본 논문은 슬롯이 삽입된 접지, 수정된 급전선 및 서로 다른 반지름을 갖는 원형 링 구조의 패치 안테나를 제시한다. 안테나의 크기는 $15{\times}12mm^2$이며, 전체 면적 $180mm^2$ 및 전기적 치수 $0.14{\lambda}{\times}0.12{\lambda}$(초단 주파수)를 갖는다. 제안된 안테나는 3.1 GHz ~ 12.3 GHz 대역을 포함하며, 대역폭 비 4.13:1, 비 대역폭 122%, 반사계수 최대 -38dB의 결과를 보인다. 소형화된 크기를 증명하기 위해 대역폭 크기 비율이 계산되었다. 공급 라인에 삽입 된 얇은 슬롯은 전체 주파수 대역에서 우수한 임피던스정합을 제공한다. 제안된 안테나의 시뮬레이션은 반사 계수 ${\leq}-10dB$, VSWR 2:1, 방사 패턴 및 군지연 (ns)을 시뮬레이션 결과로 제시하였다. 제안된 안테나는 우수한 임피던스 정합 및 매우 작은 크기의 장점을 보이며, 대역폭 향상 및 UWB 단거리 고속 무선통신을 제공한다.
본 논문은 슬롯이 삽입된 접지, 수정된 급전선 및 서로 다른 반지름을 갖는 원형 링 구조의 패치 안테나를 제시한다. 안테나의 크기는 $15{\times}12mm^2$이며, 전체 면적 $180mm^2$ 및 전기적 치수 $0.14{\lambda}{\times}0.12{\lambda}$(초단 주파수)를 갖는다. 제안된 안테나는 3.1 GHz ~ 12.3 GHz 대역을 포함하며, 대역폭 비 4.13:1, 비 대역폭 122%, 반사계수 최대 -38dB의 결과를 보인다. 소형화된 크기를 증명하기 위해 대역폭 크기 비율이 계산되었다. 공급 라인에 삽입 된 얇은 슬롯은 전체 주파수 대역에서 우수한 임피던스 정합을 제공한다. 제안된 안테나의 시뮬레이션은 반사 계수 ${\leq}-10dB$, VSWR 2:1, 방사 패턴 및 군지연 (ns)을 시뮬레이션 결과로 제시하였다. 제안된 안테나는 우수한 임피던스 정합 및 매우 작은 크기의 장점을 보이며, 대역폭 향상 및 UWB 단거리 고속 무선통신을 제공한다.
This paper presents a low profile multi circular ring with different radius, patch antenna with modified feed line and slotted ground. The size of the antenna is $15{\times}12mm^2$, having electrical dimensions of $0.14{\lambda}{\times}0.12{\lambda}$ (at lower initial frequency...
This paper presents a low profile multi circular ring with different radius, patch antenna with modified feed line and slotted ground. The size of the antenna is $15{\times}12mm^2$, having electrical dimensions of $0.14{\lambda}{\times}0.12{\lambda}$ (at lower initial frequency) and footprints of $180mm^2$. The proposed antenna covers 3.1 to 12.3 GHz, reflection coefficient up to -38 dB with Bandwidth ratio of 4.13:1 and fractional Bandwidth of 122%. Bandwidth dimension ratio has been calculated (which is 6246) as a proof for compact size. Thin slots introduced on the feed line provide good impedance matching for whole frequency band. Numerical simulations of the proposed antenna are reported in terms of reflection coefficient ${\leq}-10dB$, vswr 2:1, radiation pattern and group delay (ns). The proposed antenna has advantage of very small size along with better impedance match that provides a practical approach to realize it for BW enhancement and UWB applications.
This paper presents a low profile multi circular ring with different radius, patch antenna with modified feed line and slotted ground. The size of the antenna is $15{\times}12mm^2$, having electrical dimensions of $0.14{\lambda}{\times}0.12{\lambda}$ (at lower initial frequency) and footprints of $180mm^2$. The proposed antenna covers 3.1 to 12.3 GHz, reflection coefficient up to -38 dB with Bandwidth ratio of 4.13:1 and fractional Bandwidth of 122%. Bandwidth dimension ratio has been calculated (which is 6246) as a proof for compact size. Thin slots introduced on the feed line provide good impedance matching for whole frequency band. Numerical simulations of the proposed antenna are reported in terms of reflection coefficient ${\leq}-10dB$, vswr 2:1, radiation pattern and group delay (ns). The proposed antenna has advantage of very small size along with better impedance match that provides a practical approach to realize it for BW enhancement and UWB applications.
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문제 정의
In this article, we describe a compact MCR modified feed line antenna for ultra wide band applications where the key factor in achieving a small size is careful parametric selection targeting at reasonable footprint reduction while maintaining suitable level of electrical performance. The final design exhibits a size of only 180 ㎟.
제안 방법
Circularly polarized (CP) wide slot antenna feed by a microstrip with wide axial ratio bandwidth for C band applications has been reported in [7]. The overall design is very simple and unique to achieve 3 ㏈ axial ratio band by protruding a horizontal stub from the ground plane to wards the centre of wide slot (WS) and then feeding the WS with a microstrip feed line positioned to the side of the WS, underneath the protruded stub. A compact HUT-shaped printed antenna[8], an inverted F-shaped radiating patch on one side of the substrate and rectangular ground plane with L-shaped slot on the other side[9], hexagonal patch with rectangular slot in ground[10] are described to support the literature.
대상 데이터
Similarly as it is mentioned above that the main Radiating patch consists of number of rings having different dimension values. The thoughts behind this design were simple circular patch R1 of dimension 4 mm along with conventional (straight) microstrip feed line. The relation between rings is elaborated below
참고문헌 (15)
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