 28 GHz ». ELKOMIKA : Jurnal Teknik Energi Elektrik, Teknik Telekomunikasi, & ; Teknik Elektronika 7, no 1 (24 janvier 2019) : 43. http://dx.doi.org/10.26760/elkomika.v7i1.43.

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ABSTRAKKebutuhan pengguna yang semakin meningkat harus diimbangi dengan peningkatan kecepatan data dan kapasitas suatu jaringan, sehingga diperlukan bandwidth yang lebar. 5G merupakan salah satu teknologi yang akan diresmikan tahun 2020 yang menjadi solusi terhadap peningkatan kecepatan data dan kapasitas layanan. Salah satu kandidat yang menjadi frekuensi kerja 5G yaitu 28 GHz. Antena mikrostrip merupakan salah satu jenis antena yang dapat digunakan untuk teknologi 5G. Namun, antena mikrostrip memiliki beberapa kekurangan, diantaranya bandwidth dan gain yang kecil. Untuk itu, dibutuhkan teknik yang dapat meningkatkan bandwidth dan gain antena. Pada penelitian ini dirancang antena mikrostrip bentuk rectangular patch yang ditambahkan slot berbentuk U dengan tujuan meningkatkan bandwidth dan disusun secara array 1×2 untuk meningkatkan gain antena. Hasil dari simulasi didapatkan antena mampu bekerja pada rentang frekuensi 27,5 GHz – 29,12 GHz pada batas return loss kurang dari -15 dB dengan bandwidth sebesar 1,62 GHz. Nilai gain yang dihasilkan sebesar 7,52 dB. Pola radiasi yang dihasilkan, yaitu unidireksional dan berpolarisasi secara linear.Kata kunci: 5G, 28 GHz, mikrostrip, rectangular patch, array, U-Slot ABSTRACTData rate and network capacity improvements offset the increase of user needs, hence it requires a wider bandwidth. The most current high-end technology, which can solve the problem is 5G. One of the frequency that becomes the candidate of 5G is 28 GHz. For 5G, it could apply one of the antenna types, micro strip antenna. However, micro strip antenna has a shortage of narrow bandwidth and small gain. Therefore, it requires a technique to increase the bandwidth and gain of the antenna. In this study, the form of micro strip of antenna design is a rectangular patch with the addition of U-Slot and arranged 1x2 to increase the bandwidth and antenna gain. The results of the simulation show that the antenna is working well at the range frequency of 27.5 GHz - 29.12 GHz, with a return loss limit of -15 dB with bandwidth of 1.62 GHz, the resulting gain value is 7.52 dB, the resulting radiation pattern is unidirectional and linearly polarized.Keywords: 5G, 28 GHz, microstrip, rectangular patch, array, U-Slot
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Leo Pauline, S., et T. R Ganesh Babu. « Design and Analysis of Compact Dual Band U-Slot Microstrip Patch Antenna with Defected Ground Structure for Wireless Application ». International Journal of Engineering & ; Technology 7, no 3.1 (4 août 2018) : 17. http://dx.doi.org/10.14419/ijet.v7i3.1.16787.

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This paper explore about the micro strip patch antenna design with a defected ground structure (DGS) for dual band operation. The intend of this paper is to design an micro strip antenna, under the frequency at 2.4 GHz and 5.2 GHz that can be utilized for BLUETOOTH and WLAN applications. The feeding technique used here is coaxial feed technique. The above said double band property can be established by etching U-slot in the ground plane. Being periodic structure slot is selected and it is imposed on ground plane. The periodic structures naturally modify the method of propagation of the electromagnetic signal passing on to the antenna. Essentially its core is to vary the parasitic capacitance and inductance of the material through which the substrate is made. This may moreover leads to the reduction in size and progress the performance of the antenna. Micro strip patch antennae are favored due to the fact that these are small in size, inexpensive, consume low power and easy to fabricate and also be designed to meet wide band application requirements.
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Thèses sur le sujet "MICRO STRIP PATCH ANTENNA"

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Chu, Chia-ching, et 朱家慶. « Study of micro-strip circuitry customized patch antenna ». Thesis, 2007. http://ndltd.ncl.edu.tw/handle/09680381088714110916.

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碩士
正修科技大學
電機工程研究所
95
This thesis proposed a new mechanism for the design and analysis of microstrip antenna.By using microstrip circuit to coordinate the loading device (radiator) attaining the proposed operation frequency, antenna gain and minimum cross polarization (XPL) on maximum front to back ratio, we carried on the design of microstrip circuit in matching different loading radiators for a microstrip antenna. Then, we found that design of microstrip components via path between the microstrip circuit (for instance:passive low pass filter or band pass filter) and the loading device (radiator) is responsible for the microstrip circuit itself without coupling to the loading device and maintains the original circuit characteristics being kept in proposed operation frequency, antenna gain and minimum XPL on maximum front to back ratio for a microstrip patch antenna. Usually, it is difficult to establish the equivalent circuit model for the analysis of a microstrip patch antenna. Our finding helps creating an equivalent circuit accurately with microstrip circuit to learn the correlation of the components for the input, characteristic and the impedance in the minimum XPL as well as maximum front to back ratio, antenna gain, impedance bandwidth upon the optimization design of the chip antenna.
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YADAV, RAKESH KUMAR. « DESIGN AND ANALYSIS OF DUAL-BAND SWASTIKA SHAPED MICRO-STRIP PATCH ANTENNA ». Thesis, 2017. http://dspace.dtu.ac.in:8080/jspui/handle/repository/16529.

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In this paper, a novel single-layer circular swastika shaped antenna with dual-band characteristics is presented. The proposed patch antenna, with design operating frequencies of5.5 GHz and 10.3 GHz, is targeted for applications in C-band and X-band. More importantly, the circular swastika-shaped micro strip patch antenna exhibits a theta polarized radiation pattern with gains of 11.17 dB and 9.05 dB with corresponding reflection Coefficients of (VSWR = 1.419) and (VSWR =1.046) at 5.5 GHz and 10.3 GHz, respectively. The Measurements of the fabricated patch antenna corroborate the simulation results obtained in HFSS. This dual-resonance antenna, with comparatively high gain performance, can be easily integrated into systems for satellite and radar communications.
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Sethi, Sujeet Kumar. « Design and Analysis of Dual Band Micro strip Patch Antenna ». Thesis, 2015. http://ethesis.nitrkl.ac.in/7538/1/2015_Design_Sethi.pdf.

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This thesis involves the design and analysis of Dual band Microstrip patch antenna which operates at lower and upper resonating frequency of 3.05 GHz and 7.24 GHz respectively. Basically transmission line modelling approach has been used to model the antenna. The proposed antenna has been fed with 50O microstrip feed line. In the first frequency band we have bandwidth of 310MHz (2.91-3.22 GHz) with gain and directivity 3.304dB and 4.393dBi respectively. The second frequency band has a bandwidth of 580MHz (6.69-8.27 GHz) with gain and directivity of 3.534dB and 5.516dBi. Radiation efficiency at the two bands of operations are 75.12% and 63.52% respectively. Design parameters for the proposed antenna have been calculated from the transmission line model equations considering the effects of introducing inset notch parallel to the radiating edge of the antenna. Ground plane dimensions have been optimized by analyzing the antenna characteristics through parametric study. The CST Microwave Studio software has been used to implement the desired design and various antenna parameters have been studied. Furthermore, an attempt has been taken to calculate the return loss vs frequency response through MATLAB coding. The proposed antenna covers a good portion of S-band and C-band. It can be embedded in mobile devices for the purposes of mobile WiMAX, Wi-Fi, Bluetooth and WLAN operations due to its very small size and weight. Also it can be used by weather radar, surface ship radar, and some communications satellites for various surveillance and communication purposes
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CHAUHAN, MANOJ SINGH. « INVESTIGATION OF ELECTROMAGNETIC BAND GAP STRUCTURES FOR MICRO STRIP PATCH ANTENNA ». Thesis, 2014. http://dspace.dtu.ac.in:8080/jspui/handle/repository/15452.

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The main objective of this dissertation “Investigation of Electromagnetic Band Gap Structures for Micro Strip patch Antenna” is to design and simulate the various electromagnetic band gap (EBG) structure in order to investigate their frequency band gap region and reflection phase characteristic for micro strip antenna parameter improvement. Range of frequency region at which wave cannot propagate in the material is known as frequency band gap region and variation in phase of a reflected wave is produced by a surface determined by the reflection phase property. Two dimensional mushroom-like EBG structures have been investigated in this dissertation. The equivalent LC circuit of EBG structure acts as two dimensional electric filter to block the flow of wave. Frequency band gap property is investigated by dispersion diagram, scattering parameter method and reflection phase property is investigated by wave guide method. Electromagnetic Interference (EMI) is a source of noise problems in electronic devices. The EMI is attributed to coupling between sources of radiation and components placed in the same media such as substrate or chassis. This coupling can be either through conducting currents or through radiation. The radiation of electromagnetic (EM) fields is supported by surface currents. Thus, minimization of these surface currents is considered a major and critical step to suppress EMI. In this dissertation, A novel EBG strategy is presented to confine surface currents in antenna substrate. Traditional use of lossy materials and absorbers suffers from considerable disadvantages including mechanical and thermal reliability leading to limited life time, cost, volume, and weight. Here, a new method of EM noise suppression is introduced into micro strip patch antennas using mushroom-type EBG structures. These structures are suitable for suppressing surface currents within a frequency band denoted as the band gap. The effectiveness of the EBG as an EMI suppresser is demonstrated using numerical simulations CST Software. Applications of EBG structure in micro strip antennas are investigated, in which surface wave of micro strip antenna substrate is suppressed by dual layer of EBG around the micro strip patch. Significant improvement in return loss and bandwidth has been achieved. v EBG structure also exhibit property of artificial magnetic conductor (AMC) in a certain frequency range. Phase of reflected wave do not change in this frequency region. PEC ground plane in micro strip antenna gives 180 degree phase shift, which rise the disadvantage of distractive interference between incident wave and reflected wave of micro strip antenna .When PEC ground plane is replaced by AMC ground plane, it gives the constructed interference. Micro strip antenna with AMC ground plane has been investigated. Significant improvement in return loss has been achieved of micro strip antenna.
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Huang, Chao Hsiang, et 黃召翔. « Design of Micro-strip UWB antenna ». Thesis, 2009. http://ndltd.ncl.edu.tw/handle/01372403029133116254.

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碩士
長庚大學
電機工程學研究所
97
This paper proposes a novel ultra-wideband (UWB) and band-notch microstrip antenna. The proposed antenna size is 30 x 30 mm2 and designed to work on a substrate FR4 and relative permittivity of 4.4. Experimental results show that the return loss of the proposed antenna is lower than -10dB from 3.4 to 10.8GHz and the impedance bandwidth is 104%. The radiation patterns within this range are also measured, when 4GHz and 6GHz radiation patterns are omnidirectional in XZ-plane and YZ-plane. Moreover, the use of a 5.15–5.825 GHz frequency band has been limited by IEEE 802.11a for a wireless local area network (WLAN) system. Therefore, the original antenna with a concave slot is proposed to provide the band notched in the vicinity of 5.3GHz. Finally, we set up an experimental UWB system using wireless USB devices. Measured results show that under the free space transmission distance up to 0 to 6m form 53 to 480 Mbit/s data rates the packet error rate are 0%.
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胡毓清. « Defected Ground Structure Application for Micro-strip Antenna Design ». Thesis, 2006. http://ndltd.ncl.edu.tw/handle/30220440942718168030.

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碩士
明新科技大學
電子工程研究所
94
With continuous improvement on the mobile communication technology, personal wireless communication products are getting smaller and lighter in weight. In the mean time, with the enhancement of frequencies in use and the demand on broadband and multi-frequency communication, almost every wireless communication product will install a small antenna in front of the RF to provide the best transmission and receiving of the signal. Therefore, the design of the antenna will play a decisive role in the performance of the wireless communication product. Based on this fact, the research work for designing an efficient and appropriate antenna for the wireless communication product is crucially important. The research topic in this paper will mainly focus on designing the dual Rectangular of common plane micro-strip antenna. The structure will be applied in the design of the dual band frequency antenna. However, because of the fact that the dual Rectangular micro-strip antenna will bring out the serious drawback of harmonic and cross- coupling resonance, we propose two approaches to improve. One is to use the Defected Ground Structure (DGS). This structure can produce the effect of Stop –band under certain frequency range, greatly reduce the energy gap, and moreover suppress the harmonic resonance and improve the Return Loss Level. The other one is to use the traditional open stub. The approach is to insert an open stub in the appropriate position before the signal is fed into micro-strip line to form an effective duplexer switch to properly switch between the lower-frequency and higher-frequency antenna element so that the harmonics can be suppressed. This paper proposes the above two improvement plans together with the simulation result and the real experience to validate the approaches. The result indicate the feasibility and effectiveness of those approaches in designing the dual Rectangular micro-strip antenna.
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Liu, Tzu-Wei, et 劉子瑋. « Study of Multi-Band 2F2L Planar Micro-strip Antenna Design ». Thesis, 2017. http://ndltd.ncl.edu.tw/handle/02518268349794084482.

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碩士
萬能科技大學
電資研究所
105
This paper presents a new planar microstrip antenna architecture (2F2L planar multi-band microstrip antenna), which has the advantages of miniaturization, stable gain simple structure, and it is suitable for the application of multi-band wireless transmission device. 2F2L planar multi-band microstrip antenna is the use of two pairs of symmetrical F and L structure composed of 2F2L rectangular planar dipole antenna. The dimension of antenna is 47 mm x 12 mm x 1.6 mm with a flat and small area and can be printed on FR4 circuit boards using a printing method. This antenna can be excited four resonant frequencies, and then the multi-band effect is achieved. The simulation process use the IE3D simulator, which is a high frequency simulation software program. The simulation results are: resonant frequencies are f_1= 1.72GHz, f_2= 2.32GHz, f_3= 3.58GHz and f_4= 5.8GHz; the return loss S_11 were -17dB, -24.5dB, -17dB and -21.5dB respectively at the resonant frequencies. The resonant frequency bandwidths are BW_1= 100MHz (1.68~1.78GHz), BW_2= 260MHz (2.32 ~ 2.58 GHz), BW_3= 400MHz (3.3 ~ 3.7GHz), and BW_4= 900MHz (5.1 ~ 6 GHz) with S_11 <-10dB, respectively. The implementation of antenna was excuted by using Altium PCB Layout program, which transferred the antenna configuration to FR4 printed circuit board. The measurement results of antenna are f_1 = 1.73GHz, f_2= 2.44GHz, f_3 = 3.49GHz and f_4 = 5.47GHz; the return loss S_11 at resonant points are -11.77dB, -24.6dB, -19.73dB and -16.04dB, and the band width of the four bands corresponding to S_11 is less than -10dB are BW_1 = 110MHz, BW_2 = 300MHz, BW_3 = 740MHz, and BW_4 = 1230MHz, respectively. The frequency bandwidth of these frequencies can be used for LTE1700, LTE 2300, WiFi/Bluetooth/WLAN 2400, LTE 3500, WiFi 3600, LTE 5800 and WiFi 5G band.
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Chan, Yi-lin, et 詹易霖. « ANTENNA COVERING THE WHOLE LTE BANDS WITH A BACKSIDE STRIP COUPLED TO A DRIVEN PATCH ». Thesis, 2015. http://ndltd.ncl.edu.tw/handle/01030664332509134166.

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碩士
大同大學
通訊工程研究所
103
This thesis provides a mobile phone antenna to cover 704MHz-2690MHz. The size of antenna is 45 × 22.5 mm2 and the thickness is 0.8mm on FR4 substrate. This antenna is constituted by the front-side monopole and back-side meandered strip, the meandered strip divided into two parts: the first part apply as a matching circuit, the other part resonant for the frequency of 704MHz, 1405MHz and 2100MHz, the resonant frequency 1050MHz, 1970MHz and 2690MHz is generated by a monopole antenna. The monopole and the meandered strip coupling make the working frequency wider which can replace a multi-band antenna. The use of coupled fed design covers the existing LTE operating frequency and conforms to most system application of the present smart phone, which operating band are LTE (704 MHz ~ 746MHz), LTE (824 MHz ~ 894MHz), LTE (880 MHz ~ 960MHz) and high-band LTE (1710 MHz ~ 2690MHz), and the other provides 5 bands to be covered with seven receiving systems (GSM-850 and GSM-900, DCS-1800, PCS-1900, UMTS, GPS, and IEEE 802.11b).
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Chapitres de livres sur le sujet "MICRO STRIP PATCH ANTENNA"

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Kumar, Arun, et Manish Kumar Singh. « Dual Band Micro Strip Patch Antenna for UWB Application ». Dans Data Science and Analytics, 434–41. Singapore : Springer Singapore, 2018. http://dx.doi.org/10.1007/978-981-10-8527-7_36.

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Kaur, Amandeep, Praveen Kumar Malik et Ramendra Singh. « Planar Rectangular Micro-strip Patch Antenna Design for 25 GHz ». Dans Lecture Notes in Electrical Engineering, 211–19. Singapore : Springer Singapore, 2021. http://dx.doi.org/10.1007/978-981-15-8297-4_18.

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Shah, Priyanka, et Niraj Tevar. « Inset Feed Micro-Strip Patch Antenna for Communication Application Using CST ». Dans Advanced Computing and Intelligent Technologies, 515–22. Singapore : Springer Singapore, 2021. http://dx.doi.org/10.1007/978-981-16-2164-2_41.

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Mahor, Vikas, et Madhav Singh. « A Novel Meta-material Based Mirco-strip Patch Antenna ». Dans Intelligent Computing Applications for Sustainable Real-World Systems, 230–36. Cham : Springer International Publishing, 2020. http://dx.doi.org/10.1007/978-3-030-44758-8_20.

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Kumari, Shraddha, Shubham Sachan et Asmita Rajawat. « Bandwidth Enhancement of Micro-strip Patch Antenna Using Disconnected U-Shaped DGS ». Dans Advances in Intelligent Systems and Computing, 1009–18. Singapore : Springer Singapore, 2018. http://dx.doi.org/10.1007/978-981-10-5903-2_106.

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Rama Krishna, Ch, Ch Prabhu Anand et D. Durga Prasad. « Design of S-Shaped Micro-strip Patch Antenna for Ka Band Applications ». Dans ICICCT 2019 – System Reliability, Quality Control, Safety, Maintenance and Management, 260–68. Singapore : Springer Singapore, 2019. http://dx.doi.org/10.1007/978-981-13-8461-5_29.

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Santra, Arpita, Arnima Das, Abhijit Kundu, Maitreyi R. Kanjilal et Moumita Mukherjee. « On Some Studies of Micro-strip Patch Antenna for Bio-Medical Applications ». Dans Lecture Notes in Bioengineering, 241–46. Singapore : Springer Singapore, 2021. http://dx.doi.org/10.1007/978-981-33-6915-3_25.

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Jebaselvi, G. D. Anbarasi, U. Anitha, R. Narmadha, Harikiran Nimmagadda et Manish Kumar Reddy Nangi. « Design and development of 33GHz micro strip patch antenna for 5G wireless communication ». Dans Recent Trends in Communication and Electronics, 310–15. London : CRC Press, 2021. http://dx.doi.org/10.1201/9781003193838-56.

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Bakade, Kanchan V. « System Design and Implementation of FDTD on Circularly Polarized Squared Micro-Strip Patch Antenna ». Dans Communications in Computer and Information Science, 266–71. Berlin, Heidelberg : Springer Berlin Heidelberg, 2011. http://dx.doi.org/10.1007/978-3-642-20209-4_38.

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Kokare, Anil J., Mahesh S. Mathpati et Bhagyashri S. Patil. « Design and Simulation of Different Structures of Micro Strip Patch Antenna for Wireless Applications ». Dans Techno-Societal 2020, 95–102. Cham : Springer International Publishing, 2021. http://dx.doi.org/10.1007/978-3-030-69921-5_10.

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Actes de conférences sur le sujet "MICRO STRIP PATCH ANTENNA"

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Fazal, Nayyer, et Shahid Bashir. « Penta band micro strip patch antenna ». Dans 2012 International Conference on Robotics and Artificial Intelligence (ICRAI). IEEE, 2012. http://dx.doi.org/10.1109/icrai.2012.6413391.

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Khan, Imran, K. R. Sudhindra, D. Geetha et K. Fakhruddin. « LCP substrate based micro strip patch antenna ». Dans 2016 International Conference on Electrical, Electronics, Communication, Computer and Optimization Techniques (ICEECCOT). IEEE, 2016. http://dx.doi.org/10.1109/iceeccot.2016.7955200.

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Bagwari, Ashish, Rahul Tiwari et Vivek Singh Kushwah. « CPW-Fed Micro-Strip Patch Antenna for Wireless Communication ». Dans 2020 Global Conference on Wireless and Optical Technologies (GCWOT). IEEE, 2020. http://dx.doi.org/10.1109/gcwot49901.2020.9391602.

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Reddy, Aleddula Abhishek. « Deisgn of UWB Range of Micro strip Patch Antenna ». Dans 2020 3rd International Conference on Intelligent Sustainable Systems (ICISS). IEEE, 2020. http://dx.doi.org/10.1109/iciss49785.2020.9316118.

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Mishra, N. K., D. K. Vishwakarma et A. Kumar. « Performance analysis of micro-strip patch antenna and Dielectric Resonator Antenna array ». Dans 2013 International Conference on Emerging Trends in Computing, Communication and Nanotechnology (ICE-CCN). IEEE, 2013. http://dx.doi.org/10.1109/ice-ccn.2013.6528599.

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Kannadhasan, S., et A. C. Shagar. « Design and analysis of U-Shaped micro strip patch antenna ». Dans 2017 Third International Conference on Advances in Electrical, Electronics, Information, Communication and Bio-Informatics (AEEICB). IEEE, 2017. http://dx.doi.org/10.1109/aeeicb.2017.7972333.

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Hadzic, Haris, Wally Verzotti, Zoran Blazevic et Maja Skiljo. « 2.4 GHz micro-strip patch antenna array with suppressed sidelobes ». Dans 2015 23rd International Conference on Software, Telecommunications and Computer Networks (SoftCOM). IEEE, 2015. http://dx.doi.org/10.1109/softcom.2015.7314057.

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Bhide, G., A. Nandgaonkar et S. Nalbalwar. « Dual Band High Gain Union Shaped Micro-strip Patch Antenna ». Dans International Conference on Communication and Signal Processing 2016 (ICCASP 2016). Paris, France : Atlantis Press, 2017. http://dx.doi.org/10.2991/iccasp-16.2017.106.

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Chaari, Mohamed Zied, Rashid Rahimi, Hamadi Ghariani et Mongi Lahiani. « Microwave energy harvesting using rectangular micro-strip patch array antenna ». Dans 2017 Sensors Networks Smart and Emerging Technologies (SENSET). IEEE, 2017. http://dx.doi.org/10.1109/senset.2017.8125041.

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R, Hannah Jessie Rani, et Hamsa S. « Micro-strip Patch Antenna for 5G sub 6 GHz Applications ». Dans 2022 International Interdisciplinary Humanitarian Conference for Sustainability (IIHC). IEEE, 2022. http://dx.doi.org/10.1109/iihc55949.2022.10060179.

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