TW201806234A - Antenna structure and wireless communication device using same - Google Patents
Antenna structure and wireless communication device using same Download PDFInfo
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- TW201806234A TW201806234A TW106123339A TW106123339A TW201806234A TW 201806234 A TW201806234 A TW 201806234A TW 106123339 A TW106123339 A TW 106123339A TW 106123339 A TW106123339 A TW 106123339A TW 201806234 A TW201806234 A TW 201806234A
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01Q—ANTENNAS, i.e. RADIO AERIALS
- H01Q1/00—Details of, or arrangements associated with, antennas
- H01Q1/36—Structural form of radiating elements, e.g. cone, spiral, umbrella; Particular materials used therewith
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01Q—ANTENNAS, i.e. RADIO AERIALS
- H01Q1/00—Details of, or arrangements associated with, antennas
- H01Q1/12—Supports; Mounting means
- H01Q1/22—Supports; Mounting means by structural association with other equipment or articles
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01Q—ANTENNAS, i.e. RADIO AERIALS
- H01Q1/00—Details of, or arrangements associated with, antennas
- H01Q1/12—Supports; Mounting means
- H01Q1/22—Supports; Mounting means by structural association with other equipment or articles
- H01Q1/24—Supports; Mounting means by structural association with other equipment or articles with receiving set
- H01Q1/241—Supports; Mounting means by structural association with other equipment or articles with receiving set used in mobile communications, e.g. GSM
- H01Q1/242—Supports; Mounting means by structural association with other equipment or articles with receiving set used in mobile communications, e.g. GSM specially adapted for hand-held use
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01Q—ANTENNAS, i.e. RADIO AERIALS
- H01Q1/00—Details of, or arrangements associated with, antennas
- H01Q1/12—Supports; Mounting means
- H01Q1/22—Supports; Mounting means by structural association with other equipment or articles
- H01Q1/24—Supports; Mounting means by structural association with other equipment or articles with receiving set
- H01Q1/241—Supports; Mounting means by structural association with other equipment or articles with receiving set used in mobile communications, e.g. GSM
- H01Q1/242—Supports; Mounting means by structural association with other equipment or articles with receiving set used in mobile communications, e.g. GSM specially adapted for hand-held use
- H01Q1/243—Supports; Mounting means by structural association with other equipment or articles with receiving set used in mobile communications, e.g. GSM specially adapted for hand-held use with built-in antennas
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01Q—ANTENNAS, i.e. RADIO AERIALS
- H01Q1/00—Details of, or arrangements associated with, antennas
- H01Q1/12—Supports; Mounting means
- H01Q1/22—Supports; Mounting means by structural association with other equipment or articles
- H01Q1/24—Supports; Mounting means by structural association with other equipment or articles with receiving set
- H01Q1/241—Supports; Mounting means by structural association with other equipment or articles with receiving set used in mobile communications, e.g. GSM
- H01Q1/242—Supports; Mounting means by structural association with other equipment or articles with receiving set used in mobile communications, e.g. GSM specially adapted for hand-held use
- H01Q1/243—Supports; Mounting means by structural association with other equipment or articles with receiving set used in mobile communications, e.g. GSM specially adapted for hand-held use with built-in antennas
- H01Q1/244—Supports; Mounting means by structural association with other equipment or articles with receiving set used in mobile communications, e.g. GSM specially adapted for hand-held use with built-in antennas extendable from a housing along a given path
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01Q—ANTENNAS, i.e. RADIO AERIALS
- H01Q1/00—Details of, or arrangements associated with, antennas
- H01Q1/44—Details of, or arrangements associated with, antennas using equipment having another main function to serve additionally as an antenna, e.g. means for giving an antenna an aesthetic aspect
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01Q—ANTENNAS, i.e. RADIO AERIALS
- H01Q1/00—Details of, or arrangements associated with, antennas
- H01Q1/48—Earthing means; Earth screens; Counterpoises
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01Q—ANTENNAS, i.e. RADIO AERIALS
- H01Q1/00—Details of, or arrangements associated with, antennas
- H01Q1/50—Structural association of antennas with earthing switches, lead-in devices or lightning protectors
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01Q—ANTENNAS, i.e. RADIO AERIALS
- H01Q5/00—Arrangements for simultaneous operation of antennas on two or more different wavebands, e.g. dual-band or multi-band arrangements
- H01Q5/20—Arrangements for simultaneous operation of antennas on two or more different wavebands, e.g. dual-band or multi-band arrangements characterised by the operating wavebands
- H01Q5/28—Arrangements for establishing polarisation or beam width over two or more different wavebands
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01Q—ANTENNAS, i.e. RADIO AERIALS
- H01Q5/00—Arrangements for simultaneous operation of antennas on two or more different wavebands, e.g. dual-band or multi-band arrangements
- H01Q5/30—Arrangements for providing operation on different wavebands
- H01Q5/307—Individual or coupled radiating elements, each element being fed in an unspecified way
- H01Q5/314—Individual or coupled radiating elements, each element being fed in an unspecified way using frequency dependent circuits or components, e.g. trap circuits or capacitors
- H01Q5/328—Individual or coupled radiating elements, each element being fed in an unspecified way using frequency dependent circuits or components, e.g. trap circuits or capacitors between a radiating element and ground
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04M—TELEPHONIC COMMUNICATION
- H04M1/00—Substation equipment, e.g. for use by subscribers
- H04M1/02—Constructional features of telephone sets
- H04M1/0202—Portable telephone sets, e.g. cordless phones, mobile phones or bar type handsets
- H04M1/026—Details of the structure or mounting of specific components
Landscapes
- Engineering & Computer Science (AREA)
- Computer Networks & Wireless Communication (AREA)
- Signal Processing (AREA)
- Variable-Direction Aerials And Aerial Arrays (AREA)
- Support Of Aerials (AREA)
- Waveguide Aerials (AREA)
Abstract
Description
本發明涉及一種天線結構及具有該天線結構的無線通訊裝置。The invention relates to an antenna structure and a wireless communication device having the antenna structure.
隨著無線通訊技術的進步,無線通訊裝置不斷朝向輕薄趨勢發展,消費者對於產品外觀的要求也越來越高。由於金屬殼體在外觀、機構強度、散熱效果等方面具有優勢,因此越來越多的廠商設計出具有金屬殼體,例如金屬背板的無線通訊裝置來滿足消費者的需求。但是,金屬殼體容易干擾遮蔽設置在其內的天線所輻射的訊號,不容易達到寬頻設計,導致內置天線的輻射性能不佳。再者,所述金屬背板上通常還設置有開槽及斷點,如此將影響金屬背板的完整性和美觀性。With the advancement of wireless communication technology, wireless communication devices continue to develop toward the trend of thinness and lightness, and consumers' requirements for the appearance of products are becoming higher and higher. Because metal casings have advantages in appearance, mechanical strength, and heat dissipation effects, more and more manufacturers have designed wireless communication devices with metal casings, such as metal backplanes, to meet consumer demand. However, the metal casing easily interferes with the signal radiated by the antenna that is shielded in it, and it is not easy to achieve a broadband design, resulting in poor radiation performance of the built-in antenna. Furthermore, the metal back plate is usually provided with slots and break points, which will affect the integrity and aesthetics of the metal back plate.
有鑑於此,有必要提供一種天線結構及具有該天線結構的無線通訊裝置。In view of this, it is necessary to provide an antenna structure and a wireless communication device having the antenna structure.
一種天線結構,包括金屬件、第一饋入部、第一接地部及第二接地部,所述金屬件包括金屬前框、金屬背板以及金屬邊框,所述金屬邊框夾設於所述金屬前框與所述金屬背板之間,所述金屬邊框至少包括底部、第一側部以及第二側部,所述第一側部與所述第二側部分別連接所述底部的兩端,所述金屬邊框上開設有開槽,所述開槽至少佈設於所述底部上,所述金屬前框上開設第一斷點及第二斷點,所述第一斷點及第二斷點分別位於所述開槽的兩個末端,所述第一斷點及第二斷點與所述開槽連通並延伸至隔斷所述金屬前框,位於第一斷點與第二斷點之間的金屬前框形成輻射段,所述天線結構還包括一延伸段,所述延伸段設置於所述金屬前框、金屬邊框以及金屬背板共同圍成的容置空間之內,所述延伸段連接至所述輻射段靠近第二斷點的一端,所述第一饋入部電連接至所述輻射段,且第一饋入部位於所述第一接地部與第二接地部之間,電流自所述第一饋入部饋入至所述輻射段並分別流向所述輻射段的兩端以分別激發第一頻段與第二頻段的輻射訊號,電流還沿輻射段流向延伸段以激發第三頻段的輻射訊號,所述第一頻段的頻率高於第二頻段的頻率,第三頻段的頻率高於第一頻段的頻率。An antenna structure includes a metal piece, a first feed-in portion, a first ground portion, and a second ground portion. The metal piece includes a metal front frame, a metal back plate, and a metal frame, and the metal frame is sandwiched in front of the metal. Between the frame and the metal back plate, the metal frame includes at least a bottom portion, a first side portion, and a second side portion, and the first side portion and the second side portion are respectively connected to both ends of the bottom portion, A slot is provided on the metal frame, the slot is arranged at least on the bottom, a first breakpoint and a second breakpoint are set on the metal front frame, and the first breakpoint and the second breakpoint Respectively located at two ends of the slot, the first break point and the second break point communicate with the slot and extend to cut off the metal front frame, located between the first break point and the second break point The metal front frame forms a radiating section, and the antenna structure further includes an extension section, and the extension section is disposed in an accommodating space surrounded by the metal front frame, the metal frame, and the metal back plate. The extension section Connected to an end of the radiating section near a second breakpoint, the first An input section is electrically connected to the radiation section, and a first feed section is located between the first ground section and a second ground section, and a current is fed from the first feed section to the radiation section and flows to the radiation, respectively. The two ends of the segment excite the radiation signals of the first and second frequency bands respectively, and the current also flows along the radiation segment to the extension segment to excite the radiation signals of the third frequency band. The frequency of the first frequency band is higher than that of the second frequency band. The frequency of the third frequency band is higher than that of the first frequency band.
一種無線通訊裝置,包括天線結構,天線結構包括金屬件、第一饋入部、第一接地部及第二接地部,所述金屬件包括金屬前框、金屬背板以及金屬邊框,所述金屬邊框夾設於所述金屬前框與所述金屬背板之間,所述金屬邊框至少包括底部、第一側部以及第二側部,所述第一側部與所述第二側部分別連接所述底部的兩端,所述金屬邊框上開設有開槽,所述開槽至少佈設於所述底部上,所述金屬前框上開設第一斷點及第二斷點,所述第一斷點及第二斷點分別位於所述開槽的兩個末端,所述第一斷點及第二斷點與所述開槽連通並延伸至隔斷所述金屬前框,位於第一斷點與第二斷點之間的金屬前框形成輻射段,所述天線結構還包括一延伸段,所述延伸段設置於所述金屬前框、金屬邊框以及金屬背板共同圍成的容置空間之內,所述延伸段連接至所述輻射段靠近第二斷點的一端,所述第一饋入部電連接至所述輻射段,且第一饋入部位於所述第一接地部與第二接地部之間,電流自所述第一饋入部饋入至所述輻射段並分別流向所述輻射段的兩端以分別激發第一頻段與第二頻段的輻射訊號,電流還沿輻射段流向延伸段以激發第三頻段的輻射訊號,所述第一頻段的頻率高於第二頻段的頻率,第三頻段的頻率高於第一頻段的頻率。A wireless communication device includes an antenna structure. The antenna structure includes a metal piece, a first feeding portion, a first ground portion, and a second ground portion. The metal piece includes a metal front frame, a metal back plate, and a metal frame. The metal frame Sandwiched between the metal front frame and the metal back plate, the metal frame includes at least a bottom portion, a first side portion, and a second side portion, and the first side portion and the second side portion are respectively connected A slot is provided on the metal frame at both ends of the bottom, and the slot is arranged at least on the bottom. A first breakpoint and a second breakpoint are set on the metal front frame. A breakpoint and a second breakpoint are respectively located at two ends of the slot, and the first breakpoint and the second breakpoint communicate with the slot and extend to cut off the metal front frame at the first breakpoint The metal front frame between the second break point and the second break point forms a radiating section, and the antenna structure further includes an extension section, and the extension section is disposed in an accommodation space surrounded by the metal front frame, the metal frame, and the metal back plate. Within, the extension is connected to the radiating section by At one end of the second breakpoint, the first feeding portion is electrically connected to the radiating section, and the first feeding portion is located between the first ground portion and the second ground portion, and a current is fed from the first feeding portion Into the radiating section and flowing to the two ends of the radiating section respectively to excite the radiation signals in the first and second frequency bands, and the current also flows along the radiating section to the extension section to excite the radiating signals in the third frequency band. The frequency of one frequency band is higher than the frequency of the second frequency band, and the frequency of the third frequency band is higher than the frequency of the first frequency band.
所述天線結構通過設置所述金屬件,且所述金屬件上的開槽及斷點均設置於所述金屬前框及金屬邊框上,並未設置於所述金屬背板上,使得所述金屬背板構成全金屬結構,即所述金屬背板上並沒有絕緣的開槽、斷線或斷點,使得所述金屬背板可避免由於開槽、斷線或斷點的設置而影響金屬背板的完整性和美觀性。The antenna structure is provided with the metal piece, and the slots and breakpoints on the metal piece are provided on the metal front frame and the metal frame, but not on the metal back plate, so that The metal backplane forms an all-metal structure, that is, the metal backplane has no insulating slots, breaks or breakpoints, so that the metal backplate can avoid affecting the metal due to the slotting, breakage or breakpoint settings The integrity and aesthetics of the backplane.
下面將結合本發明實施例中的附圖,對本發明實施例中的技術方案進行清楚、完整地描述,顯然,所描述的實施例僅僅是本發明一部分實施例,而不是全部的實施例。基於本發明中的實施例,本領域普通技術人員在沒有做出創造性勞動前提下所獲得的所有其他實施例,都屬於本發明保護的範圍。In the following, the technical solutions in the embodiments of the present invention will be clearly and completely described with reference to the drawings in the embodiments of the present invention. Obviously, the described embodiments are only a part of the embodiments of the present invention, but not all of the embodiments. Based on the embodiments of the present invention, all other embodiments obtained by a person of ordinary skill in the art without creative efforts shall fall within the protection scope of the present invention.
需要說明的是,當一個元件被稱為“電連接”另一個元件,它可以直接在另一個元件上或者也可以存在居中的元件。當一個元件被認為是“電連接”另一個元件,它可以是接觸連接,例如,可以是導線連接的方式,也可以是非接觸式連接,例如,可以是非接觸式耦合的方式。It should be noted that when one element is called "electrically connected" to another element, it may be directly on the other element or there may be a centered element. When an element is considered to be "electrically connected" to another element, it can be a contact connection, for example, a wire connection, or a non-contact connection, for example, a non-contact coupling.
除非另有定義,本文所使用的所有的技術和科學術語與屬於本發明的技術領域的技術人員通常理解的含義相同。本文中在本發明的說明書中所使用的術語只是為了描述具體的實施例的目的,不是旨在於限制本發明。本文所使用的術語“及/或”包括一個或多個相關的所列項目的任意的和所有的組合。Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein in the description of the present invention is for the purpose of describing specific embodiments only and is not intended to limit the present invention. The term "and / or" as used herein includes any and all combinations of one or more of the associated listed items.
下面結合附圖,對本發明的一些實施方式作詳細說明。在不衝突的情況下,下述的實施例及實施例中的特徵可以相互組合。Hereinafter, some embodiments of the present invention will be described in detail with reference to the drawings. In the case of no conflict, the following embodiments and features in the embodiments can be combined with each other.
實施例1Example 1
請參閱圖1,本發明第一較佳實施方式提供一種天線結構100,其可應用於行動電話、個人數位助理等無線通訊裝置200中,用以發射、接收無線電波以傳遞、交換無線訊號。Referring to FIG. 1, a first preferred embodiment of the present invention provides an antenna structure 100 that can be applied to wireless communication devices 200 such as mobile phones and personal digital assistants to transmit and receive radio waves to transmit and exchange wireless signals.
請一併參閱圖2及圖3,所述天線結構100包括金屬件11、第一饋入部12、第二饋入部13、第三饋入部14、第一輻射體15、第二輻射體16、第四饋入部17、第三輻射體18、第五饋入部19及第一切換電路20(參圖4)。Please refer to FIG. 2 and FIG. 3 together. The antenna structure 100 includes a metal member 11, a first feeding portion 12, a second feeding portion 13, a third feeding portion 14, a first radiator 15, a second radiator 16, The fourth feeding portion 17, the third radiator 18, the fifth feeding portion 19, and the first switching circuit 20 (see FIG. 4).
所述金屬件11可以為所述無線通訊裝置200的外殼。所述金屬件11包括金屬前框111、金屬背板112及金屬邊框113。所述金屬前框111、金屬背板112及金屬邊框113可以是一體成型的。所述金屬前框111、金屬背板112以及金屬邊框113構成所述無線通訊裝置200的外殼。所述金屬前框111上設置有一開口(圖未標),用於容置所述無線通訊裝置200的顯示單元201。可以理解,所述顯示單元201具有一顯示平面,該顯示平面裸露於該開口,且該顯示平面與所述金屬背板112大致平行設置。The metal part 11 may be a casing of the wireless communication device 200. The metal component 11 includes a metal front frame 111, a metal back plate 112, and a metal frame 113. The metal front frame 111, the metal back plate 112, and the metal frame 113 may be integrally formed. The metal front frame 111, the metal back plate 112, and the metal frame 113 constitute a casing of the wireless communication device 200. The metal front frame 111 is provided with an opening (not shown) for receiving the display unit 201 of the wireless communication device 200. It can be understood that the display unit 201 has a display plane, the display plane is exposed from the opening, and the display plane is substantially parallel to the metal back plate 112.
所述金屬背板112與所述金屬前框111相對設置。所述金屬背板112與金屬邊框113直接連接。所述金屬背板112與金屬邊框113之間沒有空隙。所述金屬背板112為一體成型的單一金屬片。所述金屬背板112為顯露後置雙鏡頭202與受話器203等元件而設置開孔204、205。所述金屬背板112其上並沒有設置任何用於分割所述金屬背板112的絕緣的開槽、斷線或斷點(請參圖2)。所述金屬背板112可作為所述天線結構100的地。The metal back plate 112 is opposite to the metal front frame 111. The metal back plate 112 is directly connected to the metal frame 113. There is no gap between the metal back plate 112 and the metal frame 113. The metal back plate 112 is a single metal sheet integrally formed. The metal back plate 112 is provided with openings 204 and 205 for exposing components such as the rear dual lens 202 and the receiver 203. The metal back plate 112 is not provided with any slot, break or break point for dividing the insulation of the metal back plate 112 (see FIG. 2). The metal back plate 112 can be used as a ground of the antenna structure 100.
所述金屬邊框113夾設於所述金屬前框111與所述金屬背板112之間,且分別環繞所述金屬前框111及所述金屬背板112的周緣設置,以與所述顯示單元201、所述金屬前框111以及金屬背板112共同圍成一容置空間114。所述容置空間114用以容置所述無線通訊裝置200的電路板210、處理單元等電子元件或電路模組於其內。本實施例中,所述電子元件至少包括所述後置雙鏡頭202、所述受話器203及前置鏡頭207,所述後置雙鏡頭202、所述受話器203及前置鏡頭207並排且間隔設置於所述無線通訊裝置200的電路板210。The metal frame 113 is sandwiched between the metal front frame 111 and the metal back plate 112, and is disposed around the periphery of the metal front frame 111 and the metal back plate 112 to communicate with the display unit. 201. The metal front frame 111 and the metal back plate 112 together form an accommodating space 114. The accommodating space 114 is used for accommodating electronic components or circuit modules such as a circuit board 210 and a processing unit of the wireless communication device 200 therein. In this embodiment, the electronic component includes at least the rear dual lens 202, the receiver 203, and the front lens 207. The rear dual lens 202, the receiver 203, and the front lens 207 are arranged side by side and spaced apart. On the circuit board 210 of the wireless communication device 200.
所述金屬邊框113至少包括頂部115、第一側部116以及第二側部117。所述頂部115連接所述金屬前框111與所述金屬背板112。所述第一側部116與所述第二側部117相對設置,兩者分別設置於所述頂部115的兩端,優選垂直設置於所述頂部115的兩端。所述第一側部116與所述第二側部117亦連接所述金屬前框111與所述金屬背板112。所述金屬邊框113上還開設有開槽118。在本實施例中,所述開槽118佈設於所述頂部115上,且分別延伸至所述第一側部116及第二側部117。可以理解,在其他實施例中,所述開槽118也可僅設置於所述頂部115,而未延伸至所述第一側部116及第二側部117中的任何一個,或者所述開槽118設置於所述頂部115,且僅沿延伸至所述第一側部116及第二側部117中的其中之一。The metal frame 113 includes at least a top portion 115, a first side portion 116, and a second side portion 117. The top 115 is connected to the metal front frame 111 and the metal back plate 112. The first side portion 116 and the second side portion 117 are disposed opposite to each other, and the two are respectively disposed at two ends of the top portion 115, and preferably are vertically disposed at both ends of the top portion 115. The first side portion 116 and the second side portion 117 are also connected to the metal front frame 111 and the metal back plate 112. A slot 118 is also defined in the metal frame 113. In this embodiment, the slot 118 is disposed on the top portion 115 and extends to the first side portion 116 and the second side portion 117 respectively. It can be understood that, in other embodiments, the slot 118 may be provided only on the top portion 115 without extending to any one of the first side portion 116 and the second side portion 117, or the opening portion The groove 118 is provided on the top portion 115 and extends along only one of the first side portion 116 and the second side portion 117.
所述金屬前框111的頂邊間隔開設有第一斷點1112及第二斷點1114,兩側邊靠近該頂邊分別開設有一第三斷點1116及一第四斷點1118。所述第三斷點1116及第四斷點1118分別位於所述開槽118的相對兩個末端。所述斷點1112、1114、1116、1118與所述開槽118連通,並延伸至隔斷所述金屬前框111。所述四個斷點自金屬前框111劃分出三部分,這三部分至少包括第一輻射段22、第二輻射段24及第三輻射段26。在本實施例中,所述第一斷點1112及第二斷點1114分別設置於金屬前框111的頂邊的相對兩端靠近拐角處,第一輻射段22位於第一斷點1112與第二斷點1114之間;所述第二輻射段24位於第一斷點1112與第三斷點1116之間,第二輻射段24由金屬前框111的頂邊延伸至側邊,且延伸經過該金屬前框111的一圓弧形拐角;所述第三輻射段26位於第二斷點1114與第四斷點1118之間,第三輻射段26由金屬前框111的頂邊延伸至另一側邊,且延伸經過該金屬前框111的另一圓弧形拐角。另外,所述開槽118及所述斷點1112、1114、1116、1118內均填充有絕緣材料(例如塑膠、橡膠、玻璃、木材、陶瓷等,但不以此為限),進而區隔所述第一輻射段22、第二輻射段24、第三輻射段26與所述金屬件11的其餘部分。A first breakpoint 1112 and a second breakpoint 1114 are spaced apart from the top edge of the metal front frame 111, and a third breakpoint 1116 and a fourth breakpoint 1118 are respectively set on both sides close to the top edge. The third breakpoint 1116 and the fourth breakpoint 1118 are respectively located at two opposite ends of the slot 118. The breakpoints 1112, 1114, 1116, and 1118 communicate with the slot 118 and extend to block the metal front frame 111. The four breakpoints are divided into three parts from the metal front frame 111, and the three parts include at least a first radiation segment 22, a second radiation segment 24, and a third radiation segment 26. In this embodiment, the first breakpoint 1112 and the second breakpoint 1114 are respectively disposed at the opposite ends of the top edge of the metal front frame 111 near the corners, and the first radiating section 22 is located at the first breakpoint 1112 and the first Between the two breakpoints 1114; the second radiating segment 24 is located between the first breakpoint 1112 and the third breakpoint 1116, and the second radiating segment 24 extends from the top edge to the side of the metal front frame 111, and extends past An arc-shaped corner of the metal front frame 111; the third radiation segment 26 is located between the second breakpoint 1114 and the fourth breakpoint 1118, and the third radiation segment 26 extends from the top edge of the metal front frame 111 to another One side, and another arc-shaped corner extending through the metal front frame 111. In addition, the slot 118 and the breakpoints 1112, 1114, 1116, and 1118 are filled with an insulating material (such as plastic, rubber, glass, wood, ceramic, etc., but not limited to this), so as to separate the offices. The first radiating section 22, the second radiating section 24, the third radiating section 26 and the rest of the metal part 11 are described.
可以理解,所述金屬前框111上半部除了所述斷點以外沒有再設置其他絕緣的開槽、斷線或斷點,因此所述金屬前框111的上半部就只有四個斷點1112、1114、1116、1118,沒有其他斷點。It can be understood that the upper half of the metal front frame 111 is not provided with other insulation slots, breaks, or breakpoints in addition to the breakpoint, so the upper half of the metal front frame 111 has only four breakpoints. 1112, 1114, 1116, 1118, no other breakpoints.
所述第一饋入部12可通過匹配電路(圖未示)電連接至所述第一輻射段22較為靠近第一斷點1112的一端,從而第一饋入部12為所述第一輻射段22饋入電流。本實施例中,從第一饋入部12饋入電流後,所述電流在第一輻射段22分別向該第一斷點1112和第二斷點1114傳送,從而使得第一輻射段22以該第一饋入部12為分隔點分為相向該第一斷點1112的金屬短臂A1及相向該第二斷點1114的金屬長臂A2。在本實施例中,所述第一饋入部12接入的位置並非對應到第一輻射段22的中間,因此所述金屬長臂A2的長度大於金屬短臂A1的長度。所述金屬短臂A1激發一第一模態以產生第一頻段的輻射訊號,所述金屬長臂A2激發一第二模態以產生第二頻段的輻射訊號。本實施例中,所述第一模態為LTE-A中頻模態,所述第一頻段為1805-2170MHz頻段;所述第二模態為LTE-A低頻模態,所述第二頻段為703-960 MHz頻段。所述LTE-A為進階長期演進技術(Long Term Evolution Advanced)的簡寫。The first feeding portion 12 may be electrically connected to an end of the first radiating section 22 closer to the first break point 1112 through a matching circuit (not shown), so that the first feeding portion 12 is the first radiating section 22. Feed current. In this embodiment, after a current is fed from the first feeding section 12, the current is transmitted to the first breakpoint 1112 and the second breakpoint 1114 in the first radiation section 22, so that the first radiation section 22 starts at this point. The first feeding portion 12 is divided into a metal short arm A1 facing the first break point 1112 and a metal long arm A2 facing the second break point 1114. In this embodiment, the position where the first feeding portion 12 is connected does not correspond to the middle of the first radiating section 22, so the length of the metal long arm A2 is greater than the length of the metal short arm A1. The metal short arm A1 excites a first mode to generate a radiation signal in a first frequency band, and the metal short arm A2 excites a second mode to generate a radiation signal in a second frequency band. In this embodiment, the first mode is an LTE-A intermediate frequency mode, the first frequency band is 1805-2170 MHz, and the second mode is an LTE-A low frequency mode, and the second frequency band is For the 703-960 MHz band. The LTE-A is an abbreviation of Long Term Evolution Advanced.
該第一輻射段22還連接至一第一接地部27及一第二接地部28。所述第一接地部27與第二接地部28分別位於該第一饋入部12的兩側。所述第一接地部27與第二接地部28均大致呈L型金屬臂。The first radiation section 22 is also connected to a first ground portion 27 and a second ground portion 28. The first grounding portion 27 and the second grounding portion 28 are respectively located on two sides of the first feeding portion 12. The first grounding portion 27 and the second grounding portion 28 are both substantially L-shaped metal arms.
所述第一輻射體15大致呈L型,其一個臂部平行並間隔於所述第一接地部27並連接至一第三接地部152,另一個臂部平行並間隔於所述第一輻射段22。所述第一輻射體15從該第一輻射段22耦合以諧振出所述第一頻段。本實施例中,所述第一輻射段22、第一饋入部12、第一接地部27、第二接地部28、第一輻射體15及第三接地部152組成第一分集天線,所述第一分集天線共振出所述LTE-A低頻模態及LTE-A中頻模態的輻射訊號。The first radiator 15 is substantially L-shaped, one arm portion is parallel and spaced from the first ground portion 27 and connected to a third ground portion 152, and the other arm portion is parallel and spaced from the first radiation Paragraph 22. The first radiator 15 is coupled from the first radiation section 22 to resonate out of the first frequency band. In this embodiment, the first radiating section 22, the first feeding portion 12, the first grounding portion 27, the second grounding portion 28, the first radiator 15 and the third grounding portion 152 constitute a first diversity antenna. The first diversity antenna resonates the radiation signals of the LTE-A low frequency mode and the LTE-A intermediate frequency mode.
所述第二饋入部13大致呈L形金屬臂,第二饋入部13的一端連接至所述第二輻射段24靠近第三斷點1116的一端。所述第二輻射段24從第二饋入部13饋入電流,激發一第三模態以產生第三頻段的輻射訊號。本實施例中,所述第三模態為GPS模態,所述第三頻段為1575MHz的頻段。本實施例中,所述第二輻射段24及第二饋入部13組成GPS天線,所述GPS天線共振出所述涵蓋GPS頻段的輻射訊號。The second feeding portion 13 is a substantially L-shaped metal arm. One end of the second feeding portion 13 is connected to an end of the second radiating section 24 near the third break point 1116. The second radiating section 24 feeds a current from the second feeding section 13 to excite a third mode to generate a radiation signal in a third frequency band. In this embodiment, the third mode is a GPS mode, and the third frequency band is a 1575 MHz frequency band. In this embodiment, the second radiation section 24 and the second feeding section 13 constitute a GPS antenna, and the GPS antenna resonates the radiation signal covering the GPS frequency band.
所述第三饋入部14大致呈L形金屬臂,第三饋入部14的一端連接至所述第三輻射段26靠近第四斷點1118的一端。所述第三輻射段26從第三饋入部14饋入電流,激發一第四模態以產生第四頻段的輻射訊號。本實施例中,所述第四模態為WiFi 2.4G模態,所述第四頻段為2400-2484MHz頻段。本實施例中,所述第三輻射段26及第三饋入部14組成WiFi 2.4G天線,所述WiFi 2.4G天線共振出所述涵蓋WiFi 2.4G頻段的輻射訊號。The third feeding portion 14 is a substantially L-shaped metal arm. One end of the third feeding portion 14 is connected to an end of the third radiating section 26 near the fourth break point 1118. The third radiation section 26 feeds a current from the third feeding section 14 to excite a fourth mode to generate a radiation signal in a fourth frequency band. In this embodiment, the fourth mode is a WiFi 2.4G mode, and the fourth frequency band is a 2400-2484 MHz frequency band. In this embodiment, the third radiation section 26 and the third feeding section 14 constitute a WiFi 2.4G antenna, and the WiFi 2.4G antenna resonates the radiation signal covering the WiFi 2.4G frequency band.
所述第二輻射體16間隔所述第一輻射段22、第二輻射段24、第二饋入部13及前置鏡頭207設置。所述第二輻射體16設置於所述第一輻射段22、第二輻射段24、第二饋入部13及前置鏡頭207所包圍的空間內。所述第二輻射體16包括均呈直條狀的第一輻射臂161、第二輻射臂162、第三輻射臂163、第四輻射臂164及第五輻射臂165。所述第二輻射體16還電性連接至所述第四饋入部17及一第四接地部166。本實施例中,所述第四饋入部17及第四接地部166均呈直條狀且相互平行。所述第一輻射臂161大致垂直連接至所述第四饋入部17與第四接地部166之間。所述第二輻射臂162垂直連接至所述第一輻射臂161與第三輻射臂163之間,所述第一輻射臂161與第三輻射臂163相互平行且由第二輻射臂162的相對兩端向相反方向延伸。所述第二輻射臂162與第四輻射臂164相互平行且由第三輻射臂163的相對兩端向相同方向延伸。所述第四輻射臂164垂直連接至所述第三輻射臂163與第五輻射臂165之間,所述第三輻射臂163與第五輻射臂165相互平行且由第四輻射臂164的相對兩端向相同方向延伸。所述第五輻射臂165的長度大於所述第三輻射臂163,所述第四輻射臂164的長度大於所述第二輻射臂162。所述第三輻射臂163間隔且平行於所述第二輻射段24,所述第四輻射臂164間隔且平行於所述金屬短臂A1,所述第四饋入部17間隔且平行於所述第二饋入部13。所述第二輻射體16從第四饋入部17饋入電流,激發一第五模態以產生第五頻段的輻射訊號。本實施例中,所述第五模態為LET-A高頻模態,所述第五頻段為2300-2690MHz頻段。本實施例中,所述第二輻射體16、第四饋入部17及第四接地部166組成第二分集天線,所述第二分集天線共振出所述高頻頻段的輻射訊號。The second radiator 16 is disposed at a distance from the first radiating section 22, the second radiating section 24, the second feeding section 13 and the front lens 207. The second radiator 16 is disposed in a space surrounded by the first radiating section 22, the second radiating section 24, the second feeding section 13 and the front lens 207. The second radiator 16 includes a first radiation arm 161, a second radiation arm 162, a third radiation arm 163, a fourth radiation arm 164, and a fifth radiation arm 165, each of which is straight. The second radiator 16 is also electrically connected to the fourth feeding portion 17 and a fourth ground portion 166. In this embodiment, the fourth feeding portion 17 and the fourth grounding portion 166 are both straight and parallel to each other. The first radiation arm 161 is substantially vertically connected between the fourth feeding portion 17 and the fourth ground portion 166. The second radiation arm 162 is vertically connected between the first radiation arm 161 and the third radiation arm 163. The first radiation arm 161 and the third radiation arm 163 are parallel to each other and are opposed by the second radiation arm 162. Both ends extend in opposite directions. The second radiation arm 162 and the fourth radiation arm 164 are parallel to each other and extend from the opposite ends of the third radiation arm 163 in the same direction. The fourth radiation arm 164 is vertically connected between the third radiation arm 163 and the fifth radiation arm 165. The third radiation arm 163 and the fifth radiation arm 165 are parallel to each other and are opposed by the fourth radiation arm 164. Both ends extend in the same direction. The length of the fifth radiation arm 165 is longer than the length of the third radiation arm 163, and the length of the fourth radiation arm 164 is longer than the length of the second radiation arm 162. The third radiating arms 163 are spaced apart and parallel to the second radiating section 24, the fourth radiating arms 164 are spaced apart and parallel to the metal short arm A1, and the fourth feeding portion 17 is spaced apart and parallel to the第二 feed-in section 13. The second radiator 16 feeds a current from the fourth feeding portion 17 to excite a fifth mode to generate a radiation signal in a fifth frequency band. In this embodiment, the fifth mode is a LET-A high-frequency mode, and the fifth frequency band is a 2300-2690 MHz frequency band. In this embodiment, the second radiator 16, the fourth feeding portion 17 and the fourth grounding portion 166 constitute a second diversity antenna, and the second diversity antenna resonates the radiation signal in the high frequency band.
所述第三輻射體18間隔所述後置雙鏡頭202、第三輻射段26及第二斷點1114設置。所述第三輻射體18設置於所述後置雙鏡頭202及第三輻射段26所包圍的空間內。所述第三輻射體18呈直條狀,其間隔且平行於所述第三輻射段26。所述第三輻射體18電性連接至所述第五饋入部19及一第五接地部182。本實施例中,所述第五饋入部19及第五接地部182均呈直條狀且相互平行。所述第三輻射體18從第五饋入部19饋入電流,激發一第六模態以產生第六頻段的輻射訊號。本實施例中,所述第六模態為WiFi 5G模態,所述第六頻段為5150-5850MHz頻段。本實施例中,所述第三輻射體18、第五饋入部19及第五接地部182組成WiFi 5G天線,所述WiFi 5G天線共振出涵蓋所述WiFi 5G頻段的輻射訊號。The third radiator 18 is disposed at a distance from the rear dual lens 202, the third radiation segment 26, and the second break point 1114. The third radiator 18 is disposed in a space surrounded by the rear dual lens 202 and the third radiation section 26. The third radiator 18 has a straight bar shape, and is spaced apart and parallel to the third radiation section 26. The third radiator 18 is electrically connected to the fifth feeding portion 19 and a fifth grounding portion 182. In this embodiment, the fifth feeding portion 19 and the fifth grounding portion 182 are straight and parallel to each other. The third radiator 18 feeds a current from the fifth feeding portion 19 to excite a sixth mode to generate a radiation signal in a sixth frequency band. In this embodiment, the sixth mode is a WiFi 5G mode, and the sixth frequency band is a 5150-5850 MHz frequency band. In this embodiment, the third radiator 18, the fifth feeding portion 19, and the fifth grounding portion 182 form a WiFi 5G antenna, and the WiFi 5G antenna resonates a radiation signal covering the WiFi 5G frequency band.
請參閱圖4,所述切換電路20設置於電路板210上。所述切換電路20一端電性連接至所述第二接地部28,另一端連接至接地面。所述接地面可以是所述金屬背板112。或者,在所述顯示單元201朝向金屬背板112那一邊可設置一個用於遮罩電磁干擾的遮罩(shielding mask)或支撐所述顯示單元201的中框。所述遮罩或中框以金屬材料製作。所述接地面也可以是所述遮罩或中框。所述遮罩或中框可以和所述金屬背板112相連接以構成更大的接地面。所述接地面是所述天線結構100的地。也就是說,所述的每一個接地部均直接連接或間接連接所述接地面。Please refer to FIG. 4, the switching circuit 20 is disposed on the circuit board 210. One end of the switching circuit 20 is electrically connected to the second ground portion 28, and the other end is connected to a ground plane. The ground plane may be the metal back plate 112. Alternatively, a shielding mask for shielding electromagnetic interference or a middle frame supporting the display unit 201 may be provided on a side of the display unit 201 facing the metal back plate 112. The mask or the middle frame is made of a metal material. The ground plane may also be the shield or the middle frame. The shield or middle frame may be connected to the metal back plate 112 to form a larger ground plane. The ground plane is the ground of the antenna structure 100. That is, each of the ground portions is directly or indirectly connected to the ground plane.
所述切換電路20包括切換單元222及至少一切換元件224。所述切換元件224可以為電感、電容、或者電感與電容的組合。所述切換元件224之間相互並聯,且其一端電連接至所述切換單元222,另一端電連接至所述接地面。如此,通過控制所述切換單元222的切換,可使得所述金屬長臂A2切換至不同的切換元件224。由於每一個切換元件224具有不同的阻抗,因此通過所述切換單元222的切換,可調整所述金屬長臂A2的第二模態的頻段。所述的調整頻段就是使該頻段往低頻偏移或往高頻偏移。The switching circuit 20 includes a switching unit 222 and at least one switching element 224. The switching element 224 may be an inductor, a capacitor, or a combination of an inductor and a capacitor. The switching elements 224 are connected in parallel with each other, and one end of the switching elements 224 is electrically connected to the switching unit 222 and the other end is electrically connected to the ground plane. In this way, by controlling the switching of the switching unit 222, the metal long arm A2 can be switched to a different switching element 224. Since each switching element 224 has a different impedance, the frequency band of the second mode of the metal long arm A2 can be adjusted by the switching of the switching unit 222. The adjustment of the frequency band is to shift the frequency band to a low frequency or to a high frequency.
本實施例中,為得到較佳的天線特性,所述開槽118的寬度可設置為3.83毫米,也即所述第一輻射段22、第二輻射段24及第三輻射段26距離金屬背板112設置為3.83毫米,以使得第一輻射段22、第二輻射段24及第三輻射段26遠離所述金屬背板112,以提升所述輻射段的天線效率。所述斷點1112、1114、1116、1118的寬度設置為2毫米,以在不影響所述天線結構100的整體外觀的情況下進一步提升所述輻射段的天線效率。In this embodiment, in order to obtain better antenna characteristics, the width of the slot 118 may be set to 3.83 mm, that is, the first radiating section 22, the second radiating section 24, and the third radiating section 26 are away from the metal back. The plate 112 is set to 3.83 mm so that the first radiating section 22, the second radiating section 24, and the third radiating section 26 are far away from the metal back plate 112, so as to improve the antenna efficiency of the radiating section. The widths of the breakpoints 1112, 1114, 1116, and 1118 are set to 2 millimeters to further improve the antenna efficiency of the radiating section without affecting the overall appearance of the antenna structure 100.
本實施例中,所述第二輻射體16間隔設置於所述前置鏡頭207的一側。所述第一接地部27間隔設置於所述前置鏡頭207的另一側。所述第二接地部28間隔設置於所述後置雙鏡頭202與受話器203之間。所述第三輻射體18間隔設置於所述後置雙鏡頭202的一側。In this embodiment, the second radiators 16 are disposed at intervals on one side of the front lens 207. The first grounding portions 27 are disposed at intervals on the other side of the front lens 207. The second grounding portion 28 is spaced between the rear dual lens 202 and the receiver 203. The third radiator 18 is disposed on one side of the rear dual lens 202 at intervals.
圖5為所述天線結構100工作時的電流走向示意圖。當電流自所述第一饋入部12進入所述第一輻射段22後,分別向兩側方向流動,其中一個方向為流經所述金屬短臂A1,並流向所述第一斷點1112(參路徑P1),同時電流耦合至所述第一輻射體15,其電流方向與所述P1方向相反(參路徑P2),電流路徑P1與P2共同激發出所述LTE-A中頻模態。電流自所述第一饋入部12進入所述第一輻射段22後,向另一個方向為流經所述金屬長臂A2,並流向所述第二斷點1114(參路徑P3),進而激發出所述LTE-A低頻模態。另外,由於所述天線結構100設置有切換電路20,因此可利用所述切換電路20切換所述金屬長臂A2的LTE-A低頻模態。當電流自所述第二饋入部13進入所述第二輻射段24後,流經所述第二輻射段24並流向所述第一斷點1112(參路徑P4),進而激發出所述GPS模態。當電流自所述第三饋入部14進入所述第三輻射段26後,流經所述第三輻射段26並流向所述第二斷點1114(參路徑P5),進而激發出所述WiFi 2.4G模態。當電流自所述第四饋入部17進入所述第二輻射體16後,沿第二輻射體16的延伸方向流經所述第二輻射體16(參路徑P6),進而激發出所述LTE-A高頻模態。當電流自所述第五饋入部19進入所述第三輻射體18後,沿第三輻射體18的延伸方向流經所述第三輻射體18(參路徑P7),進而激發出所述WiFi 5G模態。FIG. 5 is a schematic diagram of a current trend during operation of the antenna structure 100. After the current enters the first radiating section 22 from the first feeding part 12, it flows in the directions of both sides, one of which flows through the metal short arm A1 and flows to the first break point 1112 ( (Refer to path P1), and the current is coupled to the first radiator 15 at the same time, and its current direction is opposite to the direction of P1 (refer to path P2). The current paths P1 and P2 jointly excite the LTE-A intermediate frequency mode. After the current enters the first radiating section 22 from the first feeding part 12, the current flows through the metal long arm A2 in the other direction and flows to the second break point 1114 (see path P3), and then is excited. The LTE-A low-frequency mode is obtained. In addition, since the antenna structure 100 is provided with a switching circuit 20, the LTE-A low-frequency mode of the metal long arm A2 can be switched by using the switching circuit 20. When a current enters the second radiation section 24 from the second feeding section 13, it flows through the second radiation section 24 and flows to the first break point 1112 (see path P4), and then the GPS is excited. Modal. After the current enters the third radiating section 26 from the third feeding section 14, it flows through the third radiating section 26 and flows to the second break point 1114 (see path P5), and then the WiFi is excited. 2.4G mode. When a current enters the second radiator 16 from the fourth feed-in part 17, it flows through the second radiator 16 (refer to path P6) along the extending direction of the second radiator 16 and further excites the LTE. -A high frequency mode. After the current enters the third radiator 18 from the fifth feeding part 19, it flows through the third radiator 18 along the extension direction of the third radiator 18 (see path P7), and then the WiFi is excited. 5G modalities.
圖6為所述天線結構100的第一分集天線、第二分集天線及GPS天線工作時的回波損耗(Return Loss)曲線圖。其中,曲線S1、S2、S3為金屬長臂A2工作於低頻時的回波損耗值,由於切換電路20對頻段調整以呈現不同的頻率曲線形態。曲線S4為第二輻射體16工作於高頻(2300-2690MHz)時的回波損耗值。曲線S5為第二輻射段24工作於GPS頻段(中心頻率為1575MHz)時的回波損耗值。FIG. 6 is a return loss curve diagram of the first diversity antenna, the second diversity antenna, and the GPS antenna of the antenna structure 100 during operation. Among them, the curves S1, S2, and S3 are the return loss values when the metal long arm A2 works at low frequencies, because the switching circuit 20 adjusts the frequency band to present different frequency curve shapes. The curve S4 is the return loss value when the second radiator 16 operates at a high frequency (2300-2690MHz). The curve S5 is the return loss value when the second radiating segment 24 operates in the GPS frequency band (the center frequency is 1575 MHz).
圖7為所述天線結構100的WiFi 2.4G天線及WiFi 5G天線工作時的回波損耗(Return Loss)曲線圖。其中,曲線S6為第三輻射段26工作於WiFi 2.4G頻段(2400-2484MHz)時的回波損耗值。曲線S7為第三輻射體18工作於WiFi 5G頻段(5150-5850MHz)時的回波損耗值。FIG. 7 is a graph showing return losses of the WiFi 2.4G antenna and the WiFi 5G antenna of the antenna structure 100 during operation. Among them, the curve S6 is the return loss value when the third radiation segment 26 operates in the WiFi 2.4G frequency band (2400-2484MHz). The curve S7 is the return loss value of the third radiator 18 when it operates in the WiFi 5G frequency band (5150-5850MHz).
圖8為所述天線結構100的第一分集天線、第二分集天線及GPS天線工作時的效率曲線圖。其中,曲線S81、S82、S83為金屬長臂A2工作於低頻時的輻射效率,由於切換電路20對頻段調整以呈現不同的頻率曲線形態。曲線S84為第一分集天線工作於中頻時的輻射效率。S85為第二輻射體16工作於高頻(2300-2690MHz)時的輻射效率。曲線S86為第二輻射段24工作於GPS頻段(中心頻率為1575MHz)時的輻射效率。FIG. 8 is an efficiency curve diagram of the first diversity antenna, the second diversity antenna, and the GPS antenna of the antenna structure 100 during operation. Among them, the curves S81, S82, and S83 are radiation efficiency when the metal long arm A2 works at low frequency, because the switching circuit 20 adjusts the frequency band to present different frequency curve shapes. The curve S84 is the radiation efficiency of the first diversity antenna when it operates at an intermediate frequency. S85 is the radiation efficiency when the second radiator 16 operates at a high frequency (2300-2690MHz). The curve S86 is the radiation efficiency when the second radiation segment 24 operates in the GPS frequency band (the center frequency is 1575 MHz).
圖9為所述天線結構100的WiFi 2.4G天線及WiFi 5G天線工作時的的效率曲線圖。其中,曲線S87為第三輻射段26工作於WiFi 2.4G頻段(2400-2484MHz)時的輻射效率。曲線S88為第三輻射體18工作於WiFi 5G頻段(5150-5850MHz)時的輻射效率。FIG. 9 is an efficiency curve diagram of the WiFi 2.4G antenna and the WiFi 5G antenna of the antenna structure 100 during operation. The curve S87 is the radiation efficiency of the third radiation segment 26 when it operates in the WiFi 2.4G frequency band (2400-2484MHz). The curve S88 is the radiation efficiency of the third radiator 18 when it operates in the WiFi 5G frequency band (5150-5850MHz).
顯然,從圖5至圖8可知,所述天線結構100可工作於相應的低頻頻段(703-960 MHz)、中頻頻段(1805-2170MHz)、高頻頻段(2300-2690MHz)。另外,所述天線結構100還可工作於GPS頻段(1575MHz)、WiFi 2.4G頻段(2244-2484MHz)以及WiFi 5G頻段(5150-5850MHz),即涵蓋至低、中、高頻,頻率範圍較廣,且當所述天線結構100工作於上述頻段時,其工作頻率均可滿足天線工作設計要求,並具有較佳的輻射效率。Obviously, it can be known from FIG. 5 to FIG. 8 that the antenna structure 100 can work in the corresponding low frequency band (703-960 MHz), intermediate frequency band (1805-2170MHz), and high frequency band (2300-2690MHz). In addition, the antenna structure 100 can also work in the GPS frequency band (1575MHz), the WiFi 2.4G frequency band (2244-2484MHz), and the WiFi 5G frequency band (5150-5850MHz), that is, it covers the low, medium, and high frequencies, and has a wide frequency range. Moreover, when the antenna structure 100 works in the above frequency band, its working frequency can meet the design requirements of the antenna and has better radiation efficiency.
所述天線結構100通過設置所述金屬件11,且所述金屬件11上的開槽及斷點均設置於所述金屬前框111及金屬邊框113上,並未設置於所述金屬背板112上,使得所述金屬背板112構成全金屬結構,即所述金屬背板112上並沒有絕緣的開槽、斷線或斷點,使得所述金屬背板112可避免由於開槽、斷線或斷點的設置而影響金屬背板112的完整性和美觀性。The antenna structure 100 is provided with the metal member 11, and the slots and breakpoints on the metal member 11 are provided on the metal front frame 111 and the metal frame 113, but not on the metal back plate. 112, so that the metal back plate 112 forms an all-metal structure, that is, the metal back plate 112 does not have insulation slots, breaks or break points, so that the metal back plate 112 can avoid The setting of lines or breakpoints affects the integrity and aesthetics of the metal back plate 112.
實施例2Example 2
請參閱圖10,本發明第二較佳實施方式提供一種天線結構300,其可應用於行動電話、個人數位助理等無線通訊裝置400中,用以發射、接收無線電波以傳遞、交換無線訊號。Referring to FIG. 10, a second preferred embodiment of the present invention provides an antenna structure 300 that can be applied to wireless communication devices 400 such as mobile phones and personal digital assistants to transmit and receive radio waves to transmit and exchange wireless signals.
請一併參閱圖11及圖12,所述天線結構300包括金屬件31、第一饋入部32、第一接地部33、第二接地部34、第二饋入部35、第三接地部36、輻射體37、第三饋入部38、第四接地部39、第一切換電路46及第二切換電路47(參圖13)。11 and FIG. 12 together, the antenna structure 300 includes a metal member 31, a first feeding portion 32, a first grounding portion 33, a second grounding portion 34, a second feeding portion 35, a third grounding portion 36, The radiator 37, the third feeding portion 38, the fourth ground portion 39, the first switching circuit 46, and the second switching circuit 47 (see FIG. 13).
所述金屬件31可以為所述無線通訊裝置400的外殼。所述金屬件31包括金屬前框311、金屬背板312及金屬邊框313。所述金屬前框311、金屬背板312及金屬邊框313可以是一體成型的。所述金屬前框311、金屬背板312以及金屬邊框313構成所述無線通訊裝置400的外殼。所述金屬前框311上設置有一開口(圖未標),用於容置所述無線通訊裝置400的顯示單元401。可以理解,所述顯示單元401具有一顯示平面,該顯示平面裸露於該開口,且該顯示平面與所述金屬背板312大致平行設置。The metal piece 31 may be a casing of the wireless communication device 400. The metal component 31 includes a metal front frame 311, a metal back plate 312 and a metal frame 313. The metal front frame 311, the metal back plate 312, and the metal frame 313 may be integrally formed. The metal front frame 311, the metal back plate 312, and the metal frame 313 constitute a casing of the wireless communication device 400. The metal front frame 311 is provided with an opening (not shown) for receiving the display unit 401 of the wireless communication device 400. It can be understood that the display unit 401 has a display plane, the display plane is exposed from the opening, and the display plane is substantially parallel to the metal back plate 312.
所述金屬背板312與所述金屬前框311相對設置。所述金屬背板312與金屬邊框313直接連接。所述金屬背板312與金屬邊框313之間沒有空隙。所述金屬背板312為一體成型的單一金屬片。所述金屬背板312為顯露後置雙鏡頭402與受話器403而設置開孔404、405。所述金屬背板312其上並沒有設置任何用於分割所述金屬背板312的絕緣的開槽、斷線或斷點(請參圖11)。所述金屬背板312可作為所述天線結構300的地。The metal back plate 312 is opposite to the metal front frame 311. The metal back plate 312 is directly connected to the metal frame 313. There is no gap between the metal back plate 312 and the metal frame 313. The metal back plate 312 is a single metal sheet integrally formed. The metal back plate 312 is provided with openings 404 and 405 for exposing the rear dual lens 402 and the receiver 403. The metal back plate 312 is not provided with any slot, break or break point for dividing the insulation of the metal back plate 312 (see FIG. 11). The metal back plate 312 can be used as a ground of the antenna structure 300.
所述金屬邊框313夾設於所述金屬前框311與所述金屬背板312之間,且分別環繞所述金屬前框311及所述金屬背板312的周緣設置,以與所述顯示單元401、所述金屬前框311以及金屬背板312共同圍成一容置空間314。所述容置空間314用以容置所述無線通訊裝置400的電路板410、處理單元等電子元件或電路模組於其內。本實施例中,所述電子元件至少包括所述後置雙鏡頭402、所述受話器403及前置鏡頭407,所述後置雙鏡頭402、所述受話器403及前置鏡頭407並排且間隔設置於電路板410上。The metal frame 313 is sandwiched between the metal front frame 311 and the metal back plate 312, and is disposed around the periphery of the metal front frame 311 and the metal back plate 312 to communicate with the display unit 401, the metal front frame 311 and the metal back plate 312 form a containing space 314 together. The accommodating space 314 is used for accommodating electronic components or circuit modules such as a circuit board 410 and a processing unit of the wireless communication device 400 therein. In this embodiment, the electronic component includes at least the rear dual lens 402, the receiver 403, and the front lens 407. The rear dual lens 402, the receiver 403, and the front lens 407 are arranged side by side and spaced apart. On the circuit board 410.
所述金屬邊框313至少包括頂部315、第一側部316以及第二側部317。所述頂部315連接所述金屬前框311與所述金屬背板312。所述第一側部316與所述第二側部317相對設置,兩者分別設置於所述頂部315的兩端,優選垂直設置於所述頂部315的兩端。所述第一側部316與所述第二側部317亦連接所述金屬前框311與所述金屬背板312。所述金屬邊框313上還開設有開槽318。在本實施例中,所述開槽318佈設於所述頂部315上,且分別延伸至所述第一側部316及第二側部317。可以理解,在其他實施例中,所述開槽318也可僅設置於所述頂部315,而未延伸至所述第一側部316及第二側部317中的任何一個,或者所述開槽318設置於所述頂部315,且僅沿延伸至所述第一側部316及第二側部317其中之一。The metal frame 313 includes at least a top portion 315, a first side portion 316 and a second side portion 317. The top portion 315 connects the metal front frame 311 and the metal back plate 312. The first side portion 316 and the second side portion 317 are disposed opposite to each other, and the two are disposed at two ends of the top portion 315, respectively, and are preferably disposed vertically at both ends of the top portion 315. The first side portion 316 and the second side portion 317 are also connected to the metal front frame 311 and the metal back plate 312. A slot 318 is also defined in the metal frame 313. In this embodiment, the slot 318 is disposed on the top portion 315 and extends to the first side portion 316 and the second side portion 317, respectively. It can be understood that, in other embodiments, the slot 318 may be provided only on the top portion 315 without extending to any one of the first side portion 316 and the second side portion 317, or the opening portion The groove 318 is disposed on the top portion 315 and extends along only one of the first side portion 316 and the second side portion 317.
所述金屬前框311的兩側邊靠近該頂邊分別對稱開設有一第一斷點3112及一第三斷點3116,頂邊開設有第二斷點3114。所述第一斷點3112及第三斷點3116分別位於所述開槽318的相對兩個末端。所述斷點3112、3114、3116與所述開槽318連通,並延伸至隔斷所述金屬前框311。所述三個斷點將金屬前框311劃分為兩個部分,至少包括第一輻射段42及第二輻射段44。在本實施例中,所述第二斷點3114設置於金屬前框311的頂邊的一端靠近拐角處,第一輻射段42位於第二斷點3114與第三斷點3116之間,第一輻射段42由金屬前框311的頂邊延伸至一側邊,且延伸經過該金屬前框311的一圓弧形拐角;所述第二輻射段44位於第一斷點3112與第二斷點3114之間,第二輻射段44由金屬前框311的頂邊延伸至另一側邊,且延伸經過該金屬前框311的另一圓弧形拐角。第一輻射段42的長度大於第二輻射段44的長度。另外,所述開槽318及所述斷點3112、3114、3116內均填充有絕緣材料(例如塑膠、橡膠、玻璃、木材、陶瓷等,但不以此為限),進而區隔所述第一輻射段42、第二輻射段44與所述金屬件31的其他部分。A first breakpoint 3112 and a third breakpoint 3116 are symmetrically provided on both sides of the metal front frame 311 near the top edge, and a second breakpoint 3114 is provided on the top edge. The first breakpoint 3112 and the third breakpoint 3116 are respectively located at two opposite ends of the slot 318. The break points 3112, 3114, and 3116 communicate with the slot 318 and extend to block the metal front frame 311. The three breakpoints divide the front metal frame 311 into two parts, including at least a first radiation segment 42 and a second radiation segment 44. In this embodiment, the second break point 3114 is disposed near an end of the top edge of the metal front frame 311, and the first radiating section 42 is located between the second break point 3114 and the third break point 3116. The radiating section 42 extends from the top edge of the metal front frame 311 to one side, and passes through a rounded corner of the metal front frame 311; the second radiating section 44 is located at the first break point 3112 and the second break point Between 3114, the second radiating section 44 extends from the top edge of the metal front frame 311 to the other side, and passes through another arc-shaped corner of the metal front frame 311. The length of the first radiating section 42 is greater than the length of the second radiating section 44. In addition, the slot 318 and the breakpoints 3112, 3114, and 3116 are filled with an insulating material (such as plastic, rubber, glass, wood, ceramic, etc., but not limited to this), so as to separate the first A radiating section 42, a second radiating section 44 and other parts of the metal piece 31.
可以理解,所述金屬前框311上半部除了所述斷點以外沒有再設置其他絕緣的開槽、斷線或斷點,因此所述金屬前框311的上半部就只有三個斷點3112、3114、3116,沒有其他斷點。It can be understood that the upper half of the metal front frame 311 is not provided with other insulation slots, breaks, or breakpoints in addition to the breakpoint, so the upper half of the metal front frame 311 has only three breakpoints. 3112, 3114, 3116, no other breakpoints.
所述第一饋入部32的一端電連接至所述第一輻射段42較為靠近第二斷點3114的一端。第一饋入部32的另一端電連接至饋入源(圖未示)以為所述第一輻射段42饋入電流。本實施例中,從第一饋入部32饋入電流後,所述電流在第一輻射段42分別向該第二斷點3114和第三斷點3116傳送,從而使得第一輻射段42以該第一饋入部32為分隔點分為相向該第二斷點3114的金屬短臂B1及相向該第三斷點3116的金屬長臂B2。在本實施例中,所述第一饋入部32接入的位置並非對應到第一輻射段42的中間,因此所述金屬長臂B2的長度大於金屬短臂B1的長度。One end of the first feeding portion 32 is electrically connected to an end of the first radiating section 42 which is closer to the second break point 3114. The other end of the first feeding section 32 is electrically connected to a feeding source (not shown) to feed current to the first radiation section 42. In this embodiment, after a current is fed from the first feeding part 32, the current is transmitted to the second break point 3114 and the third break point 3116 in the first radiation section 42, respectively, so that the first radiation section 42 starts at this point. The first feed-in portion 32 is divided into a metal short arm B1 facing the second break point 3114 and a metal long arm B2 facing the third break point 3116. In this embodiment, the position where the first feeding portion 32 is accessed does not correspond to the middle of the first radiating section 42, so the length of the metal long arm B2 is greater than the length of the metal short arm B1.
該第一輻射段42還連接至一第一接地部33及一第二接地部34。所述第一接地部33與第二接地部34分別位於該第一饋入部32的兩側。請參閱圖11及13,該第一接地部33連接至該金屬短臂B1,該第二接地部34連接至該金屬長臂B2。所述第一饋入部32包括第一臂322、第二臂324及第三臂326。該第二臂324大致呈U形,其兩端分別垂直連接該第一臂322及第三臂326。該第一臂322及第二臂324間隔該第一輻射段42設置,該第三臂326連接該第二臂324及第一輻射段42。所述第一接地部33與第二接地部34均為大致呈L型金屬臂。The first radiation section 42 is also connected to a first ground portion 33 and a second ground portion 34. The first grounding portion 33 and the second grounding portion 34 are respectively located on two sides of the first feeding portion 32. Please refer to FIGS. 11 and 13, the first ground portion 33 is connected to the metal short arm B1, and the second ground portion 34 is connected to the metal long arm B2. The first feeding portion 32 includes a first arm 322, a second arm 324, and a third arm 326. The second arm 324 is substantially U-shaped, and two ends of the second arm 324 are vertically connected to the first arm 322 and the third arm 326, respectively. The first arm 322 and the second arm 324 are disposed at a distance from the first radiation segment 42, and the third arm 326 is connected to the second arm 324 and the first radiation segment 42. The first ground portion 33 and the second ground portion 34 are both substantially L-shaped metal arms.
所述金屬短臂B1激發一第一模態以產生第一頻段的輻射訊號,所述金屬長臂B2激發一第二模態以產生第二頻段的輻射訊號,所述金屬長臂B2與金屬短臂B1共同激發一第三模態以產生第三頻段的輻射訊號。本實施例中,所述第一模態為LTE-A中頻模態,所述第一頻段為1575-2170MHz頻段;所述第二模態為LTE-A低頻模態,所述第二頻段為703-960 MHz頻段;所述第三模態為一GPS模態,所述第三頻段為1575MHz頻段。所述第一輻射段42、第一饋入部32、第一接地部33及第二接地部34組成第一分集/GPS天線,所述第一分集/GPS天線共振出所述LTE-A低頻模態、LTE-A中頻模態及GPS模態的輻射訊號。The metal short arm B1 excites a first mode to generate a radiation signal in a first frequency band, the metal long arm B2 excites a second mode to generate a radiation signal in a second frequency band, the metal long arm B2 and metal The short arm B1 collectively excites a third mode to generate a radiation signal in a third frequency band. In this embodiment, the first mode is an LTE-A intermediate frequency mode, the first frequency band is a 1575-2170 MHz frequency band, and the second mode is an LTE-A low frequency mode, and the second frequency band is The frequency band is 703-960 MHz; the third mode is a GPS mode, and the third frequency band is a 1575 MHz frequency band. The first radiating section 42, the first feeding section 32, the first grounding section 33 and the second grounding section 34 constitute a first diversity / GPS antenna, and the first diversity / GPS antenna resonates the LTE-A low-frequency mode. Signal, LTE-A IF mode and GPS mode.
所述第一切換電路46及第二切換電路47均設置於電路板410上。請一併參閱圖14,所述第一切換電路46一端電性連接至所述第一接地部33,另一端連接至接地面。所述第二切換電路47一端電性連接至所述第二接地部34,另一端連接至接地面。所述接地面可以是所述金屬背板312。或者,在所述顯示單元401朝向金屬背板312那一邊可設置一個用於遮罩電磁干擾的遮罩(shielding mask)或支撐所述顯示單元401的中框。所述遮罩或中框以金屬材料製作。所述接地面也可以是所述遮罩或中框。所述遮罩或中框可以和所述金屬背板312相連接以構成更大的接地面。所述接地面是所述天線結構300的地。也就是說,所述的每一個接地部均直接連接或間接連接所述接地面。The first switching circuit 46 and the second switching circuit 47 are both disposed on the circuit board 410. Referring to FIG. 14 together, one end of the first switching circuit 46 is electrically connected to the first ground portion 33 and the other end is connected to a ground plane. One end of the second switching circuit 47 is electrically connected to the second ground portion 34, and the other end is connected to a ground plane. The ground plane may be the metal back plate 312. Alternatively, a shielding mask for shielding electromagnetic interference or a middle frame supporting the display unit 401 may be provided on the side of the display unit 401 facing the metal back plate 312. The mask or the middle frame is made of a metal material. The ground plane may also be the shield or the middle frame. The shield or middle frame may be connected to the metal back plate 312 to form a larger ground plane. The ground plane is the ground of the antenna structure 300. That is, each of the ground portions is directly or indirectly connected to the ground plane.
所述第一切換電路46包括切換單元462及至少一切換元件464。所述切換元件464可以為電感、電容、或者電感與電容的組合。所述切換元件464之間相互並聯,且其一端電連接至所述切換單元462,另一端電連接至接地面。如此,通過控制所述切換單元462的切換,可使得所述金屬短臂B1切換至不同的切換元件464。由於每一個切換元件464具有不同的阻抗,因此通過所述切換單元462的切換,可調整所述金屬短臂B1的第一模態的頻段。所述的調整頻段就是使該頻段往低頻偏移或往高頻偏移。所述第二切換電路47的結構與第一切換電路46大致相同,用於調整所述金屬長臂B2的第二模態的頻段。通過第二切換電路47調整適當匹配阻抗值,使得所述LTE-A低頻模態可以涵蓋703-804MHz、824-894MHz及880-960MHz頻段。The first switching circuit 46 includes a switching unit 462 and at least one switching element 464. The switching element 464 may be an inductor, a capacitor, or a combination of an inductor and a capacitor. The switching elements 464 are connected in parallel with each other, and one end of the switching elements 464 is electrically connected to the switching unit 462 and the other end is electrically connected to a ground plane. In this way, by controlling the switching of the switching unit 462, the metal short arm B1 can be switched to a different switching element 464. Since each switching element 464 has a different impedance, the frequency band of the first mode of the metal short arm B1 can be adjusted by the switching of the switching unit 462. The adjustment of the frequency band is to shift the frequency band to a low frequency or to a high frequency. The structure of the second switching circuit 47 is substantially the same as that of the first switching circuit 46, and is used to adjust the frequency band of the second mode of the metal long arm B2. An appropriate matching impedance value is adjusted by the second switching circuit 47, so that the LTE-A low-frequency mode can cover 703-804 MHz, 824-894 MHz, and 880-960 MHz frequency bands.
所述第二饋入部35的一端連接至所述第二輻射段44靠近第一斷點3112的一端。所述第二饋入部35包括第四臂352、第五臂354、第六臂356及第七臂358。所述第三接地部36大致呈直條形金屬臂並連接所述接地面。所述第四臂352與第三接地部36間隔且平行設置,所述第五臂354連接於第四臂352與第三接地部36之間。所述第六臂356大致呈U形,其兩端分別連接所述第五臂354及第七臂358,且第六臂356連接第五臂354的一端還連接該第四臂352,且與該第五臂354共線。該第四臂352、第五臂354、第六臂356及第三接地部36與該第二輻射段44間隔設置,該第七臂358連接於該第六臂356與第二輻射段44之間。所述第二輻射段44從第二饋入部35饋入電流,激發一第四模態以產生第四頻段的輻射訊號。本實施例中,所述第四模態為LTE-A高頻模態,所述第四頻段為2300-2690MHz頻段。其中,所述第四模態包括一第五模態,所述第五模態為WiFi 2.4G模態,即第四頻段涵蓋一第五頻段,所述第五頻段為WiFi 2.4G頻段,所述WiFi 2.4G頻段為2400-2484MHz。本實施例中,所述第二輻射段44、第二饋入部35及第三接地部36組成第二分集/WiFi 2.4G天線,共振出所述涵蓋高頻頻段及WiFi 2.4G頻段的輻射訊號。One end of the second feeding portion 35 is connected to an end of the second radiating section 44 near the first break point 3112. The second feeding portion 35 includes a fourth arm 352, a fifth arm 354, a sixth arm 356, and a seventh arm 358. The third grounding portion 36 is a substantially straight metal arm and is connected to the grounding surface. The fourth arm 352 is spaced from and parallel to the third ground portion 36, and the fifth arm 354 is connected between the fourth arm 352 and the third ground portion 36. The sixth arm 356 is substantially U-shaped, and two ends thereof are respectively connected to the fifth arm 354 and the seventh arm 358, and one end of the sixth arm 356 connected to the fifth arm 354 is also connected to the fourth arm 352, and The fifth arm 354 is collinear. The fourth arm 352, the fifth arm 354, the sixth arm 356, and the third ground portion 36 are spaced from the second radiation segment 44. The seventh arm 358 is connected to the sixth arm 356 and the second radiation segment 44. between. The second radiation section 44 feeds a current from the second feeding section 35 to excite a fourth mode to generate a radiation signal in a fourth frequency band. In this embodiment, the fourth mode is an LTE-A high-frequency mode, and the fourth frequency band is a 2300-2690 MHz frequency band. The fourth mode includes a fifth mode, and the fifth mode is a WiFi 2.4G mode, that is, the fourth frequency band covers a fifth frequency band, and the fifth frequency band is a WiFi 2.4G frequency band. The WiFi 2.4G frequency band is 2400-2484MHz. In this embodiment, the second radiating section 44, the second feeding section 35, and the third grounding section 36 form a second diversity / WiFi 2.4G antenna, which resonates the radiation signals covering the high-frequency band and the WiFi 2.4G band. .
所述輻射體37設置於後置雙鏡頭402、金屬長臂B2與第三斷點3116之間,且所述輻射體37間隔後置雙鏡頭402、金屬長臂B2與第三斷點3116設置。所述輻射體37、第三饋入部38及第四接地部39均呈直條狀,其中第三饋入部38及第四接地部39間隔且平行設置,輻射體37連接於第三饋入部38及第四接地部39的同一側並相向該金屬前框311的頂邊延伸。所述第四接地部39連接所述接地面。所述輻射體37從第三饋入部38饋入電流,激發一第六模態以產生第六頻段的輻射訊號。本實施例中,所述第六模態為WiFi 5G模態,所述第六頻段為5150-5850MHz頻段。本實施例中,所述輻射體37、第三饋入部38及第四接地部39組成WiFi 5G天線,所述WiFi 5G天線共振出涵蓋所述WiFi 5G頻段的輻射訊號。The radiator 37 is disposed between the rear dual lens 402, the metal long arm B2, and the third break point 3116, and the radiator 37 is disposed between the rear dual lens 402, the metal long arm B2, and the third break point 3116. . The radiator 37, the third feeding portion 38, and the fourth grounding portion 39 are all in a straight bar shape. The third feeding portion 38 and the fourth grounding portion 39 are spaced and parallel to each other. The radiator 37 is connected to the third feeding portion 38. The same side as the fourth ground portion 39 extends toward the top edge of the metal front frame 311. The fourth ground portion 39 is connected to the ground plane. The radiator 37 feeds a current from the third feeding portion 38 to excite a sixth mode to generate a radiation signal in a sixth frequency band. In this embodiment, the sixth mode is a WiFi 5G mode, and the sixth frequency band is a 5150-5850 MHz frequency band. In this embodiment, the radiator 37, the third feeding portion 38, and the fourth grounding portion 39 form a WiFi 5G antenna, and the WiFi 5G antenna resonates a radiation signal covering the WiFi 5G frequency band.
本實施例中,為得到較佳的天線特性,所述開槽318的寬度可設置為3.83毫米,也即所述第一輻射段42、第二輻射段44距離金屬背板312設置為3.83毫米,該開槽318的寬度的可調範圍為3~4.5毫米,以使得第一輻射段42、第二輻射段44遠離所述金屬背板312,以提升所述輻射段的天線效率。所述斷點3112、3114、3116的寬度設置為2毫米,該斷點3112、3114、3116的寬度的可調範圍為1.5~2.5毫米,以在不影響所述天線結構300的整體外觀的情況下進一步提升所述輻射段的天線效率。In this embodiment, in order to obtain better antenna characteristics, the width of the slot 318 can be set to 3.83 mm, that is, the first radiation section 42 and the second radiation section 44 are set to 3.83 mm from the metal back plate 312. The adjustable range of the width of the slot 318 is 3 to 4.5 millimeters, so that the first radiating section 42 and the second radiating section 44 are far away from the metal back plate 312 to improve the antenna efficiency of the radiating section. The width of the breakpoints 3112, 3114, and 3116 is set to 2 millimeters, and the width of the breakpoints 3112, 3114, and 3116 is adjustable from 1.5 to 2.5 millimeters, so as not to affect the overall appearance of the antenna structure 300 The antenna efficiency of the radiation section is further improved.
圖13為所述天線結構300工作時的電流走向示意圖。當電流自所述第一饋入部32進入所述第一輻射段42後,分別向兩側方向流動,其中一個方向為流經所述金屬短臂B1,並流向所述第二斷點3114及第一接地部33(參路徑P1),進而激發出所述LTE-A中頻模態。電流自所述第一饋入部32進入所述第一輻射段42後,向另一個方向為流經所述金屬長臂B2,並流向所述第三斷點3116及第二接地部34(參路徑P2),進而激發出所述LTE-A低頻模態。另外,電流自所述第一饋入部32進入所述第一輻射段42後,分別沿金屬短臂B1向第二斷點3114及沿金屬長臂B2向第三斷點3116方向流動,並同時向第二接地部34流動(參路徑P3),進而激發出所述GPS模態。當電流自所述第二饋入部35進入所述第二輻射段44後,流經所述第二輻射段44並流向所述第二斷點3114(參路徑P4),進而激發出所述LTE-A高頻模態及WiFi 2.4G模態。當電流自所述第三饋入部38進入所述輻射體37後,沿輻射體37的延伸方向流經所述輻射體37(參路徑P5),進而激發出所述WiFi 5G模態。FIG. 13 is a schematic diagram of a current trend during operation of the antenna structure 300. After the current enters the first radiating section 42 from the first feeding part 32, the current flows to both sides, one of which flows through the metal short arm B1 and flows to the second break point 3114 and The first grounding portion 33 (refer to path P1) further excites the LTE-A intermediate frequency mode. After the current enters the first radiating section 42 from the first feeding part 32, it flows in the other direction through the metal long arm B2, and flows to the third break point 3116 and the second grounding part 34 (see Path P2), which further excites the LTE-A low-frequency mode. In addition, after the current enters the first radiating section 42 from the first feeding part 32, the current flows along the metal short arm B1 to the second break point 3114 and the metal long arm B2 to the third break point 3116, and simultaneously Flowing to the second grounding portion 34 (see path P3), the GPS mode is further excited. After the current enters the second radiating section 44 from the second feeding section 35, it flows through the second radiating section 44 and flows to the second break point 3114 (see path P4), thereby exciting the LTE. -A high frequency mode and WiFi 2.4G mode. After the current enters the radiator 37 from the third feeding part 38, it flows through the radiator 37 along the extending direction of the radiator 37 (see path P5), and then the WiFi 5G mode is excited.
圖15為所述天線結構300的第一分集/GPS天線及第二分集/WiFi 2.4G天線工作時的S參數(散射參數)曲線圖。其中,曲線S1、S2、S3為第一分集/GPS天線及第二分集/WiFi 2.4G天線在第一切換電路46及第二切換電路47切換時的頻段調整下分別工作於低頻(703-960MHz)、GPS頻段(1575MHz)及中頻(1575-2170MHz)時的回波損耗值。曲線S4為第二分集/WiFi 2.4G天線工作於WiFi 2.4G頻段時的回波損耗值。FIG. 15 is a graph of S parameters (scattering parameters) of the first diversity / GPS antenna and the second diversity / WiFi 2.4G antenna of the antenna structure 300 during operation. Among them, the curves S1, S2, and S3 are the first diversity / GPS antenna and the second diversity / WiFi 2.4G antenna. They work at low frequencies (703-960MHz) under the frequency band adjustment when the first switching circuit 46 and the second switching circuit 47 are switched. ), GPS frequency (1575MHz) and the return loss value at the intermediate frequency (1575-2170MHz). The curve S4 is the return loss value when the second diversity / WiFi 2.4G antenna operates in the WiFi 2.4G frequency band.
圖16為所述天線結構300的第二分集/WiFi 2.4G天線及WiFi 5G天線工作時的S參數(散射參數)曲線圖。其中,曲線S5為第二分集/WiFi 2.4G天線工作於WiFi 2.4G頻段時的回波損耗值。曲線S5與圖15中的曲線S4為同一曲線。曲線S6為輻射體37工作於WiFi 5G頻段(5150-5850MHz)時的回波損耗值。FIG. 16 is a graph of S parameters (scattering parameters) of the second diversity / WiFi 2.4G antenna and WiFi 5G antenna of the antenna structure 300 during operation. The curve S5 is the return loss value when the second diversity / WiFi 2.4G antenna works in the WiFi 2.4G frequency band. The curve S5 is the same curve as the curve S4 in FIG. 15. The curve S6 is the return loss value when the radiator 37 operates in the WiFi 5G frequency band (5150-5850MHz).
圖17為所述天線結構300的第一分集/GPS天線及第二分集/WiFi 2.4G天線工作時的效率曲線圖。其中,曲線S81、S82、S83為第一分集/GPS天線及第二分集/WiFi 2.4G天線在所述第一切換電路46及第二切換電路47切換時的頻段調整下分別工作於各頻段的輻射效率。FIG. 17 is an efficiency curve diagram of the first diversity / GPS antenna and the second diversity / WiFi 2.4G antenna of the antenna structure 300 during operation. Among them, the curves S81, S82, and S83 are the first diversity / GPS antenna and the second diversity / WiFi 2.4G antenna, which respectively work in each frequency band under the frequency band adjustment when the first switching circuit 46 and the second switching circuit 47 are switched. Radiation efficiency.
圖18為所述天線結構300的第二分集/WiFi 2.4G天線及WiFi 5G天線工作時的的效率曲線圖。其中,曲線S87為第二輻射段44工作於WiFi 2.4G頻段(2044-2484MHz)時的輻射效率。曲線S88為輻射體37工作於WiFi 5G頻段(5150-5850MHz)時的輻射效率。FIG. 18 is a graph of the efficiency of the second diversity / WiFi 2.4G antenna and WiFi 5G antenna of the antenna structure 300 during operation. Among them, the curve S87 is the radiation efficiency when the second radiation segment 44 operates in the WiFi 2.4G frequency band (2044-2484MHz). The curve S88 is the radiation efficiency when the radiator 37 works in the WiFi 5G frequency band (5150-5850MHz).
顯然,從圖14至圖17可知,所述第一分集/GPS天線、第二分集/WiFi 2.4G天線及WiFi 5G天線適用的工作頻率範圍涵蓋低頻頻段(703-960 MHz)、中頻頻段(1575-2170MHz)、高頻頻段(2300-2690MHz)。另外,所述天線結構300還可工作於GPS頻段(1575MHz)、WiFi 2.4G頻段(2044-2484MHz)以及WiFi 5G頻段(5150-5850MHz),即涵蓋至低、中、高頻,頻率範圍較廣,可應用於GSM Qual-band,UMTS Band I/II/V/VIII頻段,以及LTE-A 700/850/900/1800/1900/2100/2300/2500頻段的操作,且當所述天線結構300工作於上述頻段時,其工作頻率均可滿足天線工作設計要求,並具有較佳的輻射效率。Obviously, from FIG. 14 to FIG. 17, the working frequency range applicable to the first diversity / GPS antenna, the second diversity / WiFi 2.4G antenna, and the WiFi 5G antenna covers the low frequency band (703-960 MHz) and the intermediate frequency band ( 1575-2170MHz), high frequency band (2300-2690MHz). In addition, the antenna structure 300 can also work in the GPS frequency band (1575MHz), WiFi 2.4G frequency band (2044-2484MHz), and WiFi 5G frequency band (5150-5850MHz), that is to say, it covers low, medium, and high frequencies with a wide frequency range. , Applicable to GSM Qual-band, UMTS Band I / II / V / VIII frequency band, and operation of LTE-A 700/850/900/1800/1900/2100/2300/2500 frequency band, and when the antenna structure 300 When working in the above frequency bands, the working frequency can meet the antenna design requirements and has better radiation efficiency.
所述天線結構300通過設置所述金屬件31,且所述金屬件31上的開槽318及斷點3112、3114、3116均設置於所述金屬前框311及金屬邊框313上,並未設置於所述金屬背板312上,使得所述金屬背板312構成全金屬結構,即所述金屬背板312上並沒有絕緣的開槽、斷線或斷點,使得所述金屬背板312可避免由於開槽、斷線或斷點的設置而影響金屬背板312的完整性和美觀性。The antenna structure 300 is provided with the metal piece 31, and the slot 318 and the break points 3112, 3114, and 3116 on the metal piece 31 are provided on the metal front frame 311 and the metal frame 313, but are not provided. On the metal back plate 312, the metal back plate 312 forms an all-metal structure, that is, the metal back plate 312 has no insulation slots, breaks or break points, so that the metal back plate 312 can Avoiding affecting the integrity and aesthetics of the metal back plate 312 due to the setting of slots, breaks, or break points.
實施例3Example 3
請參閱圖19,本發明第三較佳實施方式提供一種天線結構500,其可應用於行動電話、個人數位助理等無線通訊裝置600中,用以發射、接收無線電波以傳遞、交換無線訊號。Referring to FIG. 19, a third preferred embodiment of the present invention provides an antenna structure 500 that can be applied to a wireless communication device 600 such as a mobile phone or a personal digital assistant to transmit and receive radio waves to transmit and exchange wireless signals.
請一併參閱圖20及圖21,所述天線結構500包括金屬件51、第一饋入部52、第一接地部53、第二接地部54、延伸段55、輻射體56、第二饋入部57、第三接地部58、匹配電路64(參圖23)、第一切換電路66及第二切換電路67(參圖24)。Please refer to FIG. 20 and FIG. 21 together. The antenna structure 500 includes a metal piece 51, a first feeding portion 52, a first grounding portion 53, a second grounding portion 54, an extension 55, a radiator 56, and a second feeding portion. 57. The third ground portion 58, a matching circuit 64 (see FIG. 23), a first switching circuit 66, and a second switching circuit 67 (see FIG. 24).
所述金屬件51可以為所述無線通訊裝置600的外殼。所述金屬件51包括金屬前框511、金屬背板512及金屬邊框513。所述金屬前框511、金屬背板512及金屬邊框513可以是一體成型的。所述金屬前框511、金屬背板512以及金屬邊框513構成所述無線通訊裝置600的外殼。所述金屬前框511上設置有一開口(圖未標),用於容置所述無線通訊裝置600的顯示單元601。可以理解,所述顯示單元601具有一顯示平面,該顯示平面裸露於該開口,且該顯示平面與所述金屬背板512大致平行設置。The metal piece 51 may be a casing of the wireless communication device 600. The metal piece 51 includes a metal front frame 511, a metal back plate 512, and a metal frame 513. The metal front frame 511, the metal back plate 512, and the metal frame 513 may be integrally formed. The metal front frame 511, the metal back plate 512, and the metal frame 513 constitute a casing of the wireless communication device 600. The metal front frame 511 is provided with an opening (not shown) for receiving the display unit 601 of the wireless communication device 600. It can be understood that the display unit 601 has a display plane, the display plane is exposed from the opening, and the display plane is substantially parallel to the metal back plate 512.
所述金屬背板512與所述金屬前框511相對設置。所述金屬背板512與金屬邊框513直接連接。所述金屬背板512與金屬邊框513之間沒有空隙。所述金屬背板512為一體成型的單一金屬片。所述金屬背板512為顯露後置雙鏡頭與受話器等元件而設置開孔及出音孔。所述金屬背板512其上並沒有設置任何用於分割所述金屬背板512的絕緣的開槽、斷線或斷點。所述金屬背板512可作為所述天線結構500的地。The metal back plate 512 is opposite to the metal front frame 511. The metal back plate 512 is directly connected to the metal frame 513. There is no gap between the metal back plate 512 and the metal frame 513. The metal back plate 512 is a single metal sheet integrally formed. The metal back plate 512 is provided with an opening and a sound emitting hole for exposing components such as a rear dual lens and a receiver. The metal back plate 512 is not provided with any slot, break or break for dividing the insulation of the metal back plate 512. The metal back plate 512 can be used as a ground of the antenna structure 500.
所述金屬邊框513夾設於所述金屬前框511與所述金屬背板512之間,且分別環繞所述金屬前框511及所述金屬背板512的周緣設置,以與所述顯示單元601、所述金屬前框511以及金屬背板512共同圍成一容置空間514。所述容置空間514用以容置所述無線通訊裝置600的電路板610、處理單元等電子元件或電路模組於其內。本實施例中,所述電子元件至少包括所述耳機插座602及USB連接器603。所述耳機插座602及USB連接器603並排且間隔設置於所述無線通訊裝置600的電路板610。The metal frame 513 is sandwiched between the metal front frame 511 and the metal back plate 512, and is disposed around the periphery of the metal front frame 511 and the metal back plate 512 to communicate with the display unit. 601. The metal front frame 511 and the metal back plate 512 together form an accommodating space 514. The accommodating space 514 is used for accommodating electronic components or circuit modules such as a circuit board 610 and a processing unit of the wireless communication device 600 therein. In this embodiment, the electronic component includes at least the headphone socket 602 and a USB connector 603. The earphone socket 602 and the USB connector 603 are arranged side by side and spaced from the circuit board 610 of the wireless communication device 600.
所述金屬邊框513至少包括底部515、第一側部516以及第二側部517。所述底部515連接所述金屬前框511與所述金屬背板512。所述第一側部516與所述第二側部517相對設置,兩者分別設置於所述底部515的兩端,優選垂直設置於所述底部515的兩端。所述第一側部516與所述第二側部517亦連接所述金屬前框511與所述金屬背板512。所述金屬邊框513上還開設有開槽518。在本實施例中,所述開槽518佈設於所述底部515上,且分別延伸至所述第一側部516及第二側部517。可以理解,在其他實施例中,所述開槽518也可僅設置於所述底部515,而未延伸至所述第一側部516及第二側部517中的任何一個,或者所述開槽518設置於所述底部515,且僅沿延伸至所述第一側部516及第二側部517中的其中之一。The metal frame 513 includes at least a bottom portion 515, a first side portion 516, and a second side portion 517. The bottom portion 515 connects the metal front frame 511 and the metal back plate 512. The first side portion 516 and the second side portion 517 are disposed opposite to each other, and the two are respectively disposed at two ends of the bottom portion 515, and are preferably vertically disposed at both ends of the bottom portion 515. The first side portion 516 and the second side portion 517 are also connected to the metal front frame 511 and the metal back plate 512. A slot 518 is also defined in the metal frame 513. In this embodiment, the slot 518 is disposed on the bottom portion 515 and extends to the first side portion 516 and the second side portion 517, respectively. It can be understood that, in other embodiments, the slot 518 may be provided only on the bottom portion 515 and does not extend to any one of the first side portion 516 and the second side portion 517, or the opening The groove 518 is disposed on the bottom portion 515 and extends along only one of the first side portion 516 and the second side portion 517.
所述金屬前框511的兩側邊分別對稱開設有一第一斷點5112及一第二斷點5114。所述第一斷點5112及第二斷點5114分別位於所述開槽518的相對兩個末端。所述斷點5112、5114與所述開槽518連通,並延伸至隔斷所述金屬前框511。所述金屬前框511位於第一斷點5112及第二斷點5114之間的部分形成輻射段62。在本實施例中,所述輻射段62由金屬前框511的底邊分別向兩邊延伸至兩側邊,且延伸經過該金屬前框511的兩個圓弧形拐角。另外,所述開槽518及所述斷點5112、5114內均填充有絕緣材料(例如塑膠、橡膠、玻璃、木材、陶瓷等,但不以此為限),進而區隔所述輻射段62與所述金屬件51的其餘部分。A first breakpoint 5112 and a second breakpoint 5114 are respectively formed on both sides of the metal front frame 511 symmetrically. The first breakpoint 5112 and the second breakpoint 5114 are respectively located at two opposite ends of the slot 518. The breakpoints 5112, 5114 communicate with the slot 518, and extend to block the metal front frame 511. A portion of the metal front frame 511 between the first break point 5112 and the second break point 5114 forms a radiation segment 62. In this embodiment, the radiating section 62 extends from the bottom edge of the front metal frame 511 to the two sides to the two sides, and extends through two arc-shaped corners of the front metal frame 511. In addition, the slot 518 and the breakpoints 5112, 5114 are filled with an insulating material (such as plastic, rubber, glass, wood, ceramic, etc., but not limited to this), so as to separate the radiation section 62. With the rest of the metal piece 51.
所述開槽518設置兩個開孔5182、5183,所述開孔5182、5183分別對應所述耳機插座602及USB連接器603,使所述耳機插座602及USB連接器603可以部份露出以供連接耳機與USB裝置。The slot 518 is provided with two openings 5182 and 5183, and the openings 5182 and 5183 correspond to the headphone socket 602 and the USB connector 603, respectively, so that the headphone socket 602 and the USB connector 603 can be partially exposed to For connecting headphones and USB devices.
可以理解,所述金屬前框511下半部除了所述斷點以外沒有再設置其他絕緣的開槽、斷線或斷點,因此所述金屬前框511的下半部就只有兩個斷點5112、5114,沒有其他斷點。It can be understood that the lower half of the metal front frame 511 is not provided with other insulation slots, breaks, or breakpoints in addition to the breakpoint, so the lower half of the metal front frame 511 has only two breakpoints. 5112, 5114, no other breakpoints.
所述第一饋入部52的一端電連接至所述輻射段62,所述第一饋入部52的另一端通過所述匹配電路64(參見圖23)電連接至饋入源59,從而饋入源59通過匹配電路64與第一饋入部52為所述輻射段62饋入電流。本實施例中,從第一饋入部52饋入電流後,所述電流在輻射段62分別向該第一斷點5112和第二斷點5114傳送,從而使得輻射段62以該第一饋入部52為分隔點分為相向該第一斷點5112的金屬短臂C1及相向該第二斷點5114的金屬長臂C2。在本實施例中,所述第一饋入部52接入的位置並非對應到輻射段62的中間,因此所述金屬長臂C2的長度大於金屬短臂C1的長度。One end of the first feeding portion 52 is electrically connected to the radiating section 62, and the other end of the first feeding portion 52 is electrically connected to a feeding source 59 through the matching circuit 64 (see FIG. 23), thereby feeding The source 59 feeds current to the radiating section 62 through the matching circuit 64 and the first feeding portion 52. In this embodiment, after the current is fed from the first feeding portion 52, the current is transmitted to the first break point 5112 and the second break point 5114 in the radiating section 62, so that the radiating section 62 uses the first feeding section 52 is a separation point divided into a metal short arm C1 opposite to the first break point 5112 and a metal long arm C2 opposite to the second break point 5114. In this embodiment, the position where the first feeding portion 52 is accessed does not correspond to the middle of the radiating section 62, so the length of the metal long arm C2 is greater than the length of the metal short arm C1.
所述輻射段62還連接至一第一接地部53及一第二接地部54。所述第一接地部53與第二接地部54分別位於該第一饋入部52的兩側。該第一接地部53連接至該金屬短臂C1,該第二接地部54連接至該金屬長臂C2。所述第一饋入部52與第二接地部54均大致呈L型金屬臂。所述第一饋入部52與第一接地部53分別設置於所述耳機插座602的兩側,其中所述第一接地部53靠近所述耳機插座602設置。所述第一饋入部52與第二接地部54分別設置於USB連接器603的兩側。所述第一接地部53包括第一臂532、第二臂534及第三臂536。該第二臂534大致呈U形,其兩端分別垂直連接該第一臂532及第三臂536。所述第二臂534圍繞開孔5182。該第二臂534及第三臂536間隔該輻射段62設置,該第一臂532連接該第二臂534及金屬短臂C1。所述第三臂536連接至所述金屬背板512,即接地。The radiation section 62 is also connected to a first ground portion 53 and a second ground portion 54. The first grounding portion 53 and the second grounding portion 54 are respectively located on two sides of the first feeding portion 52. The first ground portion 53 is connected to the metal short arm C1, and the second ground portion 54 is connected to the metal long arm C2. The first feeding portion 52 and the second grounding portion 54 are both substantially L-shaped metal arms. The first feeding portion 52 and the first grounding portion 53 are respectively disposed on two sides of the earphone socket 602, and the first grounding portion 53 is disposed near the earphone socket 602. The first feeding portion 52 and the second ground portion 54 are respectively disposed on two sides of the USB connector 603. The first ground portion 53 includes a first arm 532, a second arm 534, and a third arm 536. The second arm 534 is substantially U-shaped, and two ends of the second arm 534 are vertically connected to the first arm 532 and the third arm 536, respectively. The second arm 534 surrounds the opening 5182. The second arm 534 and the third arm 536 are disposed at a distance from the radiation segment 62, and the first arm 532 is connected to the second arm 534 and the metal short arm C1. The third arm 536 is connected to the metal back plate 512, that is, grounded.
所述延伸段55設置於所述容置空間514之內。所述延伸段55由所述金屬長臂C2靠近所述第二斷點5114的一端向遠離所述第二斷點5114的方向延伸,並且延伸至越過所述第二接地部54。所述延伸段55間隔且平行於所述金屬前框511的底部。The extension section 55 is disposed in the accommodation space 514. The extending section 55 extends from an end of the metal long arm C2 close to the second break point 5114 in a direction away from the second break point 5114 and extends beyond the second ground portion 54. The extensions 55 are spaced apart and parallel to the bottom of the metal front frame 511.
所述金屬短臂C1及第一接地部53激發一第一模態以產生第一頻段的輻射訊號,所述金屬長臂C2激發一第二模態以產生第二頻段的輻射訊號,所述金屬長臂C2及所述延伸段55激發一第三模態以產生第三頻段的輻射訊號。本實施例中,所述第一模態為LTE-A中頻模態,所述第一頻段為1710-1990MHz頻段;所述第二模態為LTE-A低頻模態,所述第二頻段為703-960 MHz頻段;所述第三模態為LTE-A中頻模態,所述第三頻段為2110-2170MHz頻段。The metal short arm C1 and the first ground portion 53 excite a first mode to generate a radiation signal in a first frequency band, and the metal long arm C2 excites a second mode to generate a radiation signal in a second frequency band, the The metal long arm C2 and the extension 55 excite a third mode to generate a radiation signal in a third frequency band. In this embodiment, the first mode is an LTE-A intermediate frequency mode, the first frequency band is a 1710-1990 MHz frequency band, and the second mode is an LTE-A low frequency mode, and the second frequency band is The frequency band is 703-960 MHz; the third mode is the LTE-A intermediate frequency mode, and the third frequency band is the 2110-2170MHz frequency band.
請參閱圖23,所述匹配電路64電性連接於所述第一饋入部52與饋入源59之間。所述匹配電路64與饋入源59均可設置於電路板610上。所述匹配電路64包括第一阻抗元件641、第二阻抗元件642、第三阻抗元件643、第四阻抗元件644及第五阻抗元件645。所述第一阻抗元件641、第二阻抗元件642、第三阻抗元件643依次串聯連接,所述第一阻抗元件641電性連接至所述饋入源59,所述第三阻抗元件643電性連接至所述第一饋入部52。所述第四阻抗元件644一端電性連接至第一阻抗元件641與第二阻抗元件642之間,另一端接地;所述第五阻抗元件645一端電性連接至第二阻抗元件642與第三阻抗元件643之間,另一端接地。所述輻射段62通過所述匹配電路64使得增加所述中頻的頻寬。本實施例中,該第一阻抗元件641可為9.8nH(納亨)的電感,該第二阻抗元件642可為1.8nH的電感,該第三阻抗元件643可為0.8pF(皮法)的電容,該第四阻抗元件644可為0.87pF的電容,該第五阻抗元件645可為0.3pF的電容。Referring to FIG. 23, the matching circuit 64 is electrically connected between the first feeding portion 52 and the feeding source 59. Both the matching circuit 64 and the feed source 59 can be disposed on the circuit board 610. The matching circuit 64 includes a first impedance element 641, a second impedance element 642, a third impedance element 643, a fourth impedance element 644, and a fifth impedance element 645. The first impedance element 641, the second impedance element 642, and the third impedance element 643 are sequentially connected in series. The first impedance element 641 is electrically connected to the feed source 59. The third impedance element 643 is electrically connected. Connected to the first feeding portion 52. One end of the fourth impedance element 644 is electrically connected between the first impedance element 641 and the second impedance element 642, and the other end is grounded; one end of the fifth impedance element 645 is electrically connected to the second impedance element 642 and the third Between the impedance elements 643, the other end is grounded. The radiating section 62 increases the bandwidth of the intermediate frequency by the matching circuit 64. In this embodiment, the first impedance element 641 may be an inductor of 9.8 nH (NaHen), the second impedance element 642 may be an inductor of 1.8 nH, and the third impedance element 643 may be 0.8 pF (picofarad). Capacitance, the fourth impedance element 644 may be a 0.87 pF capacitor, and the fifth impedance element 645 may be a 0.3 pF capacitor.
請參閱圖24,所述第一切換電路66一端電性連接至所述第二接地部54,另一端連接至接地面。所述接地面可以是所述金屬背板512。或者,在所述顯示單元601朝向金屬背板512那一邊可設置一個用於遮罩電磁干擾的遮罩(shielding mask)或支撐所述顯示單元601的中框。所述遮罩或中框以金屬材料製作。所述接地面也可以是所述遮罩或中框。所述遮罩或中框可以和所述金屬背板512相連接以構成更大的接地面。所述接地面是所述天線結構500的地。也就是說,所述的每一個接地部均直接連接或間接連接所述接地面。Referring to FIG. 24, one end of the first switching circuit 66 is electrically connected to the second ground portion 54, and the other end is connected to a ground plane. The ground plane may be the metal back plate 512. Alternatively, a shielding mask for shielding electromagnetic interference or a middle frame supporting the display unit 601 may be provided on a side of the display unit 601 facing the metal back plate 512. The mask or the middle frame is made of a metal material. The ground plane may also be the shield or the middle frame. The shield or middle frame may be connected to the metal back plate 512 to form a larger ground plane. The ground plane is the ground of the antenna structure 500. That is, each of the ground portions is directly or indirectly connected to the ground plane.
所述第一切換電路66包括切換單元662及至少一切換元件664。所述切換元件664可以為電感、電容、或者電感與電容的組合。所述切換元件664之間相互並聯,且其一端電連接至所述切換單元662,另一端電連接至所述接地面。如此,通過控制所述切換單元662的切換,可使得所述金屬長臂C2切換至不同的切換元件664。由於每一個切換元件664具有不同的阻抗,因此通過所述切換單元662的切換,可調整所述金屬長臂C2的第二模態的頻段。所述的調整頻段就是使該頻段往低頻偏移或往高頻偏移。通過第一切換電路66調整適當電感值的大小,使得所述LTE-A低頻模態可以涵蓋703-804MHz、824-894MHz及880-960MHz頻段。所述第二切換電路67的結構與第一切換電路66大致相同。所述第二切換電路67一端電性連接至所述第三接地部58,另一端連接至所述接地面。可以理解,通過調整第一接地部53連接至金屬短臂C1的位置,可調整第一模態的頻率高低。通過調整第一接地部53彎折的長度,可調整匹配及第一模態的頻率高低。可以理解,通過調整延伸段55的長度,可以調整第三模態的頻段高低,所述延伸段55的長度越長,第三模態的頻率越低;反之,減小延伸段55的長度,則可提高第三模態的頻率。The first switching circuit 66 includes a switching unit 662 and at least one switching element 664. The switching element 664 may be an inductor, a capacitor, or a combination of an inductor and a capacitor. The switching elements 664 are connected in parallel with each other, and one end of the switching elements 664 is electrically connected to the switching unit 662, and the other end is electrically connected to the ground plane. In this way, by controlling the switching of the switching unit 662, the metal long arm C2 can be switched to a different switching element 664. Since each switching element 664 has a different impedance, the frequency band of the second mode of the metal long arm C2 can be adjusted by the switching of the switching unit 662. The adjustment of the frequency band is to shift the frequency band to a low frequency or to a high frequency. The size of the appropriate inductance is adjusted by the first switching circuit 66, so that the LTE-A low-frequency mode can cover 703-804 MHz, 824-894 MHz, and 880-960 MHz frequency bands. The structure of the second switching circuit 67 is substantially the same as that of the first switching circuit 66. One end of the second switching circuit 67 is electrically connected to the third ground portion 58, and the other end is connected to the ground plane. It can be understood that the frequency of the first mode can be adjusted by adjusting the position where the first ground portion 53 is connected to the metal short arm C1. By adjusting the bending length of the first ground portion 53, the frequency of the matching and the first mode can be adjusted. It can be understood that the height of the third mode can be adjusted by adjusting the length of the extension 55. The longer the length of the extension 55, the lower the frequency of the third mode; otherwise, the length of the extension 55 is reduced. The frequency of the third mode can be increased.
所述輻射體56包括第四臂562、第五臂564及第六臂566。所述第四臂562大致垂直地連接至所述金屬背板512。所述第五臂564大致垂直地連接至第四臂562遠離金屬背板512的一端,且延伸方向與所述延伸段55的延伸方向相同,並間隔平行所述延伸段55,所述第五臂564延伸至所述USB連接器603的上方。所述第六臂566大致呈L形金屬條,其連接至所述第五臂564遠離第四臂562的一端,第六臂566由第五臂564向外延伸後折回相向第四臂562方向延伸,且間隔平行於第五臂564。所述第二饋入部57及第三接地部58均呈長條狀。所述第二饋入部57間隔且平行所述第四臂562設置,並連接至所述第五臂564。所述第三接地部58間隔且平行所述第二饋入部57,並連接至所述第五臂564。所述輻射體56從第二饋入部57饋入電流,激發一第四模態以產生第四頻段的輻射訊號。本實施例中,所述第四模態為LTE-A高頻模態,所述第四頻段為2300-2690MHz頻段。The radiator 56 includes a fourth arm 562, a fifth arm 564, and a sixth arm 566. The fourth arm 562 is substantially vertically connected to the metal back plate 512. The fifth arm 564 is substantially perpendicularly connected to an end of the fourth arm 562 away from the metal back plate 512, and the extending direction is the same as the extending direction of the extending section 55, and is parallel to the extending section 55 at intervals. The arm 564 extends above the USB connector 603. The sixth arm 566 is generally an L-shaped metal bar, which is connected to an end of the fifth arm 564 far from the fourth arm 562. The sixth arm 566 extends outward from the fifth arm 564 and then returns to the fourth arm 562. Extending and spaced parallel to the fifth arm 564. The second feeding portion 57 and the third grounding portion 58 are both elongated. The second feeding portion 57 is spaced from and parallel to the fourth arm 562 and is connected to the fifth arm 564. The third ground portion 58 is spaced apart from and parallel to the second feeding portion 57 and is connected to the fifth arm 564. The radiator 56 feeds a current from the second feeding portion 57 to excite a fourth mode to generate a radiation signal in a fourth frequency band. In this embodiment, the fourth mode is an LTE-A high-frequency mode, and the fourth frequency band is a 2300-2690 MHz frequency band.
本實施例中,為得到較佳的天線特性,所述開槽518的寬度可設置為3-4.5毫米,較佳地,可設置為3.9毫米,也即所述輻射段62距離金屬背板512設置為3.9毫米,以使得輻射段62遠離所述金屬背板512,以提升所述輻射段的天線效率。所述斷點5112、5114的寬度設置為1.5-2.5毫米,較佳地,可設置為2毫米,以在不影響所述天線結構500的整體外觀的情況下進一步提升所述輻射段的天線效率。所述金屬前框511的厚度可設置為1.5毫米,也即所述斷點5112、5114的厚度可設置為1.5毫米。In this embodiment, in order to obtain better antenna characteristics, the width of the slot 518 may be set to 3-4.5 mm, and preferably, 3.9 mm, that is, the radiating section 62 is 512 away from the metal back plate It is set to 3.9 mm so that the radiating section 62 is far away from the metal back plate 512 to improve the antenna efficiency of the radiating section. The width of the breakpoints 5112, 5114 is set to 1.5-2.5 mm, and preferably, 2 mm, to further improve the antenna efficiency of the radiating section without affecting the overall appearance of the antenna structure 500. . The thickness of the metal front frame 511 may be set to 1.5 mm, that is, the thickness of the breakpoints 5112 and 5114 may be set to 1.5 mm.
圖22為所述天線結構500工作時的電流走向示意圖。當電流自所述第一饋入部52進入所述輻射段62後,分別向兩側方向流動,其中一個方向為流經所述金屬短臂C1,並流向所述第一斷點5112及第一接地部53(參路徑P1),進而激發出所述第一模態。電流自所述第一饋入部52進入所述輻射段62後,向另一個方向為流經所述金屬長臂C2,並流向所述第二斷點5114(參路徑P2),進而激發出所述第二模態。另外,電流自所述第一饋入部52進入所述輻射段62後,向另一個方向為流經所述金屬長臂C2,並流向所述第二斷點5114,並進一步流向所述延伸段55(參路徑P3),進而激發出所述第三模態。當電流自所述第二饋入部57進入所述輻射體56後,沿輻射體56的延伸方向,並流經所述第三接地部58(參路徑P4),進而激發出所述第四模態。FIG. 22 is a schematic diagram of a current trend during operation of the antenna structure 500. After the current enters the radiating section 62 from the first feeding part 52, it flows to both sides, one of which flows through the metal short arm C1 and flows to the first break point 5112 and the first The ground portion 53 (see path P1) further excites the first mode. After the electric current enters the radiating section 62 from the first feeding part 52, it flows in the other direction through the metal long arm C2 and flows to the second break point 5114 (see path P2), and then excites The second mode is described. In addition, after the current enters the radiating section 62 from the first feeding part 52, the current flows through the metal long arm C2 in the other direction, flows to the second break point 5114, and further flows to the extended section. 55 (see path P3), and then the third mode is excited. After the current enters the radiator 56 from the second feeding part 57, it extends along the extending direction of the radiator 56 and flows through the third ground part 58 (see path P4), thereby exciting the fourth mode. state.
圖25為所述天線結構500工作於各頻段時的S參數(散射參數)曲線圖。FIG. 25 is a graph of S-parameters (scattering parameters) when the antenna structure 500 operates in various frequency bands.
圖26為所述天線結構500工作於各頻段時的輻射效率曲線圖。FIG. 26 is a radiation efficiency curve diagram of the antenna structure 500 when operating in various frequency bands.
顯然,所述天線結構500適用的工作頻率範圍涵蓋LTE-A低頻頻段(703-960 MHz)、LTE-A中頻頻段(1710-1990MHz)、LTE-A中頻頻段(2110-2170MHz)、LTE-A高頻頻段(2300-2690MHz),頻率範圍較廣,可應用於多種頻段的操作,且當所述天線結構500工作於上述頻段時,其工作頻率均可滿足天線工作設計要求,並具有較佳的輻射效率。Obviously, the applicable operating frequency range of the antenna structure 500 covers the LTE-A low frequency band (703-960 MHz), the LTE-A intermediate frequency band (1710-1990MHz), the LTE-A intermediate frequency band (2110-2170MHz), LTE -A high-frequency band (2300-2690MHz), with a wide frequency range, can be applied to a variety of frequency band operations, and when the antenna structure 500 operates in the above frequency band, its operating frequency can meet the antenna design requirements, and has Better radiation efficiency.
所述天線結構500通過設置所述金屬件51,且所述金屬件51上的開槽及斷點均設置於所述金屬前框511及金屬邊框513上,並未設置於所述金屬背板512上,使得所述金屬背板512構成全金屬結構,即所述金屬背板512上並沒有絕緣的開槽、斷線或斷點,使得所述金屬背板512可避免由於開槽、斷線或斷點的設置而影響金屬背板512的完整性和美觀性。The antenna structure 500 is provided with the metal piece 51, and the slots and breakpoints on the metal piece 51 are provided on the metal front frame 511 and the metal frame 513, but not on the metal back plate. 512, so that the metal back plate 512 constitutes an all-metal structure, that is, the metal back plate 512 does not have insulation slots, disconnections or break points, so that the metal back plate 512 can avoid The setting of lines or breakpoints affects the integrity and aesthetics of the metal back plate 512.
本發明的實施例1的天線結構100、實施例2的天線結構300和實施例3的天線結構500可應用在同一個無線通訊裝置。例如將天線結構100或天線結構300設置在該無線通訊裝置的上方作為副天線,並將天線結構500設置在該無線通訊裝置的下方作為主天線。當該無線通訊裝置發送無線訊號時,該無線通訊裝置使用所述主天線發送無線訊號。當該無線通訊裝置接收無線訊號時,該無線通訊裝置使用所述主天線與副天線一起接收無線訊號。The antenna structure 100, the antenna structure 300 of the embodiment 2 and the antenna structure 500 of the embodiment 3 of the present invention can be applied to the same wireless communication device. For example, the antenna structure 100 or the antenna structure 300 is disposed above the wireless communication device as a secondary antenna, and the antenna structure 500 is disposed below the wireless communication device as a main antenna. When the wireless communication device sends a wireless signal, the wireless communication device uses the main antenna to send a wireless signal. When the wireless communication device receives a wireless signal, the wireless communication device uses the primary antenna and the secondary antenna to receive the wireless signal together.
以上所述,僅為本發明的較佳實施例,並非是對本發明作任何形式上的限定。另外,本領域技術人員還可在本發明精神內做其它變化,當然,這些依據本發明精神所做的變化,都應包含在本發明所要求保護的範圍之內。The above descriptions are merely preferred embodiments of the present invention, and are not intended to limit the present invention in any form. In addition, those skilled in the art can make other changes within the spirit of the present invention. Of course, these changes made in accordance with the spirit of the present invention should be included in the scope of protection of the present invention.
100‧‧‧天線結構
11‧‧‧金屬件
111‧‧‧金屬前框
112‧‧‧金屬背板
113‧‧‧金屬邊框
114‧‧‧容置空間
115‧‧‧頂部
116‧‧‧第一側部
117‧‧‧第二側部
118‧‧‧開槽
1112‧‧‧第一斷點
1114‧‧‧第二斷點
1116‧‧‧第三斷點
1118‧‧‧第四斷點
22‧‧‧第一輻射段
24‧‧‧第二輻射段
26‧‧‧第三輻射段
A1‧‧‧金屬短臂
A2‧‧‧金屬長臂
12‧‧‧第一饋入部
27‧‧‧第一接地部
28‧‧‧第二接地部
13‧‧‧第二饋入部
15‧‧‧第一輻射體
152‧‧‧第三接地部
16‧‧‧第二輻射體
17‧‧‧第四饋入部
161‧‧‧第一輻射臂
162‧‧‧第二輻射臂
163‧‧‧第三輻射臂
164‧‧‧第四輻射臂
165‧‧‧第五輻射臂
166‧‧‧第四接地部
18‧‧‧第三輻射體
19‧‧‧第五饋入部
182‧‧‧第五接地部
20‧‧‧切換電路
222‧‧‧切換單元
224‧‧‧切換元件
200‧‧‧無線通訊裝置
201‧‧‧顯示單元
202‧‧‧後置雙鏡頭
203‧‧‧受話器
204、205‧‧‧開孔
207‧‧‧前置鏡頭
210‧‧‧電路板
實施例2
300‧‧‧天線結構
31‧‧‧金屬件
311‧‧‧金屬前框
312‧‧‧金屬背板
313‧‧‧金屬邊框
314‧‧‧容置空間
315‧‧‧頂部
316‧‧‧第一側部
317‧‧‧第二側部
318‧‧‧開槽
3112‧‧‧第一斷點
3114‧‧‧第二斷點
3116‧‧‧第三斷點
42‧‧‧第一輻射段
44‧‧‧第二輻射段
B1‧‧‧金屬短臂
B2‧‧‧金屬長臂
32‧‧‧第一饋入部
322‧‧‧第一臂
324‧‧‧第二臂
326‧‧‧第三臂
33‧‧‧第一接地部
34‧‧‧第二接地部
35‧‧‧第二饋入部
352‧‧‧第四臂
354‧‧‧第五臂
356‧‧‧第六臂
358‧‧‧第七臂
36‧‧‧第三接地部
37‧‧‧輻射體
38‧‧‧第三饋入部
39‧‧‧第四接地部
46‧‧‧第一切換電路
47‧‧‧第二切換電路
462‧‧‧切換單元
464‧‧‧切換元件
400‧‧‧無線通訊裝置
401‧‧‧顯示單元
402‧‧‧後置雙鏡頭
403‧‧‧受話器
404、405‧‧‧開孔
407‧‧‧前置鏡頭
410‧‧‧電路板
實施例3
500‧‧‧天線結構
51‧‧‧金屬件
511‧‧‧金屬前框
512‧‧‧金屬背板
513‧‧‧金屬邊框
514‧‧‧容置空間
515‧‧‧底部
516‧‧‧第一側部
517‧‧‧第二側部
518‧‧‧開槽
5182、5183‧‧‧開孔
5112‧‧‧第一斷點
5114‧‧‧第二斷點
62‧‧‧輻射段
C1‧‧‧金屬短臂
C2‧‧‧金屬長臂
52‧‧‧第一饋入部
53‧‧‧第一接地部
532‧‧‧第一臂
534‧‧‧第二臂
536‧‧‧第三臂
54‧‧‧第二接地部
55‧‧‧延伸段
56‧‧‧輻射體
562‧‧‧第四臂
564‧‧‧第五臂
566‧‧‧第六臂
57‧‧‧第二饋入部
58‧‧‧第三接地部
59‧‧‧饋入源
64‧‧‧匹配電路
641‧‧‧第一阻抗元件
642‧‧‧第二阻抗元件
643‧‧‧第三阻抗元件
644‧‧‧第四阻抗元件
645‧‧‧第五阻抗元件
66‧‧‧第一切換電路
67‧‧‧第二切換電路
662‧‧‧切換單元
664‧‧‧切換元件
600‧‧‧無線通訊裝置
601‧‧‧顯示單元
602‧‧‧耳機插座
603‧‧‧USB連接器
610‧‧‧電路板
100‧‧‧ Antenna Structure
11‧‧‧ metal parts
111‧‧‧ metal front frame
112‧‧‧metal back plate
113‧‧‧metal frame
114‧‧‧accommodation space
115‧‧‧Top
116‧‧‧First side
117‧‧‧ second side
118‧‧‧Slotted
1112‧‧‧First breakpoint
1114‧‧‧ Second breakpoint
1116‧‧‧ Third breakpoint
1118‧‧‧ Fourth breakpoint
22‧‧‧ the first radiation segment
24‧‧‧Second Radiation Section
26‧‧‧ The third radiation segment
A1‧‧‧ metal short arm
A2‧‧‧metal long arm
12‧‧‧First Feeding Department
27‧‧‧First ground
28‧‧‧ second ground
13‧‧‧Second Feeding Department
15‧‧‧ first radiator
152‧‧‧ third ground
16‧‧‧Second radiator
17‧‧‧Fourth Feeding Department
161‧‧‧The first radiation arm
162‧‧‧Second Radiation Arm
163‧‧‧The third radiation arm
164‧‧‧ Fourth Radiation Arm
165‧‧‧Fifth Radiation Arm
166‧‧‧ Fourth ground
18‧‧‧ third radiator
19‧‧‧ Fifth Feeding Department
182‧‧‧ fifth ground
20‧‧‧switching circuit
222‧‧‧Switch unit
224‧‧‧Switching element
200‧‧‧Wireless communication device
201‧‧‧display unit
202‧‧‧ rear dual camera
203‧‧‧ Receiver
204, 205‧‧‧ opening
207‧‧‧Front lens
210‧‧‧Circuit Board Example 2
300‧‧‧ Antenna Structure
31‧‧‧metal parts
311‧‧‧metal front frame
312‧‧‧metal back plate
313‧‧‧metal frame
314‧‧‧accommodation space
315‧‧‧Top
316‧‧‧first side
317‧‧‧second side
318‧‧‧Slotted
3112‧‧‧First breakpoint
3114‧‧‧ Second breakpoint
3116‧‧‧ Third breakpoint
42‧‧‧ the first radiation segment
44‧‧‧Second Radiation Section
B1‧‧‧metal short arm
B2‧‧‧metal long arm
32‧‧‧First Feeding Department
322‧‧‧First Arm
324‧‧‧ second arm
326‧‧‧ third arm
33‧‧‧First ground
34‧‧‧ second ground
35‧‧‧Second Feeding Department
352‧‧‧ Fourth Arm
354‧‧‧Fifth Arm
356‧‧‧ Sixth Arm
358‧‧‧ seventh arm
36‧‧‧ third ground
37‧‧‧ radiator
38‧‧‧ Third Feeding Department
39‧‧‧ Fourth ground
46‧‧‧first switching circuit
47‧‧‧Second Switching Circuit
462‧‧‧Switch unit
464‧‧‧switching element
400‧‧‧Wireless communication device
401‧‧‧display unit
402‧‧‧ rear dual camera
403‧‧‧ Receiver
404, 405‧‧‧ Opening
407‧‧‧Front lens
410‧‧‧Circuit Board Example 3
500‧‧‧ Antenna Structure
51‧‧‧metal parts
511‧‧‧ metal front frame
512‧‧‧metal back plate
513‧‧‧metal frame
514‧‧‧accommodation space
515‧‧‧ bottom
516‧‧‧first side
517‧‧‧second side
518‧‧‧Slotted
5182, 5183‧‧‧ Opening
5112‧‧‧First breakpoint
5114‧‧‧ Second breakpoint
62‧‧‧ Radiation Section
C1‧‧‧metal short arm
C2‧‧‧metal long arm
52‧‧‧First Feeding Department
53‧‧‧First ground
532‧‧‧first arm
534‧‧‧second arm
536‧‧‧ third arm
54‧‧‧Second ground section
55‧‧‧ extension
56‧‧‧ radiator
562‧‧‧ Fourth arm
564‧‧‧Fifth Arm
566‧‧‧ Sixth Arm
57‧‧‧Second Feeding Department
58‧‧‧ third ground
59‧‧‧feed source
64‧‧‧ matching circuit
641‧‧‧First impedance element
642‧‧‧Second impedance element
643‧‧‧Third impedance element
644‧‧‧Fourth impedance element
645‧‧‧Fifth impedance element
66‧‧‧first switching circuit
67‧‧‧Second switching circuit
662‧‧‧ switch unit
664‧‧‧Switching element
600‧‧‧Wireless communication device
601‧‧‧display unit
602‧‧‧Headphone socket
603‧‧‧USB connector
610‧‧‧Circuit Board
圖1為本發明第一實施例的天線結構應用至無線通訊裝置的示意圖。 圖2為圖1所示無線通訊裝置的組裝示意圖。 圖3為圖1所示無線通訊裝置另一角度下的組裝示意圖。 圖4為本發明第一實施例的天線結構中切換電路的電路圖。 圖5圖1所示天線結構工作時的電流走向圖。 圖6為圖1所示天線結構工作於LTE-A低頻模態、LTE-A中頻模態、LTE-A高頻模態及GPS模態時的回波損耗曲線圖。 圖7為圖1所示天線結構工作於WiFi 2.4G模態及WiFi 5G模態時的回波損耗曲線圖。 圖8為圖1所示天線結構工作於LTE-A低頻模態、LTE-A中頻模態、LTE-A高頻模態及GPS模態時的輻射效率圖。 圖9為圖1所示天線結構工作於WiFi 2.4G模態及WiFi 5G模態時的輻射效率圖。 圖10為本發明第二實施例的天線結構應用至無線通訊裝置的示意圖。 圖11為圖10所示無線通訊裝置的組裝示意圖。 圖12為圖10所示無線通訊裝置另一角度下的組裝示意圖。 圖13為本發明第二實施例的天線結構中切換電路的電路圖。 圖14圖10所示天線結構工作時的電流走向圖。 圖15為圖10所示天線結構工作於LTE-A低頻模態、LTE-A中頻模態、LTE-A高頻模態及GPS模態時的回波損耗曲線圖。 圖16為圖10所示天線結構工作於WiFi 2.4G模態及WiFi 5G模態時的回波損耗曲線圖。 圖17為圖10所示天線結構工作於LTE-A低頻模態、LTE-A中頻模態、LTE-A高頻模態及GPS模態時的輻射效率圖。 圖18為圖10所示天線結構工作於WiFi 2.4G模態及WiFi 5G模態時的輻射效率圖。 圖19為本發明第三實施例的天線結構應用至無線通訊裝置的示意圖。 圖20為圖19所示無線通訊裝置的組裝示意圖。 圖21為圖20所示無線通訊裝置部分組裝示意圖。 圖22為圖21所示天線結構工作時的電流走向圖。 圖23為本發明第三實施例的天線結構中匹配電路的電路圖。 圖24為本發明第三實施例的天線結構中切換電路的電路圖。 圖25為本發明第三實施例的天線結構工作時的S參數曲線圖。 圖26為本發明第三實施例的天線結構工作時的輻射效率圖。FIG. 1 is a schematic diagram of an antenna structure applied to a wireless communication device according to a first embodiment of the present invention. FIG. 2 is an assembly diagram of the wireless communication device shown in FIG. 1. FIG. 3 is an assembly diagram of the wireless communication device shown in FIG. 1 from another angle. FIG. 4 is a circuit diagram of a switching circuit in an antenna structure according to a first embodiment of the present invention. FIG. 5 is a current trend diagram of the antenna structure shown in FIG. 1 during operation. FIG. 6 is a graph of return loss when the antenna structure shown in FIG. 1 is operated in the LTE-A low frequency mode, the LTE-A intermediate frequency mode, the LTE-A high frequency mode and the GPS mode. FIG. 7 is a return loss curve diagram of the antenna structure shown in FIG. 1 when it operates in the WiFi 2.4G mode and the WiFi 5G mode. FIG. 8 is a radiation efficiency diagram when the antenna structure shown in FIG. 1 works in the LTE-A low-frequency mode, the LTE-A intermediate-frequency mode, the LTE-A high-frequency mode, and the GPS mode. FIG. 9 is a radiation efficiency diagram when the antenna structure shown in FIG. 1 works in a WiFi 2.4G mode and a WiFi 5G mode. FIG. 10 is a schematic diagram of an antenna structure applied to a wireless communication device according to a second embodiment of the present invention. FIG. 11 is an assembly diagram of the wireless communication device shown in FIG. 10. FIG. 12 is an assembly diagram of the wireless communication device shown in FIG. 10 from another angle. FIG. 13 is a circuit diagram of a switching circuit in an antenna structure according to a second embodiment of the present invention. FIG. 14 is a diagram of a current trend when the antenna structure shown in FIG. 10 works. FIG. 15 is a graph of return loss when the antenna structure shown in FIG. 10 is operated in the LTE-A low frequency mode, the LTE-A intermediate frequency mode, the LTE-A high frequency mode, and the GPS mode. FIG. 16 is a graph showing return loss curves of the antenna structure shown in FIG. 10 when the WiFi 2.4G mode and the WiFi 5G mode are operated. FIG. 17 is a radiation efficiency diagram when the antenna structure shown in FIG. 10 works in the LTE-A low-frequency mode, the LTE-A intermediate-frequency mode, the LTE-A high-frequency mode, and the GPS mode. FIG. 18 is a radiation efficiency diagram of the antenna structure shown in FIG. 10 when the WiFi 2.4G mode and the WiFi 5G mode are operated. FIG. 19 is a schematic diagram of an antenna structure applied to a wireless communication device according to a third embodiment of the present invention. FIG. 20 is an assembly diagram of the wireless communication device shown in FIG. 19. FIG. 21 is a partial assembly diagram of the wireless communication device shown in FIG. 20. FIG. 22 is a current trend diagram of the antenna structure shown in FIG. 21 during operation. FIG. 23 is a circuit diagram of a matching circuit in an antenna structure according to a third embodiment of the present invention. FIG. 24 is a circuit diagram of a switching circuit in an antenna structure according to a third embodiment of the present invention. FIG. 25 is an S-parameter curve diagram of the antenna structure in operation according to the third embodiment of the present invention. FIG. 26 is a radiation efficiency diagram of an antenna structure in operation according to a third embodiment of the present invention.
無no
100‧‧‧天線結構 100‧‧‧ Antenna Structure
1112‧‧‧第一斷點 1112‧‧‧First breakpoint
1114‧‧‧第二斷點 1114‧‧‧ Second breakpoint
1116‧‧‧第三斷點 1116‧‧‧ Third breakpoint
1118‧‧‧第四斷點 1118‧‧‧ Fourth breakpoint
22‧‧‧第一輻射段 22‧‧‧ the first radiation segment
24‧‧‧第二輻射段 24‧‧‧Second Radiation Section
26‧‧‧第三輻射段 26‧‧‧ The third radiation segment
A1‧‧‧金屬短臂 A1‧‧‧ metal short arm
A2‧‧‧金屬長臂 A2‧‧‧metal long arm
12‧‧‧第一饋入部 12‧‧‧First Feeding Department
27‧‧‧第一接地部 27‧‧‧First ground
28‧‧‧第二接地部 28‧‧‧ second ground
13‧‧‧第二饋入部 13‧‧‧Second Feeding Department
15‧‧‧第一輻射體 15‧‧‧ first radiator
152‧‧‧第三接地部 152‧‧‧ third ground
16‧‧‧第二輻射體 16‧‧‧Second radiator
17‧‧‧第四饋入部 17‧‧‧Fourth Feeding Department
161‧‧‧第一輻射臂 161‧‧‧The first radiation arm
162‧‧‧第二輻射臂 162‧‧‧Second Radiation Arm
163‧‧‧第三輻射臂 163‧‧‧The third radiation arm
164‧‧‧第四輻射臂 164‧‧‧ Fourth Radiation Arm
165‧‧‧第五輻射臂 165‧‧‧Fifth Radiation Arm
166‧‧‧第四接地部 166‧‧‧ Fourth ground
18‧‧‧第三輻射體 18‧‧‧ third radiator
19‧‧‧第五饋入部 19‧‧‧ Fifth Feeding Department
182‧‧‧第五接地部 182‧‧‧ fifth ground
210‧‧‧電路板 210‧‧‧Circuit Board
Claims (20)
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US201662365341P | 2016-07-21 | 2016-07-21 | |
US62/365341 | 2016-07-21 |
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CN108417969B (en) * | 2018-02-27 | 2024-02-27 | 厦门美图移动科技有限公司 | Antenna structure and electronic equipment |
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CN110767980B (en) | 2018-07-27 | 2021-11-02 | 深圳富泰宏精密工业有限公司 | Antenna structure and wireless communication device with same |
CN110838612B (en) * | 2018-08-17 | 2021-12-28 | 深圳富泰宏精密工业有限公司 | Antenna structure and wireless communication device with same |
CN111092292B (en) * | 2018-10-24 | 2022-10-11 | 荷兰移动驱动器公司 | Antenna structure and wireless communication device with same |
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TWI653784B (en) | 2019-03-11 |
CN107681250A (en) | 2018-02-09 |
CN107681251A (en) | 2018-02-09 |
TW201806240A (en) | 2018-02-16 |
CN107681249A (en) | 2018-02-09 |
TW201806235A (en) | 2018-02-16 |
TWI653783B (en) | 2019-03-11 |
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