TWI600209B - Antenna reset circuit - Google Patents
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Description
本發明屬於通訊天線技術,特別是一種用於手持式裝置並能夠重置天線場型之天線重置電路。 The present invention pertains to communication antenna technology, and more particularly to an antenna reset circuit for a handheld device that is capable of resetting an antenna pattern.
當今隨著微波頻段已被許多應用領域佔滿而不敷使用,促使各界皆競相投入毫米波(Millimeter Wave,mm-Wave)頻段的相關系統研發,由於毫米波在傳播時,其繞射衰減遠比微波更為嚴重,因此用於傳輸毫米波的天線需具有高增益的特性,並且為了能使該天線所產生之場型能達到全面性涵蓋,習知的方式係採用具有複數天線的天線系統,藉由選擇性開啟不同數量的天線來達到場型的改變的功效。 Nowadays, as the microwave frequency band has been used up by many application fields, it has prompted all circles to compete in the development of related systems in the millimeter wave (mm-wave) band. Because the millimeter wave is transmitting, its diffraction attenuation is far. It is more serious than microwave, so the antenna for transmitting millimeter waves needs to have high gain characteristics, and in order to enable the field pattern generated by the antenna to be comprehensively covered, the conventional method adopts an antenna system with a plurality of antennas. The effect of changing the field pattern is achieved by selectively turning on a different number of antennas.
然而,在開啟不同數量的天線時,該天線系統的輸入阻抗會發生變化,因此,為了能在不同數量的天線被開啟情況下皆達到阻抗匹配,習知的方式係在天線系統中設置多種多組的阻抗匹配電路,並透過切換裝置來選取適合的阻抗匹配電路,如此一來,該天線系統除了須設置多個的阻抗匹配電路外,還需要設計額外的控制電路來搭配各組合適的阻抗匹配電路,使得習知的天線系統整體架構尺寸過大且電路複雜。再者,習知的阻抗匹配電路係使用集總元件來實現, 但適用於毫米波的集總元件的成本高、誤差大且不穩定,當進行大量生產時會使得該阻抗匹配電路的生產良率降低。 However, when a different number of antennas are turned on, the input impedance of the antenna system changes. Therefore, in order to achieve impedance matching when a different number of antennas are turned on, the conventional method is various in the antenna system. The impedance matching circuit of the group selects a suitable impedance matching circuit through the switching device. In addition, in addition to the multiple impedance matching circuits, the antenna system needs to design an additional control circuit to match the appropriate impedance of each group. The matching circuit makes the overall structure of the conventional antenna system too large and the circuit is complicated. Furthermore, conventional impedance matching circuits are implemented using lumped elements, However, the lumped element suitable for the millimeter wave has high cost, large error, and instability, and the production yield of the impedance matching circuit is lowered when mass production is performed.
微帶線是位於接地層上由電介質隔開的印製導線,它是一根帶狀導線(信號線).與地平面之間用一種電介質隔離開。印製導線的厚度、寬度、印製導線與地層的距離以及電介質的介電常數決定了微帶線的特性阻抗。如果線的厚度、寬度以及與地平面之間的距離是可控制的,則它的特性阻抗也是可以控制的。單位長度微帶線的傳輸延遲時間,僅僅取決於介電常數而與線的寬度或間隔無關。微帶線的主要作用有二:一是把高頻信號能進行較有效地傳輸;二是與其他固體器件如電感、電容等構成一個匹配網路,使信號輸出端與負載很好地匹配。微帶線的優點包括:體積小、重量輕、使用頻帶寬、可靠性高和製造成本低等。微帶線和類微帶線一般用薄膜工藝製造。介質基片選用介電常數高、微波損耗低的材料,如氧化鋁陶瓷、石榴石鐵氧體和石英等。導體應具有導電率高、穩定性好、與基片的粘附性強等特點。 The microstrip line is a printed conductor separated by a dielectric on the ground plane, which is a strip conductor (signal line). Is isolated from the ground plane by a dielectric. The thickness and width of the printed conductor, the distance between the conductor and the formation, and the dielectric constant of the dielectric determine the characteristic impedance of the microstrip line. If the thickness, width, and distance from the ground plane are controllable, its characteristic impedance is also controllable. The propagation delay time per unit length of the microstrip line depends only on the dielectric constant and is independent of the width or spacing of the lines. The main functions of the microstrip line are two: one is to transmit the high-frequency signal more efficiently; the other is to form a matching network with other solid devices such as inductors and capacitors, so that the signal output end is well matched with the load. Advantages of the microstrip line include: small size, light weight, frequency bandwidth, high reliability, and low manufacturing cost. Microstrip lines and microstrip-like lines are typically fabricated using a thin film process. The dielectric substrate is made of a material having a high dielectric constant and low microwave loss, such as alumina ceramics, garnet ferrite, and quartz. The conductor should have the characteristics of high conductivity, good stability, and strong adhesion to the substrate.
為改善先前技術之缺點,本發明提出一種天線重置電路,該天線重置電路係設置於具有複數天線的一多天線系統中,以切換該等天線所產生的整體輻射場型,該天線重置電路係包含一饋入部、複數功率分配鏈路及複數開關單元。該饋入部係用以饋入一電訊號;該等功率分配鏈路係分 別對應地耦接於該等天線與該饋入部之間,用以在各該天線與該饋入部之間形成該電訊號的傳輸路徑;及該等開關單元,係分別對應地設置於各該功率分配鏈路,用以選擇地切斷或導通各該天線與該饋入部之間的電訊號路徑。藉此,透過該等開關單元的設計,能容易地調整該等天線的整體場型以增進訊號接收品質。 In order to improve the disadvantages of the prior art, the present invention provides an antenna reset circuit which is disposed in a multi-antenna system having a plurality of antennas for switching the overall radiation pattern generated by the antennas. The circuit includes a feed portion, a complex power distribution link, and a plurality of switch units. The feeding portion is configured to feed a telecommunication signal; the power distribution link is divided into Optionally, the antenna is coupled between the antenna and the feeding portion to form a transmission path of the electrical signal between each of the antennas and the feeding portion; and the switching units are respectively disposed correspondingly to the antennas And a power distribution link for selectively cutting or turning on the electrical signal path between each of the antennas and the feeding portion. Thereby, the overall field pattern of the antennas can be easily adjusted through the design of the switching units to improve signal reception quality.
本發明之另一目的在於提供一種能夠同時匹配單個或是多個天線之天線重置電路,並提供一種具有穩定特性並具有高生產良率之天線重置電路。本發明係可應用於毫米波頻段之天線設備裝置,本發明之一實施例中,頻寬包含36~40GHz頻帶,然並不局限於毫米波頻段與前述頻帶才能使用,熟知本發明相關技術者均可以本發明揭示之內容變化適用於不同頻段之天線通訊用途, 本發明之一實施例中,該天線重置電路與該多天線系統均可設置於印刷式電路上來實現,除了能夠排除習知採用集總元件設計之缺陷,也能確保該天線重置電路之響應的穩定性及提高該天線重置電路的生產良率。 Another object of the present invention is to provide an antenna reset circuit capable of simultaneously matching single or multiple antennas, and to provide an antenna reset circuit having stable characteristics and high production yield. The present invention is applicable to an antenna device device of a millimeter wave band. In an embodiment of the present invention, the bandwidth includes a frequency band of 36 to 40 GHz, but is not limited to the millimeter wave band and the foregoing frequency band, and is well known to those skilled in the art. The content changes disclosed in the present invention can be applied to antenna communication purposes in different frequency bands. In an embodiment of the present invention, the antenna reset circuit and the multi-antenna system can be implemented on a printed circuit, and the antenna reset circuit can be ensured except that the deficiencies of the lumped component design can be eliminated. The stability of the response and the production yield of the antenna reset circuit are improved.
本發明之一實施例中,各該開關單元係分別對應地設置自該功率分配鏈路與該饋入部之耦接位置起,並符合該天線之共振頻率之二分之一波長的位置處。透過切換各該開關單元達到多種場型的切換,能使場型有指向性、全向性和對向性的變換,選取適當天線場型與指向,來提升行動裝 置之通訊品質。 In an embodiment of the present invention, each of the switch units is correspondingly disposed from a coupling position of the power distribution link and the feed portion, and conforms to a position of one-half wavelength of a resonance frequency of the antenna. By switching the switching units to achieve switching of various field types, the field type can be transformed with directivity, omnidirectionality and orientation, and the appropriate antenna field type and pointing can be selected to enhance the mobile device. Set the communication quality.
本發明之一實施例中,各該開關單元係為微機電系統(Micro Electro Mechanical Systems,MEMS)開關或是射頻二極體。 In an embodiment of the invention, each of the switching units is a Micro Electro Mechanical Systems (MEMS) switch or a radio frequency diode.
本發明之一實施例中,該饋入部不與該些功率分配鏈路連接之一端係連接至一匹配單元,該匹配單元係為一微帶線。 In an embodiment of the invention, the feeding portion is not connected to one of the power distribution link ends to a matching unit, and the matching unit is a microstrip line.
本發明之一實施例中,該多天線系統係具有四組天線,該等功率分配鏈路的數量係為四個,該等功率分配鏈路係設置於同一平面,並以該饋入部為中心向外延伸,且相鄰之功率分配鏈路的延伸方向係彼此垂直。 In an embodiment of the present invention, the multi-antenna system has four sets of antennas, and the number of the power distribution links is four, and the power distribution links are disposed on the same plane, and are centered on the feed portion. Extending outwardly, and extending directions of adjacent power distribution links are perpendicular to each other.
本發明之一實施例中,各該開關單元係與一偏壓輸入線相耦接,透過該偏壓輸入線選擇地輸入一偏壓來開啟或關閉該開關單元。 In an embodiment of the invention, each of the switch units is coupled to a bias input line, and a bias is selectively input through the bias input line to turn the switch unit on or off.
本發明之一實施例中,各該功率分配鏈路上係分別設置有一接地線,且該接地線之電氣長度係為該天線之共振頻率之四分之一波長的n倍,其中n係為正整數。 In an embodiment of the present invention, each of the power distribution links is respectively provided with a grounding wire, and the electrical length of the grounding wire is n times of a quarter wavelength of the resonant frequency of the antenna, wherein the n system is positive Integer.
本發明之一實施例中,該等功率分配鏈路係以微帶線實現。 In one embodiment of the invention, the power distribution links are implemented in microstrip lines.
本發明之一實施例中,該饋入部與該功率分配鏈路間係以階梯式微帶線相連接。 In an embodiment of the invention, the feed portion and the power distribution link are connected by a stepped microstrip line.
本發明之天線重置電路係透過一組饋入部搭配 多組功率分配鏈路、及於各該功率分配鏈路上分別設置有該開關單元的設計,使該天線重置電路不但能匹配單個天線,亦可用於同時匹配多個天線,能大幅縮減該天線重置電路所需要的架構尺寸,使用者更能容易地調整該等天線的整體場型以增進訊號接收品質;再者,該天線重置電路係以印刷式電路取代集總元件的方式來實現,縱使在量產時印刷式電路的線寬或線長有稍許誤差,亦能夠保持該天線重置電路的響應特性,更可確保該天線重置電路之響應的穩定性及提高該天線重置電路的生產良率。 The antenna reset circuit of the present invention is matched with a set of feeding parts The plurality of sets of power distribution links and the design of the switch unit are respectively disposed on each of the power distribution links, so that the antenna reset circuit can not only match a single antenna, but also can simultaneously match multiple antennas, and can greatly reduce the antenna. By resetting the required size of the circuit, the user can easily adjust the overall field type of the antenna to improve signal reception quality. Moreover, the antenna reset circuit is implemented by replacing the lumped component with a printed circuit. Even if there is a slight error in the line width or line length of the printed circuit during mass production, the response characteristics of the antenna reset circuit can be maintained, and the stability of the response of the antenna reset circuit can be ensured and the antenna reset can be improved. The production yield of the circuit.
以上之概述與接下來的詳細說明及附圖,皆是為了能進一步說明本發明達到預定目的所採取的方式、手段及功效。而有關本發明的其他目的及優點,將在後續的說明及圖示中加以闡述。 The above summary, the following detailed description and the accompanying drawings are intended to further illustrate the manner, the Other objects and advantages of the present invention will be described in the following description and drawings.
1、1’、1”‧‧‧多天線系統 1, 1', 1" ‧ ‧ multi-antenna system
10、10’、10”‧‧‧天線重置電路 10, 10', 10" ‧ ‧ antenna reset circuit
110‧‧‧饋入部 110‧‧‧Feeding Department
121、122、123、124‧‧‧功率分配鏈路 121, 122, 123, 124‧‧‧ power distribution links
121’、122’、123’、124’‧‧‧功率分配鏈路 121', 122', 123', 124'‧‧‧ power distribution links
121”、122”、123”、124”‧‧‧功率分配鏈路 121", 122", 123", 124"‧‧‧ power distribution links
131、132、133、134‧‧‧開關單元 131, 132, 133, 134‧‧‧ switch units
141、142、142、144‧‧‧偏壓輸入線 141, 142, 142, 144‧‧‧ bias input lines
151、152、153、154‧‧‧接地線 151, 152, 153, 154‧‧‧ grounding wire
21、22、23、24‧‧‧天線 21, 22, 23, 24‧‧‧ antenna
30‧‧‧連通部 30‧‧‧Connecting Department
301‧‧‧連通柱 301‧‧‧Connected column
302‧‧‧匹配單元 302‧‧‧Matching unit
圖1係為本發明之天線重置電路第一實施例各視角示意圖。 1 is a schematic view of various angles of a first embodiment of an antenna reset circuit of the present invention.
圖2係為本發明天線重置電路之第二實施例各視角示意圖。 2 is a perspective view of a second embodiment of the antenna reset circuit of the present invention.
圖3係為本發明天線重置電路之第三實施例各視角示意圖。 FIG. 3 is a schematic view showing the perspective of a third embodiment of the antenna reset circuit of the present invention.
圖4係為本發明之第一、第二與第三實施例之反射係數頻率響應圖。 Figure 4 is a graph showing the frequency response of reflection coefficients of the first, second and third embodiments of the present invention.
圖5係為本發明之第一、第二與第三實施例之多種場型切換輻射場型量測圖。 Figure 5 is a cross-sectional view of a plurality of field-type switching radiation patterns of the first, second and third embodiments of the present invention.
以下係藉由特定的具體實例說明本發明之實施方式,熟悉此技藝之人士可由本說明書所揭示之內容輕易地瞭解本發明之其他優點與功效。 The embodiments of the present invention are described below by way of specific examples, and those skilled in the art can readily appreciate other advantages and functions of the present invention from the disclosure herein.
現有技術中,因毫米波空間傳輸衰減極大,故天線必須使用高增益指向天線場型,且為了達到全面性涵蓋,傳統技術為採用多天線系統,透過選擇性開啟不同數量的天線,來達到高增益指向場型的改變。為了不同天線開啟下皆達到匹配,需要不同的匹配電路,所以多天線切換架構設有與天線數量相同之多組阻抗匹配電路,再透過額外的切換裝置來選取適合的阻抗匹配架構,因此裝置體積過大、電路結構複雜、元件數量多,不利於設計與控制運作。且現有技術之匹配電路多用集總元件實現,其成本與操作不穩定性將會提高,集總元件本身也會有誤差,當進行大量生產時會降低良率。為改善習知技術之缺點,本發明提出一種天線重置電路,僅需使用一組可重置電路達到同時控制並可選擇複數組天線傳輸信號,能同時匹配所有情形,且在所有的操作模式下皆有寬頻響應。本發明之天線重置電路係以傳輸線(微帶線)來實現,搭配印刷式電路結構,可大幅降低生產成本,並具有高操作穩定性與高品質的訊號強度。 In the prior art, since the millimeter wave spatial transmission attenuation is extremely large, the antenna must use a high gain pointing antenna field type, and in order to achieve comprehensive coverage, the conventional technology adopts a multi-antenna system to achieve high by selectively opening different numbers of antennas. The gain points to a change in the field pattern. In order to achieve matching for different antennas, different matching circuits are required, so the multi-antenna switching architecture has multiple sets of impedance matching circuits with the same number of antennas, and then selects an appropriate impedance matching structure through an additional switching device, so the device volume Too large, complicated circuit structure, and a large number of components are not conducive to design and control operations. Moreover, the matching circuit of the prior art is mostly realized by the lumped component, the cost and the operational instability will be improved, and the lumped component itself will have an error, which will reduce the yield when mass production is performed. In order to improve the shortcomings of the prior art, the present invention proposes an antenna reset circuit that only needs to use a set of resettable circuits to simultaneously control and select a complex array antenna to transmit signals, which can match all situations simultaneously, and in all modes of operation. There are broadband responses below. The antenna reset circuit of the present invention is realized by a transmission line (microstrip line), and is matched with a printed circuit structure, which can greatly reduce the production cost, and has high operational stability and high quality signal strength.
請參閱圖1,係為本發明之天線重置電路第一實施例各視角示意圖。本實施例中,該天線重置電路10係設置 於一具雙層式立體結構的多天線系統1中,圖1(a)係為該多天線系統1之第一層基板上視圖,圖1(b)係為該多天線系統1之第一層基板下視圖,圖1(c)係為該多天線系統1之第二層基板示意圖,而圖1(d)係為該多天線系統1之第一層基板與第二層基板的組合示意圖,其中該等基板係為印刷電路板。 Please refer to FIG. 1 , which is a perspective view of the first embodiment of the antenna reset circuit of the present invention. In this embodiment, the antenna reset circuit 10 is configured. In a multi-antenna system 1 having a two-layer three-dimensional structure, FIG. 1(a) is a top view of the first layer substrate of the multi-antenna system 1, and FIG. 1(b) is the first of the multi-antenna system 1. FIG. 1(c) is a schematic diagram of a second layer substrate of the multi-antenna system 1, and FIG. 1(d) is a schematic diagram of a combination of a first layer substrate and a second layer substrate of the multi-antenna system 1. Where the substrates are printed circuit boards.
該天線重置電路10係包含一饋入部110、四個功率分配鏈路121、122、123、124,及四個開關單元131、132、133、134。該天線重置電路10係可搭配四個指向性之天線21、22、23、24而成為一多天線系統1。其中,具有指向性的該等天線21、22、23、24的類型可依設計需要而選擇,於本實施例中,該等天線21、22及24係可採用準八木宇田天線(Quasi Yagi-Uda antenna),而該天線23係採用矩形貼片天線;再者,該等天線21、22、23、24的設置位置之選擇,係以能使整體天線的場型盡可能涵蓋設計需求所欲接收/發送訊號之方向而設置。於本實施例中,係以該多天線系統1能夠達到全方位的訊號涵蓋為目標,因此該等天線21、22、23、24係分別設置於上下左右(以該基板垂直於地平面而言)的四個方向。值得注意的是,本發明之天線的類型、數量及設置位置皆可依設計需求而有所調整,並不以實施例為限。 The antenna reset circuit 10 includes a feed portion 110, four power distribution links 121, 122, 123, and 124, and four switch units 131, 132, 133, and 134. The antenna reset circuit 10 can be combined with four directional antennas 21, 22, 23, 24 to form a multi-antenna system 1. The types of the antennas 21, 22, 23, and 24 having directivity may be selected according to design requirements. In this embodiment, the antennas 21, 22, and 24 may be quasi-Yakumu Uda antennas (Quasi Yagi- Uda antenna), and the antenna 23 adopts a rectangular patch antenna; further, the positions of the antennas 21, 22, 23, and 24 are selected such that the field pattern of the entire antenna can cover the design requirements as much as possible. Set to receive/send the direction of the signal. In this embodiment, the multi-antenna system 1 is capable of achieving omnidirectional signal coverage. Therefore, the antennas 21, 22, 23, and 24 are respectively disposed on the upper, lower, left, and right sides (in terms of the substrate perpendicular to the ground plane). ) in four directions. It should be noted that the type, the number, and the setting position of the antenna of the present invention may be adjusted according to design requirements, and are not limited to the embodiment.
該饋入部110係可用以饋入一電訊號(圖未示),以驅動該等天線21、22、23、24。本實施例中,該多天線系統1係採用雙層式立體結構,該饋入部110之一端係與該等功 率分配鏈路121、122、123、124相耦接,而另一端係與設置於第二層基板之一連通部30相耦接,請一併參考圖1(c),該連通部30可具有一連通柱301及一匹配單元302,該天線重置電路1係可透過該連通部30係來與該匹配單元302、或設置於不同平面之一外部電路(圖未示)相耦接並進行電訊號傳輸,故本發明之第一實施例可達到以一組匹配電路控制多組天線之功效。 The feed portion 110 can be used to feed a signal (not shown) to drive the antennas 21, 22, 23, 24. In this embodiment, the multi-antenna system 1 adopts a two-layer three-dimensional structure, and one end of the feeding portion 110 and the same function The rate distribution links 121, 122, 123, and 124 are coupled to each other, and the other end is coupled to a communication portion 30 disposed on the second layer substrate. Referring to FIG. 1(c) together, the communication portion 30 can be Having a connecting post 301 and a matching unit 302, the antenna reset circuit 1 can be coupled to the matching unit 302 or an external circuit (not shown) disposed on one of different planes through the connecting portion 30 and The electrical signal transmission is performed, so that the first embodiment of the present invention can achieve the effect of controlling multiple sets of antennas with a set of matching circuits.
該等功率分配鏈路121、122、123、124係可分別對應地耦接於該等天線21、22、23、24與該饋入部110之間,以在各該天線21、22、23、24與該饋入部110之間形成該電訊號的傳輸路徑。其中,該等功率分配鏈路121、122、123、124係可為實質上相同的微帶線所實現,即該等功率分配鏈路121、122、123、124的電氣長度及線寬等設計規格皆大致相同,藉由此設計方式,能使由該饋入部110所輸入的電訊號之功率能夠平均分配至該等功率分配鏈路121、122、123、124。 The power distribution links 121, 122, 123, and 124 are respectively coupled between the antennas 21, 22, 23, and 24 and the feed portion 110 to be in the antennas 21, 22, and 23, A transmission path of the electrical signal is formed between the 24 and the feeding portion 110. The power distribution links 121, 122, 123, and 124 can be implemented by substantially the same microstrip line, that is, the electrical length and line width of the power distribution links 121, 122, 123, and 124 are designed. The specifications are substantially the same, and by this design, the power of the electrical signals input by the feeding unit 110 can be evenly distributed to the power distribution links 121, 122, 123, and 124.
該等開關單元131、132、133、134係可分別對應地設置於各該功率分配鏈路121、122、123、124,使該等功率分配鏈路121、122、123、124上皆分別設置有一個該開關單元,該等開關單元131、132、133、134係用以選擇地切斷或導通各該天線21、22、23、24與該饋入部110之間的電訊號路徑。為了使部份之該等開關單元因選擇地關閉進而切斷對應之該等電訊號路徑,讓被切斷該電訊號路徑之功率分配鏈 路的輸入阻抗等效為開路,因此各該開關單元131、132、133、134的設置位置,需為自各該功率分配鏈路121、122、123、124與該饋入部110之耦接位置起算、並符合該等天線21、22、23、24之共振頻率之二分之一波長的位置處,此種設計方式,於理想狀況下在被切斷該電訊號路徑之功率分配鏈路不會有能量損耗,而能將該電訊號之能量完整的分配並饋入於導通之各該功率分配鏈路所耦接的天線,以本實施例而言,該等天線21、22、23、24的共振頻率為38GHz,因此該等開關單元131、132、133、134係需設置於距離該饋入部110大約3.95*10-3公尺的位置處。再者,該等開關單元131、132、133、134係分別與一偏壓輸入線141、142、142、144相耦接,該些偏壓輸入線係連接至外部一控制單元(圖未示),讓該控制單元來選擇地切換該等開關單元131、132、133、134之開啟或關閉狀態。其中,該等開關單元131、132、133、134係可為微機電系統(Micro Electro Mechanical Systems,MEMS)開關或是射頻二極體。 The switch units 131, 132, 133, and 134 are respectively disposed on the power distribution links 121, 122, 123, and 124, respectively, so that the power distribution links 121, 122, 123, and 124 are respectively set. There is a switch unit, and the switch units 131, 132, 133, and 134 are used to selectively cut or turn on the electrical signal path between the antennas 21, 22, 23, and 24 and the feed portion 110. In order for some of the switching units to be selectively turned off to cut off the corresponding electrical signal paths, the input impedance of the power distribution link that is cut off the electrical path is equivalent to an open circuit, so each of the switching units The setting positions of 131, 132, 133, and 134 are calculated from the coupling positions of the power distribution links 121, 122, 123, and 124 and the feeding portion 110, and conform to the antennas 21, 22, 23, and 24; At a position one-half of the wavelength of the resonant frequency, this design method does not have energy loss in the power distribution link that is cut off the electrical signal path under ideal conditions, and can complete the energy of the electrical signal. An antenna coupled to each of the power distribution links that is turned on, and in this embodiment, the resonant frequencies of the antennas 21, 22, 23, and 24 are 38 GHz, and thus the switching units 131 and 132 The 133 and 134 are disposed at a position of about 3.95*10 -3 meters from the feeding portion 110. Furthermore, the switching units 131, 132, 133, 134 are respectively coupled to a bias input line 141, 142, 142, 144, and the bias input lines are connected to an external control unit (not shown) And letting the control unit selectively switch the on or off states of the switch units 131, 132, 133, 134. The switch units 131, 132, 133, and 134 may be Micro Electro Mechanical Systems (MEMS) switches or radio frequency diodes.
此外,該等功率分配鏈路121、122、123、124上係分別設置有接地線151、152、153、154,該等接地線151、152、153、154係分別用於使該等功率分配鏈路121、122、123、124接地。其中,該等接地線151、152、153、154的設置位置並無限制,但本發明所屬技術領域中具有通常知識者可瞭解的是,為使控制偏壓輸入的控制單元(圖未示)不影響該多天線 系統1的射頻訊號,需透過將末端為短路的殘段(例如接地線)之電氣長度設計為四分之一波長,使得該殘端的輸入阻抗等效為開路、進而不影響該多天線系統1的射頻訊號之特性,亦即該等接地線151、152、153、154之電氣長度係可設計為該天線之共振頻率之四分之一波長的n倍,其中n係為正整數。以本實施例而言,該等天線21、22、23、24的共振頻率為38GHz,因此該等接地線151、152、153、154之電氣長度係可為1.96*10-3*n公尺。 In addition, the power distribution links 121, 122, 123, and 124 are respectively provided with grounding lines 151, 152, 153, and 154, and the grounding lines 151, 152, 153, and 154 are respectively used for the power distribution. The links 121, 122, 123, 124 are grounded. The location of the grounding lines 151, 152, 153, and 154 is not limited, but those skilled in the art can understand that the control unit for inputting the control bias (not shown) The RF signal of the multi-antenna system 1 is not affected, and the electrical length of the stub (such as the grounding wire) whose terminal is short-circuited is designed to be a quarter wavelength, so that the input impedance of the stray is equivalent to an open circuit, and thus does not affect The characteristics of the radio frequency signals of the multi-antenna system 1, that is, the electrical lengths of the ground lines 151, 152, 153, 154 can be designed to be n times the quarter-wavelength of the resonant frequency of the antenna, wherein n is A positive integer. In this embodiment, the resonant frequencies of the antennas 21, 22, 23, and 24 are 38 GHz, so the electrical lengths of the grounding wires 151, 152, 153, and 154 may be 1.96*10 -3 *n meters. .
本發明之第一實施例係為雙層式基板立體結構,惟本發明之天線重置電路亦可於單一基板上實施,以符合現今電子裝置微小輕量化之需求。 The first embodiment of the present invention is a two-layer substrate three-dimensional structure, but the antenna reset circuit of the present invention can also be implemented on a single substrate to meet the demand for the miniaturization of electronic devices.
請參閱圖2,係為本發明天線重置電路之第二實施例各視角示意圖,圖2(a)係為該第二實施例上視圖,圖2(b)係為該第二實施例下視圖。相較於第一實施例之該多天線系統1採用雙層式設計,第二實施例的多天線系統1’係採單層式設計。不同於第一實施例將匹配單元設於第二層基板上,為實現單層式的天線系統1’,該第二實施例的天線重置電路10’之功率分配鏈路121’、122’、123’、124’係採用階梯式微帶線設計來實現匹配之功效,於靠近該饋入部110的前段一部份係先具有較窄的線寬,而後連向功率分配鏈路121’、122’、123’、124’之部分具有稍寬的線寬。藉由此種設計方式,雖然該第二實施例並無額外連接至一匹配單元,在僅有該等天線21、22、 23、24中之其中一者被驅動開啟時(即該等開關單元131、132、133、134中僅有一者係為開啟狀態)會具有較高輸入阻抗,但該等天線21、22、23、24的響應頻寬仍在可接受的範圍。隨著該等天線21、22、23、24被開啟的數量增加後,該天線系統1’之整體的等效輸入阻抗會降低,則被設計為高阻抗的功率分配鏈路121’、122’、123’、124’將可補償所降低的輸入阻抗,使在不同數量的天線21、22、23、24被開啟時,其響應頻寬皆能符合設計需求。該第二實施例具有之饋入部110、開關單元(131、132、133、134)、偏壓輸入線(141、142、142、144)與接地線(151、152、153、154)之作用原理與功效均與第一實施例相同,故不再贅述。 2 is a top view of the second embodiment of the antenna reset circuit of the present invention, FIG. 2(a) is a top view of the second embodiment, and FIG. 2(b) is a second embodiment. view. The multi-antenna system 1 of the second embodiment adopts a two-layer design as compared with the first embodiment, and the multi-antenna system 1' of the second embodiment adopts a single-layer design. Different from the first embodiment, the matching unit is disposed on the second layer substrate. To realize the single layer antenna system 1', the power distribution link 121', 122' of the antenna reset circuit 10' of the second embodiment 123', 124' adopts a stepped microstrip line design to achieve the matching effect, and a portion of the front portion close to the feeding portion 110 has a narrow line width first, and then connects to the power distribution links 121', 122. Portions of ', 123', 124' have a slightly wider line width. With this design, although the second embodiment is not additionally connected to a matching unit, only the antennas 21, 22, When one of 23, 24 is driven to be turned on (ie, only one of the switching units 131, 132, 133, 134 is in an open state), it will have a higher input impedance, but the antennas 21, 22, 23 The response bandwidth of 24 is still within an acceptable range. As the number of enabled antennas 21, 22, 23, 24 is increased, the overall equivalent input impedance of the antenna system 1' is reduced, and is designed as a high impedance power distribution link 121', 122' 123', 124' will compensate for the reduced input impedance so that when different numbers of antennas 21, 22, 23, 24 are turned on, the response bandwidth can meet the design requirements. The second embodiment has the functions of the feed portion 110, the switching units (131, 132, 133, 134), the bias input lines (141, 142, 142, 144) and the ground lines (151, 152, 153, 154). The principles and effects are the same as those of the first embodiment, and therefore will not be described again.
請參閱圖3,係為本發明天線重置電路之第三實施例各視角示意圖,圖3(a)係為該第三實施例上視圖,圖3(b)係為該第三實施例下視圖。相似於第二實施例的多天線系統1’,第三實施例的多天線系統1”係亦採單層式設計,與第二實施例之差異在於該等功率分配鏈路121”、122”、123”、124”的布局方式有所不同。有別於第一實施例的天線重置電路10及第二實施例的天線重置電路10’均採用當該電訊號饋入後隨即一分為四的設計方式,本實施例之天線重置電路10”由三個T型分波器所組合而成,即其係將該電訊號饋入後先透過第一組的T型分波器來等分為二分,而後再透過另外二組的T型分波器將功率分為四份,進而成為四組功率分配鏈路121”、 122”、123”、124”,此種設計方式與第二實施例相同皆是單層式設計,但由於電路佈局的差異,第三實施例中具有額外的電路板空間來設置另一匹配單元(圖未示),亦或者選擇第二實施例之方式,在饋入部與該些功率分配鏈路121”、122”、123”、124”間採用階梯式微帶線設計來實現匹配之功效(如圖3(a)所示,饋入部至功率分配鏈路之微帶線線寬有所變化),因此第三實施例相較於第二實施例可具有更寬之響應頻寬,亦確保在不同數量的天線21、22、23、24被開啟時,其響應頻寬皆能符合設計需求。該第三實施例具有之饋入部110、開關單元(131、132、133、134)、偏壓輸入線(141、142、142、144)與接地線(151、152、153、154)之作用原理與功效均與第一實施例相同,故不再贅述。 3 is a perspective view of a third embodiment of the antenna reset circuit of the present invention, FIG. 3(a) is a top view of the third embodiment, and FIG. 3(b) is a third embodiment. view. Similar to the multi-antenna system 1' of the second embodiment, the multi-antenna system 1" of the third embodiment also adopts a single-layer design, which differs from the second embodiment in the power distribution links 121", 122" The layout of the 123", 124" is different. The antenna reset circuit 10 different from the first embodiment and the antenna reset circuit 10' of the second embodiment are both used when the electrical signal is fed. For the design of the fourth embodiment, the antenna reset circuit 10" of the present embodiment is composed of three T-type splitters, that is, the T-wave splitter of the first group is transmitted after the electrical signal is fed. Divided into two points, and then divided the power into four by the other two sets of T-type splitter, and then become four sets of power distribution links 121", 122", 123", 124", this design is the same as the second embodiment in a single layer design, but due to the difference in circuit layout, the third embodiment has additional board space to set another matching unit. (not shown), or alternatively, the manner of the second embodiment is adopted, and a stepped microstrip line design is adopted between the feeding portion and the power distribution links 121", 122", 123", 124" to achieve the matching effect ( As shown in FIG. 3(a), the line width of the microstrip line of the feed portion to the power distribution link varies, so that the third embodiment can have a wider response bandwidth than the second embodiment, and also ensures When different numbers of antennas 21, 22, 23, 24 are turned on, the response bandwidth can meet the design requirements. The third embodiment has the feeding portion 110, the switching unit (131, 132, 133, 134), and the partial The principle and function of the pressure input lines (141, 142, 142, 144) and the ground lines (151, 152, 153, 154) are the same as those of the first embodiment, and therefore will not be described again.
請參閱圖4,係分別為本發明之第一、第二與第三實施例之反射係數頻率響應圖。圖4(a)係為第一實施例、圖4(b)係為第二實施例、圖4(c)係為第三實施例。其中第一實施利之該多天線系統1因採用雙層式立體結構,使得在該等天線21、22、23、24開啟時皆能具有相當寬的頻寬之反射係數頻率響應;而第二實施例之該多天線系統1’係為單層式設計,藉由改變該等功率分配鏈路121’、122’、123’、124’的寬度來達到匹配,使該多天線系統1’於生產上更容易,但第二實施例之多天線系統1’的響應頻寬係窄於該多天線系統1的響應頻寬。第三實施例之該多天線系統1”亦為單層式設計,並由三個T型 分波器所組成功率分配鏈路121”、122”、123”、124”,該多天線系統1”的響應頻寬係介於該多天線系統1的響應頻寬和該多天線系統1’的響應頻寬之間。熟知本發明相關技術者可依實際需求,選擇上述三種實施例之構型來實施,均可達到本發明所具備之優點與功效。 Please refer to FIG. 4, which are reflection coefficient frequency response diagrams of the first, second and third embodiments of the present invention, respectively. 4(a) is a first embodiment, FIG. 4(b) is a second embodiment, and FIG. 4(c) is a third embodiment. In the first embodiment, the multi-antenna system 1 has a two-layer stereo structure, so that the antennas 21, 22, 23, and 24 can have a relatively wide bandwidth reflection coefficient frequency response when the antennas 21, 22, 23, and 24 are turned on; For example, the multi-antenna system 1' is a single-layer design, and the width of the power distribution links 121', 122', 123', 124' is changed to achieve matching, so that the multi-antenna system 1' is produced. This is easier, but the response bandwidth of the multi-antenna system 1' of the second embodiment is narrower than the response bandwidth of the multi-antenna system 1. The multi-antenna system 1" of the third embodiment is also a single-layer design and is composed of three T-types. The power splitting links 121", 122", 123", 124" formed by the splitter, the response bandwidth of the multi-antenna system 1" is between the response bandwidth of the multi-antenna system 1 and the multi-antenna system 1' Between the response bandwidths, those skilled in the art can implement the configurations of the above three embodiments according to actual needs, and all of the advantages and effects of the present invention can be achieved.
請參閱圖5,係分別為本發明之第一、第二與第三實施例之多種場型切換的輻射場型量測圖,圖5(a)為第一實施例之該多天線系統1、圖5(b)為第二實施例之該多天線系統1’、圖5(c)為第三實施例之該多天線系統1”之多種場型的切換的輻射場型量測圖。 Referring to FIG. 5, the radiation field type measurement diagrams of the plurality of field type switchings of the first, second, and third embodiments of the present invention, respectively, and FIG. 5(a) is the multi-antenna system 1 of the first embodiment. 5(b) is a multi-antenna system 1' of the second embodiment, and FIG. 5(c) is a radiation field type measurement diagram of switching of various field types of the multi-antenna system 1" of the third embodiment.
本發明之天線重置電路具有n條鏈路時,n條鏈路末端分別接上天線,再使用切換電路控制n條鏈路的導通情況,此架構使場型能達到(2n-1)種的變化,其中大致分為指向性、全向性和雙向性三類場型變化,再與高增益天線整合,即能達到同時具高增益以及波束切換的功能需求。於本發明之第一、第二、第三實施例中,該等多天線系統1、1’、1”係分別設置有本發明之天線重置電路10、10’、10”,透過該等開關單元131、132、133、134來使該等多天線系統1、1’、1”能達到多種場型切換的功效。透過該等開關單元131、132、133、134的切換,能使該等多天線系統1、1’、1”場型可在指向性、全向性和對向性之間進行切換,其場型如圖5(a)~(c)所示,藉此可以依照該等多天線系統1、1’、1”的使用環境進而選取適 當的天線場型與指向,來提升行動裝置之通訊品質。 When the antenna reset circuit of the present invention has n links, the ends of the n links are respectively connected to the antenna, and then the switching circuit is used to control the conduction of the n links, and the architecture enables the field type to reach (2 n -1). The changes are roughly divided into three types of directional, omnidirectional and bidirectional field-type changes, and then integrated with high-gain antennas, which can achieve the functions of high gain and beam switching. In the first, second, and third embodiments of the present invention, the multi-antenna systems 1, 1', 1" are respectively provided with the antenna reset circuits 10, 10', 10" of the present invention, through which the The switching units 131, 132, 133, 134 enable the multi-antenna systems 1, 1 ', 1" to achieve various field switching effects. By switching between the switching units 131, 132, 133, 134, The multi-antenna system 1, 1 ', 1" field type can switch between directivity, omnidirectionality and oppositeism, and its field pattern is shown in Figures 5(a) to (c), whereby The use environment of the multi-antenna systems 1, 1 ', 1" further selects an appropriate antenna field type and orientation to improve the communication quality of the mobile device.
綜上所述,本發明之天線重置電路係透過該等功率分配鏈路及於各該功率分配鏈路上分別設置有該開關單元的設計,使該天線重置電路不但能匹配單個天線,亦可用於同時匹配多個天線,能大幅縮減該天線重置電路所需要的結構尺寸,且更能容易地調整該等天線的整體場型以增進訊號接收品質;再者,該天線重置電路係以印刷式電路取代集總元件的方式來實現,縱使在量產時印刷式電路的線寬或線長有稍許誤差,亦能夠保持該天線重置電路的響應特性,更可確保該天線重置電路之響應的穩定性及提高該天線重置電路的生產良率。 In summary, the antenna reset circuit of the present invention is provided with the switching unit through the power distribution links and the power distribution links, so that the antenna reset circuit can not only match a single antenna, but also It can be used to match multiple antennas at the same time, which can greatly reduce the structure size required by the antenna reset circuit, and can more easily adjust the overall field type of the antennas to improve the signal receiving quality. Moreover, the antenna reset circuit system By replacing the lumped component with a printed circuit, even if there is a slight error in the line width or line length of the printed circuit during mass production, the response characteristics of the antenna reset circuit can be maintained, and the antenna reset can be ensured. The stability of the response of the circuit and the production yield of the antenna reset circuit.
上述之實施例僅為例示性說明本發明之特點及其功效,而非用於限制本發明之實質技術內容的範圍。任何熟習此技藝之人士均可在不違背本發明之精神及範疇下,對上述實施例進行修飾與變化。因此,本發明之權利保護範圍,應如後述之申請專利範圍所列。 The above-described embodiments are merely illustrative of the features and functions of the present invention, and are not intended to limit the scope of the technical scope of the present invention. Modifications and variations of the above-described embodiments can be made by those skilled in the art without departing from the spirit and scope of the invention. Therefore, the scope of protection of the present invention should be as set forth in the scope of the claims described below.
1‧‧‧多天線系統 1‧‧‧Multi-antenna system
10‧‧‧天線重置電路 10‧‧‧Antenna reset circuit
110‧‧‧饋入部 110‧‧‧Feeding Department
121、122、123、124‧‧‧功率分配鏈路 121, 122, 123, 124‧‧‧ power distribution links
131、132、133、134‧‧‧開關單元 131, 132, 133, 134‧‧‧ switch units
141、142、142、144‧‧‧偏壓輸入線 141, 142, 142, 144‧‧‧ bias input lines
151、152、153、154‧‧‧接地線 151, 152, 153, 154‧‧‧ grounding wire
21、22、23、24‧‧‧天線 21, 22, 23, 24‧‧‧ antenna
Claims (8)
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TW105106069A TWI600209B (en) | 2016-03-01 | 2016-03-01 | Antenna reset circuit |
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TW105106069A TWI600209B (en) | 2016-03-01 | 2016-03-01 | Antenna reset circuit |
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TW201733208A TW201733208A (en) | 2017-09-16 |
TWI600209B true TWI600209B (en) | 2017-09-21 |
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US10916860B2 (en) | 2018-12-19 | 2021-02-09 | National Chaio Tung University Quanta Computer Inc. | Compact high-gain pattern reconfigurable antenna |
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