、新型說明: 【新型所屬之技術領域】 本創作係有關於一種可任意設置高頻輻射體之天線結 構,尤指一種用於無線通訊信號接收與發射的 高頻輻射體之天線結構。 【先前技術】 天線主要負責訊號接收與發射的功能,隨著科技進步 發屐,所應用的範圍遍及日常生活的每一產品,包括:筆 記型電腦、手機、車用衛星導航、數位電視等。因應不同 通訊規範衍生出不同的天線操作頻段,並且配合益線產品 外觀輕薄則、_勢’域為了滿足上述各種需求遂朝向 寬頻化與微型化研發改良。 傳統高頻天線於研發階段遭遇到的挑戰在於微型化咬 計時’各倾會互_合產生讀,進㈣響天線本體的 特性造成頻寬降低、增益與效率降低等不良效果。 習知的高頻天線以單面印刷方式將高麻射體佈設於 基板上,形成—金屬平面天魏,屬平面天線體主要 係由複_射體間隔排列,可增加電波截斷面積並增強1 收發特性,其高頻操作頻段範圍為24GHZ附近。'、 田其高:天線僅於單面設置天線輻射體,未善加利 土又,《面積’使得南頻天線整體尺寸微型化成效 有限;亚且上述之高頻天線操作頻段未涵蓋至傳絲New type of description: [New technical field] This creation relates to an antenna structure in which a high-frequency radiator can be arbitrarily set, and more particularly to an antenna structure for a high-frequency radiator for receiving and transmitting wireless communication signals. [Prior Art] The antenna is mainly responsible for the function of signal reception and transmission. With the advancement of science and technology, the application range covers every product in daily life, including: notebook computers, mobile phones, satellite navigation for vehicles, digital TVs, etc. In response to different communication specifications, different antenna operating frequency bands are derived, and the appearance of the benefit line products is light and thin, and the _ potential field is developed to meet the above various requirements, towards broadband and miniaturization. The challenge encountered in the development of traditional high-frequency antennas is that the miniaturized bite timings will produce read and read, and the characteristics of the antenna body will reduce the bandwidth, gain and efficiency. The conventional high-frequency antennas are arranged on the substrate by a single-sided printing method to form a metal plane, and the planar antenna body is mainly arranged by a complex ray, which can increase the radio wave cut-off area and enhance 1 Transceiver characteristics, its high frequency operating frequency range is around 24GHZ. ', Tian Qigao: The antenna only sets the antenna radiator on one side, and the area is not good. The "area" makes the overall size of the south frequency antenna miniaturized. The above-mentioned high frequency antenna operating frequency band is not covered. wire
Gsrrr=rs(i.57GHz),導致天線無法將無線二 星定位系統整合為-,甚為可惜。 叙,本創作人有感於上述問題之可改善,乃潛心研 M395272 究旅配合學理之運用,而提種設計合理JL有效改善上 述間題之本創作。 【新哦内容】 本創作之目的,在於提供〆種可任意設置高頻輕射體 之天線結構’其高頻輻射體可設置於天線結構各處’旅且 與有多個操作頻段且涵蓋频段包含低頻至高頻。 為了解決上述技術問題,根據本創作之實施例’提供 一種高頻天線’其包括:一微波基板、一第一天線單元、 一第二天線單元、一第三天線單元、第四天線單元及一金 屬件。第一天線單元具有一第一線路部、/第一金屬區及 一第二線路部,第三天線單元具有一高頻輻射體及一第二 金屬區。該第一天線單元、該第二天線單元及該第三天線 單元沒置於该微波基板之表面,該金屬件設置於該微波基 板之一邊緣,且該金屬件另一端連接於該第二天線單元之 一端。 因此’本創作的有益效果在於:藉由半聯電容之設計 ’叮將尚頻輪射體設置於微波基板之正反面各處’提升天 線結構設計的彈性運用。本創作可任意設置高頻輻射體之 天線結構之共振模態可在704〜960 MHz及〜2690 MHz 頻帶附近,並利用各天線單元間的間距調整,以控制各天 線單元間的電磁耦合能量,進而調整天線之共振頻率,滿 足各種無線通訊標準之操作頻段。 為使能更進一步瞭解本創作之特徵及技術内容,請參 閱以下有關本創作之詳細說明與附圖,然而所附圖式僅提 供參考與說明用,並非用來對本創作加以限制者。 4/15 M395272 【實施方式】 請參閱第一圖至第四圓所示,為本創作之第—實施例 ,該可任意設置高頻輻射體之天線結構Μ包括:一微波基 板1、一第一天線單元2、一第二天線單元3、—第三天 線單元4、一第四天線單元5及一金屬件6。 該微波基板1具有一第一表面1〇及一與該第一表面 1 0相對之第二表面1 1。 該第一天線單元2具有一第一線路部2 〇、一第一金 屬區2 1及一第一線路部2 2,該第一天線單元2設置於 該第一表面10。該第一金屬區2丄可為方形金屬片,該 第一線路部2 0具有一從該第一金屬區2丄向外延伸之第 一區段2 0 1、一從該第一區段2 〇丄的一末端朝向垂直 該第一區段2 0 1的方向延伸之第二區段2 〇 2、一從該 第二區段2 0 2的一末端朝向垂直該第二區段2 〇 2的方 向延伸之第三區段2 〇 3、一從該第三區段2 0 3的一末 端朝向該第一區段2 〇1的方向延伸且平行於該第二區段 202之第四區段204、一從該第四區段2 〇 4的一末 端朝向垂直該第四區段2 〇 4的方向延伸之第五區段2 〇 5、一從該第五區段2 〇 5的一末端朝向垂直該第五區段 2 0 5的方向延伸之第六區段2 〇 6及一從該第六區段2 0 6的一末端朝向垂直該第六區段2 〇 6的方向延伸之第 七區段2 0 7。該第二線路部2 2具有一從該第一金屬區 2 1向外延伸之第一延伸部2 2 1及一從該第一延伸部2 21的一末端朝向垂直該第一延伸部2 2 1的方向延伸之 第一末端部2 2 2。 s亥第二天線單元3具有一第二延伸部3 〇及一從該第 5/15 —延伸部3 0的一末端朝向垂直該第二延伸部3 0的方向 延伸之第二末端部3丨,該第二天線單元3設觅於該第一 表面丨〇。 遠第三天線單元4具有一第二金屬區4 〇及一高頻輻 1 ’該第三天線單元4設置於該第二表面1 1。該 叫頻私射體41具有一高頻延伸部411及一從該高頻延 41 ”ΙΜ 1 ]的一末端朝向垂直該高頻延伸部4 :丨1的方向 ,^之高頻末端部4 :丨2,該高頻輻射體4 1與該第二金 屬區4 0連接。該笫二金屬區4 0及該高頻末端部4 1 2 J為^形金屬片。該第二金屬區4 〇對應於該第一金屬區 2該笫二金屬區4 〇與該第一金屬區2 1之間形成一 ^有屯各特性之對應區域S,且該第二金屬區4 〇設有一 'L 3 °亥岛入點[’可連接同轴傳輸線(圖未示)饋入 訊號。 该第四天線單元5具有一第四延伸部5 〇,其設置於 該第二表面丨:丨。 …一該第—天線單元2、該第二天線單元3、該第三天線 卓元4及該第四天線單元5可為金屬微帶。 該金屬件6設置於該微波基板丄上,該金屬件6具有 多個分別與該微波基板1、該第一天線單元2及該第二天 線單元3連接之金屬連接片6 〇。該些金屬連接片6 〇可 分為固定用途與電性連接用途,該金屬件6經由該些金屬 連接片6 0連接固定於該微波基板1上;該金屬件6透過 該些金屬連接片6 0,分別電性連接於該第一天線單元2 及該第二天線單元3,該些金屬連接片6 〇分別電性連接 於該第一末端部2 2 2及該第二末端部3 1連接,且該金 6/15 M395272 屬件6具有接地的功效。 本創作之可任意設置高頻輻射體之天線結構Μ尺寸可 為60*3*10 mm3 ,其中該微波基板1之厚度可為0.4 mm ,該第一天線單元2、該第二天線單元3、該第三天線單 元4及該第四天線單元5可為厚度〇. 1 mm之金屬薄體。 _ 請參閱第五圖至第八圖所示,為本創作之第二實施例 .,該可任意設置高頻輻射體之天線結構Μ包括:一微波基 • 板1、一第一天線單元2、一第二天線單元3、一第三天 線單元4、一第四天線單元5及一金屬件6。 ® 該微波基板1、該第一天線單元2、該第二天線單元 3、該第四天線單元5及該金屬件6之配置與本創作第一 ^ 實施例相同。 該第三天線單元4具有一設置於該第二表面11之第 二金屬區4 0及一設置於該第一表面1 0之高頻輻射體4 ^ 1。該高頻輻射體41具有一高頻延伸部411及一從該 高頻延伸部411的一末端朝向垂直該高頻延伸部411 的方向延伸之高頻末端部41 2,該高頻輻射體4 1與該 • 第一金屬區2 1連接。該第二金屬區4 0對應於該第一金 ‘· 屬區2 1,該第二金屬區4 0與該第一金屬區2 1之間形 ' 成一具有電容特性之對應區域S,且該第二金屬區40設 有一饋入點F,該饋入點F可連接同軸傳輸線(圖未示) 饋入訊號。 本創作之第二實施例與第一實施例差別在於,第二實 施例之該高頻輻射體41設於該第一表面1 0,且該高頻 輻射體41與該第一金屬區2 1連接。透過將該高頻輻射 體41設置於不同的位置,於天線結構設計將具有更大的 7/15 M395272 彈性可調整天線整體佈局。 請參間笫九_示’依據上述本劍作之第一货施例及 P贯施例所狀料任意設置高軸㈣之天線結構μ 來進仃⑽,可得财創作在不同頻率_ζ)下所得到之駐 波岡(VSWR),由第九圖實驗結果可知,該可任意設置高 頻零讀體之天線結構Μ具有多個共振模態且形成兩組駐= 丨雜於3 (m之可操作頻段範間,此返回損失曲線證明本剑 作為涵蓋多個㈣搬_之天職構。並可藉由調夢該Gsrrr=rs (i.57GHz), it is a pity that the antenna cannot integrate the wireless binary positioning system into -. Syria, the creator feels that the above problems can be improved, but is devoted to the use of M395272 research and cooperation, and the rational design of JL effectively improves the creation of the above questions. [New content] The purpose of this creation is to provide an antenna structure that can arbitrarily set up a high-frequency light-emitting body. Its high-frequency radiator can be placed in the antenna structure. It has multiple operating frequency bands and covers the frequency band. Contains low to high frequencies. In order to solve the above technical problem, an embodiment of the present invention provides a high frequency antenna that includes: a microwave substrate, a first antenna unit, a second antenna unit, a third antenna unit, and a fourth antenna unit. And a metal piece. The first antenna unit has a first line portion, a first metal portion and a second line portion, and the third antenna unit has a high frequency radiator and a second metal region. The first antenna unit, the second antenna unit, and the third antenna unit are not disposed on a surface of the microwave substrate, the metal member is disposed on an edge of the microwave substrate, and the other end of the metal member is connected to the first One end of the two antenna elements. Therefore, the beneficial effect of this creation is that the design of the semi-coupling 叮 设置 尚 尚 尚 设置 设置 设置 设置 设置 设置 设置 设置 设置 设置 设置 设置 设置 设置 设置 设置 ’ ’ ’ ’ ’ ’ ’ ’ ’ ’ ’ ’ ’ ’ The resonance mode of the antenna structure of the high-frequency radiator can be arbitrarily set in the vicinity of the 704~960 MHz and ~2690 MHz bands, and the spacing between the antenna elements is adjusted to control the electromagnetic coupling energy between the antenna elements. Furthermore, the resonant frequency of the antenna is adjusted to meet the operating frequency bands of various wireless communication standards. In order to further understand the features and technical contents of the present invention, please refer to the following detailed description and drawings of the present invention. However, the drawings are only for reference and explanation, and are not intended to limit the creation. 4/15 M395272 [Embodiment] Please refer to the first to fourth circles. For the first embodiment of the present invention, the antenna structure of the high-frequency radiator can be arbitrarily arranged, including: a microwave substrate 1, a first An antenna unit 2, a second antenna unit 3, a third antenna unit 4, a fourth antenna unit 5, and a metal member 6. The microwave substrate 1 has a first surface 1A and a second surface 11 opposite the first surface 10. The first antenna unit 2 has a first line portion 2, a first metal region 2 1 and a first line portion 22, and the first antenna unit 2 is disposed on the first surface 10. The first metal region 2丄 can be a square metal piece, the first line portion 20 has a first segment 2 0 1 extending outward from the first metal region 2丄, and a first segment 2 a second end 2 〇 2 of the end of the crucible extending in a direction perpendicular to the first section 2 0 1 , and an end from the end of the second section 2 0 2 toward the second section 2 〇 2 a third section 2 〇3 extending in a direction extending from an end of the third section 203 toward the first section 2 〇1 and parallel to a fourth section of the second section 202 a segment 204, a fifth segment 2 〇5 extending from an end of the fourth segment 2 〇4 toward a direction perpendicular to the fourth segment 2 〇4, and a segment from the fifth segment 2 〇5 a sixth section 2 〇6 extending toward the direction perpendicular to the fifth section 205 and extending from an end of the sixth section 206 toward the direction perpendicular to the sixth section 2 〇6 The seventh section is 2 0 7. The second line portion 2 2 has a first extending portion 2 2 1 extending outward from the first metal portion 21 and a first extending portion 2 21 from an end of the first extending portion 2 21 The first end portion 2 2 2 extending in the direction of 1. The second antenna unit 3 has a second extending portion 3 and a second end portion 3 extending from a distal end of the fifth/15-extension portion 30 toward a direction perpendicular to the second extending portion 30. The second antenna unit 3 is disposed on the first surface 丨〇. The far third antenna unit 4 has a second metal region 4 〇 and a high frequency antenna 1 ′. The third antenna unit 4 is disposed on the second surface 11 . The radio frequency transmitter 41 has a high frequency extension portion 411 and a high frequency end portion 4 from a distal end of the high frequency extension 41 ΙΜ 1 ] toward a direction perpendicular to the high frequency extension portion 4 : 丨 1 The 高频2, the high-frequency radiator 41 is connected to the second metal region 40. The bismuth metal region 40 and the high-frequency end portion 4 1 2 J are ^-shaped metal sheets. The second metal region 4 〇 corresponding to the first metal region 2, the second metal region 4 〇 and the first metal region 2 1 form a corresponding region S having various characteristics, and the second metal region 4 is provided with an 'L 3 °Hai Island Inlet ['Connectable coaxial transmission line (not shown) feeds in signal. The fourth antenna unit 5 has a fourth extension 5 〇, which is disposed on the second surface 丨: 丨. The first antenna unit 2, the second antenna unit 3, the third antenna element 4, and the fourth antenna unit 5 may be metal microstrips. The metal member 6 is disposed on the microwave substrate, the metal member 6 has a plurality of metal connecting pieces 6 连接 respectively connected to the microwave substrate 1, the first antenna unit 2 and the second antenna unit 3. The metal connecting pieces 6 can be divided into For the purpose of the application, the metal member 6 is connected to the microwave substrate 1 via the metal connecting pieces 60; the metal member 6 is electrically connected to the first through the metal connecting pieces 60. The antenna unit 2 and the second antenna unit 3 are electrically connected to the first end portion 2 2 2 and the second end portion 31, respectively, and the gold 6/15 M395272 The member 6 has the function of grounding. The antenna structure of the present invention can be arbitrarily set to a high-frequency radiator, and the size of the antenna structure can be 60*3*10 mm3, wherein the thickness of the microwave substrate 1 can be 0.4 mm, the first antenna unit 2. The second antenna unit 3, the third antenna unit 4, and the fourth antenna unit 5 may be thin metal bodies having a thickness of 〇1 mm. _ Please refer to the fifth to eighth figures, The second embodiment of the creation. The antenna structure for arbitrarily setting the high-frequency radiator includes: a microwave base plate 1, a first antenna unit 2, a second antenna unit 3, and a third antenna unit. 4. A fourth antenna unit 5 and a metal member 6. The microwave substrate 1, the first antenna unit 2, the second The arrangement of the wire unit 3, the fourth antenna unit 5 and the metal member 6 is the same as that of the first embodiment of the present invention. The third antenna unit 4 has a second metal region 40 disposed on the second surface 11 and a high-frequency radiator 4 ^ 1 disposed on the first surface 10. The high-frequency radiator 41 has a high-frequency extension 411 and a vertical extension from the end of the high-frequency extension 411 The high frequency end portion 41 2 extending in the direction of 411 is connected to the first metal region 2 1. The second metal region 40 corresponds to the first gold '. The second metal region 40 and the first metal region 2 1 form a corresponding region S having a capacitance characteristic, and the second metal region 40 is provided with a feeding point F, and the feeding point F can be coaxially connected. The transmission line (not shown) feeds in the signal. The second embodiment of the present invention differs from the first embodiment in that the high-frequency radiator 41 of the second embodiment is disposed on the first surface 10, and the high-frequency radiator 41 and the first metal region 2 1 connection. By arranging the high-frequency radiator 41 at different positions, the antenna structure design will have a larger 7/15 M395272 elastic adjustable antenna overall layout. Please refer to the 笫 _ _ Show 'According to the first article of the above-mentioned sword and the application of the P example, the antenna structure μ of the high axis (4) can be arbitrarily set to enter the 仃 (10), and the wealth can be created at different frequencies _ζ According to the experimental results of the ninth figure, the antenna structure of the high-frequency zero-reading body can be arbitrarily set to have a plurality of resonance modes and form two groups of stations = noisy at 3 (m). Between the operable frequency bands, this return loss curve proves that the sword is covered by multiple (four) moving _ the day of the job.
第·^天線單元4之該高頻輻射體4]之金屬微帶帶宽以增 進1¾頻段的阻抗匹配 本創作之,,j任意設置高頻輻射體之天線結構M因立且 有宽廣的频段涵蓋範圍,使本創作更可應用於 丨Evolut丨on)通訊傳輸協定,其各天線單元之金屬微帶帶 览,可針對不同的操作頻段進行細微調整,並可增進各 段的阻抗匹配,達成可任意設置高頻輻射體之天線結構M 功能最佳化之成效。The metal microstrip bandwidth of the high-frequency radiator 4] of the antenna unit 4 is used to enhance the impedance matching of the 13⁄4 band, and the antenna structure M of the high-frequency radiator is arbitrarily set and has a wide range. The coverage of the frequency band makes the creation more applicable to the Evolut丨on communication transmission protocol. The metal microstrip of each antenna unit can be finely adjusted for different operating frequency bands, and the impedance matching of each segment can be improved. The effect of optimizing the function of the antenna structure M of the high-frequency radiator can be achieved.
4翏考下表,下表顯示本創作之多頻迴圈天線結構M 之天/泉特性,其中本創作之Gajn值與效率均可達到產品之修 規格。 - 頻 率 (MHz) 704 710 716 734 740 746 751 756 777 782 787 -5.177 -4.266 -4.209 -3.190 -3.121 -2.934 -2.960 -3.009 -3.265 -3.013 -3.157 30.36 37.45 39.55 47.97 ----—-—_ 48.74 50.89 50.58 50.01 47.15 49.97 48.34 8/15 M395272 頻 率 (MHz) 824 836 849 869 880 894 900 915 925 940 960 Gain(dB) -3.040 -3.292 -3.707 -3.749 -3.578 -3.962 3.810 -3.831 -3.767 -4.288 -5.658 效率(%) 49.66 46.86 42.59 42.18 43.87 40.16 41.59 41.39 42.00 37.26 27.18 & 頻 率 (MHz) 1710 1750 1785 1805 1840 1850 1880 1910 1920 1930 1950 Gain(dB) -3.224 -3.336 -3.764 -3.289 -3.172 -3.368 -3.467 -3.584 -3.868 -4.095 -4.575 - 效率(%) 47.60 46.39 42.03 46.89 48.17 46.05 45.01 43.81 41.04 38.95 34.87 • 頻 率 I960 1980 1990 2110 2140 2170 2300 2350 2400 2500 2535 (MHz) Gain(dB) -4.331 -4.171 -3.565 -4.629 -5.006 -4.994 -2.161 -2.839 -2.086 -2.402 -2.310 效率(%) 36.89 38.27 44.00 34.44 31.58 31.67 60.80 52.0! 61.86 57.52 58.75 頻 率 2570 2620 2655 2690 (MHz) Gain(dB) -1.740 -2.416 -2.450 -2.401 * 效率(%) 66.99 57.33 56.89 57.53 综上所述,本創作之可任意設置高頻輻射體之天線結 構藉由串聯電容之設計,可將高頻輻射體設置於微波基板 之正反面各處’提升天線結構設計的彈性運用。本創作之 天線共振模態可在704〜960 MHz及1710〜2690 MHz頻帶附 近’並利用各天線單元間的間距調整,以控制各天線單元 9/15 I⑽W粞合能量’進而調盤天線之共振頻率,滿足各種 無線通訊標準之操作頻段。 fii以上所述僅為本創作之較佳可行實施例,非因此即 佝限本創作之專利範圍,故舉凡運用本創作說明書及圖式 内乾所為之等效結構變化,均同理皆包含於本創作之範圍 内,合予陳明。 【圆式簡單說明】 ,:λ,阎為本創作可任意設置高頻輻射體之天線結構第 一實施例微波基板第一表面示意圓。 笫二圖為本創作可任意設置高頻輻射體之天線結構第 一赏施例微波基板第二表面示意圖。 第三圖為本創作可任意設置高頻輻射體之天線結構第 一實施例立體分解示意圖。 第四圖為本創作可任意設置高頻輻射體之天線結構第 一實施例立體組合示意圖。 第五圓為本創作可任意設置高頻輻射體之天線結構 二賁施例微波基板第—表面示意圖。 、第六圖為本創作可任意設置高頻輻射體之天線結構第 一實施例微波基板第二表面示意圖。 第七圖為本創作可任意設置高頻輻射體之天線結構第 一實施例立體分解示意圖。 第八圖為本創作可任意設置高頻輻射體之天線結構第 一貫施例立體組合示意圖。 —第九圖為本創作可任意設置高頻輻射體之天線結構第 一霄她例及第二實施例在不同頻率(GHz)下所得到之駐波 10/15 M395272 圖(VSWR)之實驗曲線圖。 【主要元件符號說明】 Μ 可任意設置高頻輻射體之天線結構 1 微波基板 10 第一表面 11 第二表面 2 第一天線單元4 Refer to the table below. The table below shows the characteristics of the multi-frequency loop antenna structure M of this creation. The Gajn value and efficiency of this creation can reach the repair specifications of the product. - Frequency (MHz) 704 710 716 734 740 746 751 756 777 782 787 -5.177 -4.266 -4.209 -3.190 -3.121 -2.934 -2.960 -3.009 -3.265 -3.013 -3.157 30.36 37.45 39.55 47.97 ------__ 48.74 50.89 50.58 50.01 47.15 49.97 48.34 8/15 M395272 Frequency (MHz) 824 836 849 869 880 894 900 915 925 940 960 Gain (dB) -3.040 -3.292 -3.707 -3.749 -3.578 -3.962 3.810 -3.831 -3.767 -4.288 - 5.658 Efficiency (%) 49.66 46.86 42.59 42.18 43.87 40.16 41.59 41.39 42.00 37.26 27.18 & Frequency (MHz) 1710 1750 1785 1805 1840 1850 1880 1910 1920 1930 1950 Gain (dB) -3.224 -3.336 -3.764 -3.289 -3.172 -3.368 - 3.467 -3.584 -3.868 -4.095 -4.575 - Efficiency (%) 47.60 46.39 42.03 46.89 48.17 46.05 45.01 43.81 41.04 38.95 34.87 • Frequency I960 1980 1990 2110 2140 2170 2300 2350 2400 2500 2535 (MHz) Gain(dB) -4.331 -4.171 - 3.565 -4.629 -5.006 -4.994 -2.161 -2.839 -2.086 -2.402 -2.310 Efficiency (%) 36.89 38.27 44.00 34.44 31.58 31.67 60.80 52.0! 61.86 57.52 58.75 Frequency 2570 2620 2655 2690 (MHz) Gain(dB) -1.740 -2.416 -2.450 -2.401 * Efficiency (%) 66.99 57.33 56.89 57.53 In summary, the antenna structure of the high-frequency radiator can be arbitrarily set by the design of the series capacitor. The high-frequency radiator is disposed on the front and back sides of the microwave substrate to enhance the elastic design of the antenna structure design. The antenna resonance mode of this creation can be in the vicinity of the 704~960 MHz and 1710~2690 MHz bands' and the spacing between the antenna elements is adjusted to control the resonance energy of each antenna unit 9/15 I(10)W and the resonance of the tuning antenna Frequency, which satisfies the operating frequency bands of various wireless communication standards. The above description of fii is only a preferred and feasible embodiment of this creation, and therefore it is not limited to the scope of patents of this creation. Therefore, the equivalent structural changes made by using this creation specification and the internal structure of the drawings are all included in the same reason. Within the scope of this creation, it is given to Chen Ming. [Circular Simple Description], : λ, 阎 is an antenna structure in which a high-frequency radiator can be arbitrarily set. In the first embodiment, the first surface of the microwave substrate is schematically round. The second figure is a schematic diagram of the second surface of the microwave substrate in the first embodiment of the antenna structure in which the high-frequency radiator can be arbitrarily set. The third figure is a perspective exploded view of the first embodiment of the antenna structure in which the high-frequency radiator can be arbitrarily set. The fourth figure is a three-dimensional combination diagram of the first embodiment of the antenna structure in which the high-frequency radiator can be arbitrarily set. The fifth circle is an antenna structure in which the high-frequency radiator can be arbitrarily set. The first-surface schematic of the microwave substrate is applied. The sixth figure is a schematic diagram of the second surface of the microwave substrate according to the first embodiment of the antenna structure in which the high-frequency radiator can be arbitrarily set. The seventh figure is a perspective exploded view of the first embodiment of the antenna structure in which the high-frequency radiator can be arbitrarily set. The eighth figure is a three-dimensional combination diagram of the first embodiment of the antenna structure in which the high-frequency radiator can be arbitrarily set. - The ninth figure is the antenna structure of the arbitrarily set high-frequency radiator of the creation. The first experimental example of the standing wave 10/15 M395272 (VSWR) obtained by the example and the second embodiment at different frequencies (GHz) Figure. [Description of main component symbols] 天线 Antenna structure of high-frequency radiator can be arbitrarily set 1 Microwave substrate 10 First surface 11 Second surface 2 First antenna unit
2 0 第一線路部 2 0 1 第一區段 2 0 2 第二區段 2 0 3 第三區段 2 0 4 第四區段 2 0 5 第五區段 2 0 6 第六區段 2 0 7 第七區段 2 1 第一金屬區 2 2 第二線路部 2 2 1 第一延伸部 2 2 2 第一末端部 3 第二天線單元 30 第二延伸部 31 第二末端部 4 第三天線單元 40 第二金屬區 41 高頻輻射體 11/15 M395272 411 高頻延伸部 412 高頻末端部 5 笫四天線f元 5 0 笫四延伸部 6 金屬件 6 0金屬連接片 F 饋入點 S 對應區域 12/152 0 First line part 2 0 1 First section 2 0 2 Second section 2 0 3 Third section 2 0 4 Fourth section 2 0 5 Fifth section 2 0 6 Sixth section 2 0 7 seventh section 2 1 first metal zone 2 2 second line section 2 2 1 first extension 2 2 2 first end section 3 second antenna unit 30 second extension section 31 second end section 4 third Antenna unit 40 Second metal region 41 High-frequency radiator 11/15 M395272 411 High-frequency extension 412 High-frequency end portion 5 笫 Four-antenna f-element 5 0 笫 Four extensions 6 Metal parts 6 0 Metal connection piece F Feed-in point S corresponding area 12/15