基于CSRR结构的双陷波超宽带天线设计

设计了一个基于圆环型互补开口谐振环(CSRR)结构的双陷波超宽带天线。通过在超宽带天线的辐射体上蚀刻圆环形CSRR结构实现了双陷波特性,对CSRR结构实现陷波特性的机理进行了分析。测量结果表明,天线在超宽带系统3.1~11.0GHz工作频段内的电压驻波比小于2,在WiMAX和WLAN频带内具有良好的陷波特性。天线体积较小,便于加工,适用于超宽带天线单元。     

具有双陷波特性的超宽带平面天线设计

设计了一种带有2个陷波频段的超宽带天线。天线的缝隙和馈电枝节采用相反的梯形结构,以实现较好的阻抗匹配。通过在宽缝隙中增加2个线形枝节和1个"E"形结构,使得天线在3.0 GHz~3.9 GHz和5 GHz~6 GHz 2个频段内出现频率阻断。根据天线的阻抗曲线,给出等效谐振电路并对陷波产生的原理进行了分析。最后对天线的远场辐射特性进行分析和阐述,测试结果良好,达到了陷波超宽带天线频率阻断的效果。     

一种陷波可重构的超宽带天线设计与研究

该文设计了一种具有四陷波及可重构特性的超宽带天线。通过在天线辐射贴片、微带馈线上刻蚀U形槽,以及在改进型地板上添加环形开口寄生单元来实现天线四陷波特性。采用在陷波结构中加入PIN二极管开关的方法实现陷波可重构特性,通过开关的断开与闭合,分别实现三陷波和四陷波特性,从而进一步提高了超宽带频段的利用率。分析了天线陷波产生的原理,研究了天线部分尺寸参数对陷波的影响。通过仿真和实物测量结果对比表明,该天线在3~11.74 GHz频段内可有效抑制窄带系统的干扰。天线尺寸为24 mm×16 mm×0.8 mm,结构较紧凑,可广泛用于各种超宽带通信系统。     

一种可控三陷波超宽带天线设计与研究

为了避免如WiMax, WLAN和X频段卫星系统等窄带通信系统对超宽带通信系统的影响,该文提出一种具有可控三陷波特性的超宽带天线。该天线通过在辐射贴片和接地板上开槽,并在基板背面增加环形寄生单元的方法实现三陷波特性。天线在3.1~10.6 GHz的超宽带频段内能够有效地工作并抑制3种不同的窄带通信系统的干扰。同时在环形寄生单元处增加开关设置,使天线能够实现双/三陷波的功能切换,并增强陷波性能。实测和仿真结果吻合,该天线实现了良好的陷波功能,在工作频段内有良好的辐射方向特性。     

一种新型双陷波超宽带天线设计

设计了一种新型双陷波超宽带印刷天线。辐射贴片底部为梯形结构,实现了良好的阻抗匹配。通过在贴片上加载两个U型缝隙,分别在中心频率3.5GHz和5.5GHz处产生陷波。比较陷波前后天线表面电流密度,并用传输线理论对陷波产生机理进行了分析。天线实测与仿真结果吻合,通带内天线辐射效果良好,陷波频段内增益下降超过5dB,达到了陷波抑制的效果。     

一种紧凑型超宽带双陷波天线的设计

提出了一款共面波导馈电的超宽带双陷波天线。该天线主要由梯形共面地、微带馈线和圆形辐射体三部分构成。其中,梯形共面地使天线实现超宽带,圆形辐射贴片上的倒L形槽和弧形槽使天线实现陷波特性。使用Ansoft HFSS软件对所设计天线进行仿真实验,然后加工成实物天线并进行测试。结果表明:天线回波损耗及辐射方向图的实测结果与仿真结果基本吻合,在3.0～10.9 GHz频段内,除陷波频段3.3～3.6 GHz和5.15～5.825 GHz外,天线的回波损耗均在-10 dB以下,相应工作频段内有较好的辐射方向图。因此,所设计的天线性能满足超宽带通信系统应用要求。     

一种具有陷波特性的改进型Vivaldi 超宽带天线

为了提高常规Vivaldi 天线低频段前向辐射增益,避免超宽带天线对某些已有频段的影响,提出了一 种覆盖1. 2 ~14 GHz 的具有陷波特性的高增益超宽带端射天线。该天线通过在辐射贴片两侧加载Y 形缝隙,有利 于天线表面电流向槽线汇聚,使天线的辐射特性明显提高。低频部分(1. 2 ~7. 5 GHz)的增益比原始天线提高最多2 dB,通过使用CSRR 结构,实现了对WLAN 应用频段(5. 125 ~5. 825 GHz)的隔离,使该天线具有陷波特性。最终,对 天线实物进行加工和测试,进一步验证了设计的可靠性。     

一种小型具有双阻带特性的超宽带天线设计

提出了一种具有双阻带特性的共面波导馈电超宽带天线。通过在辐射单元上开E型槽实现了3.75 GHz的第一个陷波结构,并在地板上开两条对称槽实现5.5 GHz的第二个陷波结构。文中提出的具有阻带特性超宽带天线的实测结果与仿真结果吻合较好。除了两个期望的阻带外其他超宽带频段内,该天线满足VSWR<2。同时给出了仿真辐射方向图和增益图。     

基于SRR结构的陷波超宽带天线设计

针对超宽带系统易受窄带信号干扰的问题,设计了一种新颖的基于金属开口谐振环(SRR)结构的平面超宽带陷波天线。在天线的辐射贴片上加载U形缝隙,实现了其陷波特性。利用仿真软件研究了U形缝隙的物理尺寸对其陷波特性的影响,并对所设计的超宽带天线进行了制作和测量。结果表明,所制天线在超宽带系统3.1~10.6GHz工作频段的电压驻波比(VSWR)小于2,在WLAN频段具有良好的陷波特性,有效地抑制了超宽带通信系统与窄带通信系统之间潜在的干扰。     

一种新型具有双陷波特性的超宽带天线设计

本文提出了一种新型紧凑的具有双陷波特性的印刷超宽带天线。天线采用微带传输线馈电,并通过圆形与矩形 的混合结构辐射单元和带有矩形开槽结构的地板来实现天线的超宽带特性,工作带宽覆盖UWB 频率范围。通过地板上 两个对称的J 形开槽和微带馈线两侧对称添加的线型结构单元来实现双陷波特性,两个陷波频段刚好覆盖了3.5GHz 的 WIMAX 频段标准和5.2/5.8GHz 的WLAN 频段标准。同时,该天线在工作频带范围内具有良好的辐射特性,符合超宽带 通信的使用标准。     

Compact printed ultra-wideband monopole antenna with dual band-notched characteristics

A compact printed ultra-wideband (UWB) monopole antenna with dual band-notched characteristics is presented. One complementary split-ring resonator (CSRR) is etched inside the patch of the monopole antenna to achieve dual notch frequency bands. A practical example for a UWB antenna (working from 2.90 to 12 GHz) is demonstrated, with one notch frequency band at 3.40-3.48 GHz and the other at 5.40-5.98 GHz. In addition, the effect of the dimensions of the CSRR on the dual notch frequency bands is also analysed.     

一种小型化双陷波可重构UWB天线设计

提出了一种小型化的双陷波可重构超宽带(ultra wide band, UWB)天线,通过在辐射贴片上刻蚀大、小两个C形槽,实现5G (3.3~4.4 GHz)/WiMAX (3.3~3.6 GHz)和WLAN (5.150~5.825 GHz)两个频段的陷波. 采用两个PIN二极管跨接在C形槽上,通过控制PIN二极管的通断状态,在两个频段上实现陷波可重构. 为了实现小型化,天线采用削顶圆形结构的辐射贴片,并将C形槽设计为嵌套结构,天线最终尺寸为18.0 mm×19.5 mm. 仿真与测量结果表明:天线可以在UWB、两种单陷波和双陷波共四种状态下工作,UWB频段为3.1~11.0 GHz,两个单陷波频段分别为3.2~4.9 GHz、5.2~6.0 GHz,双陷波频段为3.25~4.75 GHz和5.3~6.1 GHz. 天线的最大增益为2.8 dBi,具有良好的辐射特性.     

Metamaterial inspired quad band circularly polarized antenna for WLAN/ISM/Bluetooth/WiMAX and satellite communication applications

A CPW fed metamaterial inspired Quadband circularly polarized antenna is presented in this article. The proposed antenna consists of defected ground structure with a radiating stub, which is at opposite side of the feedline. A waveguide mode of analysis is carried out for split ring resonator (SRR) and complimentary split ring resonator (CSRR) to enhance the properties of metamaterials. The proposed antenna analysis is taken iteration wise and used FR-4 Material as the substrate material with Ɛ_r = 4.4 and analysed using ANSYS electromagnetic desktop. The designed antenna projecting the peak gain of 4.8 dB and it is working in the application bands of WLAN/ISM/Bluetooth at 2.4 GHz, 5.8 GHz and 3.35 WiMAX band, X-band downlink satellite communication system (7.25–7.75 GHz) and ITU band (8–8.5 GHz) with fractional bandwidth of about 70%. Proposed antenna exhibits circular polarization at 2.39–2.55 GHz, 3.05–3.1 GHz, 4–5 GHz and 6.3–6.64 GHz respectively. To know the signal integrity of the antenna, time domain analysis is carried out for identical antennas in two conditions (face to face and side by side) with the help of CST microwave studio. The designed antenna showing excellent correlation in measurements with respect to simulation results.     

CSRR Loaded Tunable L-Strip Fed Circular Microstrip Antenna

A tunable L-strip fed circular microstrip antenna on thick substrate with CSRR in the ground plane has been analysed and investigated. The antenna is analysed using cavity model and circuit theoretic approach for initial design and then simulated on IE3D simulation software. The antenna is made tunable with PIN diode which makes it to work in different configurations. Two diodes were used to implement a double annular slot, one annular slot and one split slot and CSRR in the ground plane. While other configurations of diodes provide bandwidth and radiation pattern diversity, CSRR provides size reduction of upto 13.31 % along with high gain directivity and radiation efficiency. A maximum gain of 8 dBi, directivity 8.3 dBi has been achieved in the respective band of operations. The antenna exhibits wideband along with multiband characteristic.     

Penta-notched UWB antenna with sharp frequency edge selectivity using combination of SRR,CSRR, and DGS

This work presents penta-notched UWB antenna with sharp frequency edge selectivity using combination of SRR, CSRR, and DGS to reject the WiMAX (3.30–3.60 GHz), lower WLAN (5.150–5.350 GHz), upper WLAN (5.725–5.825 GHz), downlink of X-band satellite communication (7.0–7.40 GHz), and the uplink of X-band satellite communication (8.10–8.50 GHz) frequency bands. All these frequency bands lie within the UWB frequency spectrum. The proposed antenna is suitable for portable communication applications due to its compact dimensions. It sharply notches the existing frequency bands to mitigate the interference caused by nearby wireless communication systems within UWB frequency range. The sharp notching is achieved by the combination of complementary split ring resonators (CSRR) on the radiating semi-circular patch, split ring resonators (SRR) placed at the junction of the feedline, and a pair of defected ground structures (DGS). All notched bands can be well controlled and shifted and the equivalent lumped model of the notched bands are also developed for validation. The proposed antenna simulated, and measured results show better performance over the present state-of-the-art designs. The proposed penta-notched UWB antenna possesses better reflection coefficient, VSWR, stable gain, and small foot print. The proposed antenna has a nearly omnidirectional radiation pattern in the passbands.     

A compact microstrip fed dual polarised multiband antenna for IEEE 802.11 a/b/g/n/ac/ax applications

A compact microstrip fed dual polarised multiband monopole antenna for IEEE 802.11 a/b/g/n/ac/ax communication based applications is presented. The antenna is circularly polarised in IEEE 802.11 b/g bands while linearly polarised in IEEE 802.11 a/n/ac/ax bands. The asymmetric U-shaped slot in the ground plane of proposed antenna is used to introduce the necessary 90° phase shift between two orthogonal electric field vectors necessary for circular polarisation. The Ω-shaped slot on patch is used to introduce a band elimination notch between the usable frequency bands. The radiation characteristics of the proposed antenna (at 2.4 GHz) can be changed from left hand circular polarisation (LHCP) to right hand circular polarisation (RHCP) by replacing asymmetric U-shaped slot with its mirror image on the opposite side of ground plane. The proposed antenna has a wide impedance bandwidth of 110.8% and can also be used in various applications including worldwide interoperability for microwave access (WiMAX) and IEEE 802.11p standard based V2V (Vehicle to Vehicle) communication.     

SRR and S-shape slot loaded triple band notched UWB antenna

This paper demonstrates the design of a triple band notched ultrawideband circular microstrip patch antenna loaded with Complementary Split RingResonator (CSRR) and S-shaped slot in microstrip feed line. Complementary Split Ring Resonator slot and S-shaped slot are used to produce band notched characteristics for WiMAX band (3.30–3.60 GHz) and WLAN band (5.10–5.80 GHz) respectively. The downlink frequency band (7.25–7.75 GHz) of X-band for satellite communication is notched using Symmetrical Split Ring Resonator Pair (SSRRP) as electromagnetic coupling element near microstrip feed line which produces band stop characteristics. Measured results of fabricated antenna prototype are compared with simulated results and found in correspondence. The VSWR and vector current plots show evidence of the significant suppression in the desired frequency bands.     

Compact CPW-fed dual-band antenna

A novel coplanar waveguide (CPW) antenna is proposed for dual-band WLAN applications. It comprises a rectangular patch, a rectangular notch cut at the lower edge of the patch and a CPW transmission line. The rectangular patch together with the ground plane of the coplanar waveguide radiates at the lower frequency band, 2.4 GHz for IEEE 802.11b/g, while the rectangular notch resonates in the upper band, 5.2/5.8 GHz for IEEE 802.11a. The designed antenna is only 32 × 5 mm, which can provide stable omnidirectional radiation patterns with an average gain of 2 dBi in both the bands. The antenna is very compact and suitable for 2.4 and 5.2/5.8 GHz WLAN operations.     

一种新型极化可重构微带天线

利用互补开口谐振环(CSRR)结构提出了一种新型极化可重构微带天线。将CSRR 和一个PIN 二极管开关加载在天线的地板上,通过控制二极管开关的状态,可以实现左旋圆极化和线极化之间的切换,无需额外的偏置电路。利用仿真软件分析了CSRR 的尺寸和位置对天线圆极化特性的影响。所设计的天线工作在5. 8GHz 频段范围,测试结果与仿真结果吻合较好。实验结果表明,在圆极化状态下,中心频率5. 77GHz,-10dB 阻抗带宽约360MHz,最小轴比为1. 5dB,3dB 轴比带宽为80MHz;线极化状态下,中心频率5. 72GHz,-10dB 阻抗带宽约200MHz。天线增益均为6dB 左右,具有良好的方向性,可用于现代无线通信系统中。     

Performances of OSIC Detector of an UpLink OFDM Massive-MIMO System in Rayleigh and Ricain Fading Channels

A compact rectangular microstrip-fed Ultra Wideband patch antenna with double band notched feature at Wi-Max and WLAN is offered in this paper. The designed antenna is composed of an ordinary rectangular patch antenna with a partially defective ground structure. For achieving dual notch characteristics a ‘U’ and ‘Reversed U’ slots are embedded in the radiating patch. The partial ground plane structure with U shaped slot in the middle is incorporated for achieving additional resonance and bandwidth enhancement. The proposed antenna has a measurement of 20 × 33 × 1.6 mm³. First notch created by U shaped slot at frequency 3.5 GHz is for Wi-Max (from 2.9 to 4.5 GHz) and Second notch which is generated by Reversed U shaped slots at frequency 5.4 GHz is for WLAN (from 5.49 to 6.45 GHz). The antenna covers almost complete range of Ultra Wideband (3.1–10.6 GHz). The Simulation analysis of the proposed antenna is carried out using CST-2011 simulation software. The radiation pattern of the simulated antenna is near Omnidirectional and the Gain of proposed antenna is almost stable over the range of UWB excluding notch bands.