tunable loop antennas

专利摘要:
LOOP TUNING ANTENNA. The present invention relates to electronic devices that are provided with and contain wireless communications circuitry. Wireless communications circuits can include radio frequency transceiver circuit and antenna structures. A parallel powered loop antenna can be formed from portions of a conductive bezel and a ground plane. The antenna can operate in multiple communication bands. The bezel can surround a peripheral portion of a display that is mounted in front of an electronic device. The bezel can contain a space. Antenna power terminals for the antenna can be located on opposite sides of the space. A variable capacitor can form a bridge in space. An inductive element can form a bridge between the space and the antenna feed terminals. A switchable inductor can be coupled in parallel with the inductive element. The tunable combination circuit can be coupled between one of the antenna power terminals and a conductor in a coaxial cable connecting the transceiver circuit to the antenna.
公开号:BR102012008299B1
申请号:R102012008299-3
申请日:2012-03-02
公开日:2021-05-25
发明作者:Nanbo Jin；Mattia Pascolini；Matt A. Mow；Robert W. Schlub；Ruben Caballero
申请人:Apple Inc.；
IPC主号:

专利说明:

This application claims priority to United States Patent Application No. 13/041,934, filed March 7, 2011, which is hereby incorporated by reference herein in its entirety. Background
The present invention relates generally to wireless communications circuits and more particularly to electronic devices having wireless communications circuits.
Electronic devices, such as portable electronic devices, are becoming increasingly popular. Examples of handheld devices include handheld computers, cell phones, media players, and hybrid devices that include the functionality of multiple devices of this type.
Devices such as these are often provided with wireless communications capabilities. For example, electronic devices can use long-range wireless communications circuits, such as cell phone circuits for communication using cell phone bands in 850 MHz, 900 MHz, 1800 MHz and 1900 MHz (for example, the Global System for Mobile Communications or GSM cell phone bands). Long-range wireless communications circuits can also handle the 2100 MHz band. Electronic devices can use short-range wireless communications links to handle communications with nearby equipment. For example, electronic devices can communicate using the WiFi® (IEEE 802.11) bands at 2.4 GHz and 5 GHz and the Bluetooth® band at 2.4 GHz.
To satisfy consumer demand for small form-factor wireless devices, manufacturers are continually striving to implement wireless communications circuits, such as antenna components, using compact structures. However, it can be difficult to fit conventional antenna structures into small devices. For example, antennas that are confined to small volumes often exhibit narrower operating bandwidths than antennas that are deployed in larger volumes. If the bandwidth of an antenna becomes too small, the antenna will not be able to cover all of the communications bands of interest In view of these considerations, it would be desirable to provide improved wireless circuitry for electronic devices. summary
Electronic devices may be provided which include antenna structures. An antenna may be configured for operation in a first and a second communication band. An electronic device may contain a radio frequency transceiver circuit that is coupled to the antenna using a transmission line. The transmission line can have a positive conductor and a ground conductor The antenna can have a positive antenna power terminal and a ground antenna power terminal to which the positive and ground conductors of the transmission line are coupled, respectively.
The electronic device may have a rectangular periphery. A rectangular display can be mounted on a front face of the electronic device. The electronic device may have a rear face which is formed from a plastic housing member. Conductive sidewall structures can rotate around the periphery of the electronic device housing and display Conductive sidewall structures can serve as a bevel for the display.
The bezel can include at least one space. The space can be filled with a solid dielectric, such as plastic. The antenna can be formed from the portion of the bezel that includes the space and a portion of a ground plane. be powered using a power arrangement that reduces the concentration of electric field in the vicinity of the space. 3Q An inductive element can be formed in parallel with the antenna feed terminals, whereas a capacitive element can be formed in series with one of the antenna feed terminals.
The inductive element can be formed from an inductive transmission line structure that bridges the antenna feed terminals. The capacitive element can be formed from a capacitor that is interposed in the positive feed path to the antenna. The capacitor can be connected, for example, between the positive ground conductor of the transmission line and the positive antenna supply terminal.
A switchable inductor circuit can be coupled in parallel with the inductive element. A tunable combination circuit can also be interposed in the positive supply path to the antenna (eg the tunable combination circuit can be connected in series with the capacitive element). A variable capacitor circuit can form a bridge in space. The switching inductor circuit, tunable combination circuit, and variable capacitor serve as an antenna tuning circuit that can be used to allow the antenna to resonate in different frequency bands.
A wireless device formed using this arrangement may be operable in first and second modes. In the first mode, the switchable inductor circuit can be tuned to allow the wireless device antenna to operate in a first low-band region and a high-band region. In the second mode, the switchable inductor circuit can be disabled to allow the wireless device's antenna to operate in a second low-band region and in the high-band region. The first and second lowband regions may or may not overlap in frequency.
The switchable inductor circuit can be configured to provide the desired subband coverage in a selected band region. The variable capacitor circuit can be tuned to fine tune the frequency characteristic of the looped antenna. Other features of the invention, its nature and various advantages will be more apparent from the associated drawings and the following detailed description of preferred embodiments. Brief Description of Drawings
Figure 1 is a perspective view of an illustrative electronic device with a wireless communications circuit in accordance with an embodiment of the present invention.
Figure 2 is a schematic diagram of an illustrative electronic device having a wireless communications circuit in accordance with an embodiment of the present invention.
Figure 3 is an end cross-sectional view of an illustrative electronic device having a wireless communications circuit in accordance with an embodiment of the present invention.
Figure 4 is a diagram of an illustrative antenna in accordance with an embodiment of the present invention.
Figure 5 is a schematic diagram of an illustrative series powered loop antenna that may be used in an electronic device in accordance with an embodiment of the present invention.
Figure 6 is a graph showing how an electronic device antenna can be configured to display coverage in multiple communication bands in accordance with an embodiment of the present invention.
Figure 7 is a schematic diagram of an illustrative parallel powered loop antenna that may be used in an electronic device in accordance with an embodiment of the present invention.
Figure 8 is a diagram of an illustrative parallel feed loop antenna with an inductance interposed in the loop in accordance with an embodiment of the present invention.
Figure 9 is a diagram of an illustrative parallel powered loop antenna having an inductive transmission line structure in accordance with an embodiment of the present invention.
Figure 10 is a diagram of an illustrative parallel feed loop antenna with an inductive transmission line structure and a series-connected capacitive element in accordance with an embodiment of the present invention.
Figure 11 is a Smith graph illustrating the performance of various electronic device loop antennas in accordance with embodiments of the present invention.
Figure 12 is a graph showing the tradeoffs between antenna gain and bandwidth for a given antenna volume.
Figure 13 is a diagram of an illustrative parallel feed loop antenna with a tunable antenna circuit in accordance with an embodiment of the present invention.
Figure 14 is a circuit diagram of an illustrative tunable combination circuit of the type that may be used in connection with the antenna of Figure 13 in accordance with an embodiment of the present invention.
Figure 15 is a circuit diagram of an illustrative switchable inductor circuit of the type that may be used in connection with the antenna of Figure 13 in accordance with an embodiment of the present invention.
Figure 16 is a circuit diagram of an illustrative variable capacitor circuit of the type that may be used in communication with the antenna of Figure 13 in accordance with an embodiment of the present invention.
Figure 17 is a graph showing how the lowband portions of the antenna of Figure 13 can be used to cover multiple communications bands of interest using the tunable antenna combination circuit in accordance with an embodiment of the present invention. Detailed Description
Electronic devices may be provided with a wireless communications circuit. The wireless communications circuit can be used to support wireless communications in multiple bands of wireless communications. The wireless communications circuit can include one or more antennas.
Antennas can include loop antennas. Conductive structures for a loop antenna, if desired, can be formed from conductive electronic device structures. Conductive electronic device structures can include conductive housing structures. Housing structures can include a conductive bezel. Space structures can be formed on the conductive bevel. The antenna can be powered in parallel using a configuration that helps to minimize the sensitivity of the antenna to contact with a user's hand or other external object.
Any suitable electronic devices can be provided with a wireless circuit that includes looped antenna structures. As an example, looped antenna structures can be used in electronic devices such as desktop computers, game consoles, routers, laptop computers, etc. With a proper configuration, loop antenna structures are provided in relatively compact electronic devices where indoor space is relatively valuable, such as portable electronic devices.
An illustrative portable electronic device in accordance with an embodiment of the present invention is shown in Figure 1. Portable electronic devices such as illustrative portable electronic device 10 may be laptop computers or small portable computers such as ultra-portable computers, netbook computers and tablet computers. Portable electronic devices can also be somewhat small devices. Examples of small portable electronic devices include wristwatch devices, pendant devices, headphone and earphone devices, and other miniature, wearable devices. Properly arranged, portable electronic devices are handheld electronic devices such as cell phones.
Space is a precious commodity in portable electronic devices. Conductive structures are also typically present, which can make efficient antenna operation challenging. For example, conductive housing structures may be present around some or all of the periphery of a portable electronic device housing.
In portable electronic device housing arrangements such as these, it may be particularly advantageous to use loop-type antenna designs that cover communications bands of interest. The use of portable devices such as handheld devices is therefore sometimes described here as an example, although any suitable electronic device can be provided with loop antenna structures if desired.
Handheld devices can be, for example, cell phones, media players with wireless communications capabilities, handheld computers (sometimes also called personal digital assistants), remote controllers, global positioning system (GPS) devices, and gaming devices portable. Handheld devices and other portable devices, if desired, can include the functionality of multiple conventional devices. Examples of multifunction devices include mobile phones that include media player functionality, gaming devices that include wireless communications capabilities, mobile phones that include gaming and email functions, and handheld devices that receive email support mobile phone calls, and support web browsing. These are merely illustrative examples. Device 10 of Figure 1 can be any portable or handheld electronic device.
Device 10 includes a housing 12 and includes at least one antenna for handling wireless communications. Housing 12, which is sometimes referred to as a case, can be formed of any suitable materials, including plastic, glass, ceramic, composites, metals or other suitable materials, or a combination of these materials. In some situations, housing portions 12 may be formed from a dielectric material or other low conductivity material so that the operation of the conductive antenna elements that are located within housing 12 is not disturbed. In other situations, housing 12 may be formed from metal elements.
Device 10, if desired, may have a display, such as display 14. Display 14 may be, for example, a touch screen that incorporates capacitive touch electrodes. Display 14 can include image pixels formed from light emitting diodes (LEDs), organic LEDs (OLEDs), plasma cells, electronic ink elements, liquid crystal display (LCD) components, or other pixel structures of suitable image. A cover glass member can cover the surface of the display 14. Buttons, such as the knob19, can pass through openings in the cover glass.
Housing 12 can include sidewall structures, such as sidewall structures 16. Structures 16 can be implemented using conductive materials. For example, frames 16 can be implemented using a conductive ring member that substantially surrounds the rectangular periphery of display 14. Frames 16 can be formed from a metal, such as stainless steel, aluminum, or other materials. suitable. One, two, or more than two separate frames can be used in forming frames 16. Frames 16 can serve as a bezel that holds display 14 on the front (top) face of device 10. Frames 16 are referred to herein, sometimes as bevel 16 or bevel 16 structures. Bevel 16 runs around the rectangular periphery of device 10 and display 14.
The bevel 16 can have a thickness (TT dimension) around 15 0.1 mm to 3 mm (as an example). The bevel sidewall portions 16 may be substantially vertical (parallel to the vertical axis V). Parallel to the vertical geometric axis V, the bevel 16 can have a TZ dimension around 1 mm to 2 cm (as an example). The aspect ratio of bevel 16 (i.e., from TZ to TT) is typically more than 1 (i.e., 20 R can be greater than or equal to 1, greater than or equal to 2, greater than or equal to 4, greater than or equal to 10, etc.).
It is not necessary for the bezel 16 to have a uniform cross section. For example, the top portion of the bezel 16, if desired, can have an inwardly projecting ferrule that helps to hold the display 14 in place. If desired, the bottom portion of the bezel 16 may also have an enlarged ferrule (for example, in the plane of the rear surface of the device 10). In the example of Figure 1, the bezel 16 has substantially straight vertical side walls. This is for illustrative purposes only. The bevel side walls 16 can be curved or can be of another suitable shape. The display 14 includes conductive structures, such as an array of capacitive electrodes, conductive lines for addressing pixel elements, driver circuits, etc. These conductive structures tend to block radio frequency signals. Therefore, it may be desirable to form part or all of the flat rear surface of the device from a dielectric material such as a plastic.
Bevel portions 16 can be supplied with 5 space frames. For example, bezel 16 may be provided with one or more spaces, such as space 18, as shown in Figure 1. Space 18 is along the periphery of device housing 10 and display 12 and therefore sometimes is referred to as a peripheral space. Space 18 divides bevel 16 (i.e. there is generally no conductive portion of bevel 16 in space 18). As shown in Figure 1, space 18 can be filled with a dielectric. For example, space 18 can be filled with air. To help provide a device 10 with a smooth uninterrupted appearance and to ensure that the bezel 16 is aesthetically appealing, the space 18 can be filled with a solid (not air) dielectric, such as a plastic. 15 Bevel 16 and spaces such as space 18 (and its associated plastic filling structure) may form part of one or more antennas in device 10. For example, bevel portions 16 and spaces such as space 18, together with the internal conductive structures, form one or more looped antennas. Internal conductive structures may include printed circuit board structures, frame members or other support structures, or other suitable conductive structures.
In a typical scenario, device 10 might have top and bottom antennas (as an example). An upper antenna, for example, may be formed at the upper end of device 10 in region 22. A lower antenna, for example, may be formed at the lower end of device 10 in region 20.
The lower antenna, for example, can be formed partially from portions of bevel 16 in the vicinity of space 18.
The antennas in device 10 can be used to support any communications bands of interest. For example, device 10 may include antenna structures to support local area network communications, cell phone voice and data communications, global positioning system (GPS) communications, Bluetooth® communications, etc. As an example, the lower antenna in region 20 of device 10 can be used in handling voice and data communications in one or more cell phone bands.
A schematic diagram of an illustrative electronic device is shown in Figure 2. The device 10 of Figure 2 may be a portable computer, such as a portable tablet computer, a mobile phone, a mobile phone with media player capabilities, a computer handheld, a remote control, a gaming device, a global positioning system (GPS) device, a combination of these devices, or any other suitable portable electronic device.
As shown in Figure 2, the portable device 10 may include a storage and processing circuit 28. The storage and processing circuit 28 may include a storage, such as a storage on a hard disk drive, a non-volatile memory. (eg, flash memory or other electrically programmable read-only memory configured to form a solid state drive), volatile memory (eg static or dynamic random access memory), and so on. A processing circuit in the storage and processing circuit 28 can be used to control the operation of the device 10. This processing circuit can be based on one or more microprocessors, microcontrollers, digital signal processors, specific integrated circuits of application, etc. The storage and processing circuit 28 can be used for running software on the device 10, such as internet browsing applications, voice over internet protocol (VOIP) phone call applications, email applications, media execution applications, operating system functions, etc. To support interactions with external equipment, the storage and processing circuit 28 can be used in the implementation of communications protocols. Communications protocols that can be implemented using the storage and processing circuit28 include internet protocols, wireless local area network protocols (eg IEEE 802.11 protocols - sometimes referred to as WiFi®), protocols for other wireless communications links range, such as Bluetooth® protocol, cell phone protocols, etc.
Input-output circuitry 30 can be used to allow data to be suppressed to device 10 and to allow data to be supplied from device 10 to external devices. The 32 input - output devices such as touch screens and other user input interface are examples of the 32 input - output circuit. The 10 input - output 32 devices may also include input - output devices such as buttons , joysticks, click wheels, scroll wheels, touchpads, mini keyboards, keyboards, microphones, cameras, etc. A user can control the operation of device 10 by supplying commands through these user input devices. Display and audio devices, such as display 14 (figure 1) and other components that present visual information and status data, can be included in devices 32. Display and audio components in input devices - 32 output may also include audio equipment such as speakers and other devices for creating sound. If desired, the input-output 32 devices may contain audio-video interface equipment, such as jacks and other connectors for external headphones and monitors.
Wireless communications circuit 34 may include a radio frequency (RF) transceiver circuit from one or more integrated circuits 25, an operating environment circuit, low noise input amplifiers, passive RF components, a or more antennas, and other circuitry to handle wireless RF signals. Wireless signals can also be sent using light (for example, using infrared communications). Wireless communications circuit 34 may include radio frequency transceiver circuitry 30 to handle multiple bands of radio frequency communications. Examples of cell phone standards that can be supported by wireless circuit 34 and device 10 include: the Global System for Mobile Communications (GSM) “2G” cell phone standard; the Enhanced Data Evolution (EVDO) cell phone standard, the Universal Mobile Telecommunications System (UMTS) “3G” cell phone standard, the Code Division Multiple Access cell phone standard 2000 (CDMA 2000) “ 3G”, and the 3GPP Long Term Evolution (LTE) cell phone standard. Other cell phone standards can be used if desired. These cell phone patterns are for illustrative purposes only.
Wireless communications circuit 34 may include circuitry for other short-range and long-range wireless links, if desired. For example, wireless communications circuit 34 may include a global positioning system (GPS) receiving equipment, a wireless circuit for receiving radio and television signals, radio paging circuits, etc. On WiFi® and Bluetooth® links and other short-range wireless links, wireless signals are typically used to carry data for tens or hundreds of feet (1 ft = 0.3048 m). On cell phone links and other long-range links, wireless signals are typically used to carry data thousands of feet or miles (1 ft = 0.3048 m; 1 mile = 1609 km).
Wireless communications circuit 34 can include antennas 40. Antennas 40 can be formed using any suitable types of antenna. For example, antennas 40 can include antennas with resonant elements that are formed from a loop antenna structure, patch antenna structures, inverted F antenna structures, slot antenna structures, flat inverted F antenna structures. , helical antenna structures, hybrids of these designs, etc. Different types of antenna can be used for different bands and band combinations. For example, one type of antenna can be used to form a local wireless link antenna and another type of antenna can be used to form a remote wireless link.
With a suitable arrangement, which is sometimes described here as an example, the lower antenna on device 10 (ie, an antenna 40 located in region 20 of device 10 of Figure 1) can be formed using a loop-type antenna design. When a user holds device 10, the user's fingers can contact the exterior of device 10. For example, the user can touch device 10 in region 20. To ensure that the antenna performance is not overly sensitive to the presence or absence of a touch or user contact by other external objects, the loop antenna can be powered using an arrangement that does not excessively concentrate electric fields in the vicinity of the space 18.
A side cross-sectional view of the device 10 of Figure 1, taken along line 24-24 in Figure 1 and viewed in direction 26 is shown in Figure 3. As shown in Figure 3, the display 14 can be mounted on the front surface. of device 10 using a bezel 16. Housing 12 may include sidewalls formed from bezel 16 and one or more rear walls formed from frames, such as a flat rear housing frame 42. Frame 42 may be formed to from a dielectric, such as a plastic, or other materials. Brackets, clips, screws, stickers and other structures can be used in affixing bezel 16 to display 14 and rear housing wall frame 42.
Device 10 may contain printed circuit boards, such as printed circuit board 46. Printed circuit board 46 and the other printed circuit boards in device 10 may be formed from a rigid printed circuit board material ( eg epoxy filled with fiberglass) or flexible sheets of material such as polymers. Flexible printed circuit boards ("flexible circuits") can be formed, for example, from flexible sheets of polyimide.
Printed circuit board 46 can contain interconnects, such as interconnects 48. Interconnects 48 can be formed from conductive traces (e.g., traces of copper coated with gold or other metals). Connectors, such as connector 50, can be connected to interconnections 48 using solder or a conductive adhesive (as examples). Integrated circuits, discrete components, such as resistors, capacitors, and inductors, and other electronic components, can be mounted in the printed circuit board 46.
Antenna 40 may have antenna feed terminals. For example, antenna 40 may have a positive antenna feed terminal, such as positive antenna feed terminal 58, and a ground antenna feed terminal, such as a ground antenna feed terminal. 54. In the illustrative arrangement of Figure 3, a transmission line path, such as a coaxial cable 52, may be coupled between the antenna feed formed from terminals 58 and 10 54 and a transceiver circuit in components 44 through the connector 50 and interconnections 48. Components 44 may include one or more integrated circuits that implement transceiver circuits 36 and 38 of Figure 2. Connector 50 may be, for example, a coaxial cable connector that is connected to the circuit board. printed circuit 46. Cable 52 may be a coaxial cable or other transmission line. Terminals 58 can be coupled to coaxial cable center connector 56. Terminal 54 can be connected to a ground conductor on cable 52 (e.g., an outer braided conductor). Other arrangements can be used for coupling transceivers in device 10 to antenna 40, if desired. The arrangement of Figure 3 is merely illustrative.
As the cross-sectional view of Figure 3 makes clear, the housing side walls 12 which are formed by the bevel 16 can be relatively tall. At the same time, the amount of area that is available for forming an antenna in region 20 at the lower end 25 of device 10 can be limited, particularly in a compact device. The compact size that is desired from antenna formation can make it difficult to form a slot-like antenna shape of sufficient size to be resonant in the desired communications bands. The shape of the bevel 16 may tend to reduce the efficiency of conventional flat inverted-F antennas. Challenges such as these, if desired, can be addressed using a loop-type design for antenna 40.
Consider, as an example, the antenna arrangement in Figure 4.
As shown in Figure 4, antenna 40 may be formed in region 20 of device 10. Region 20 may be located at the lower end of device 10, as described in relation to Figure 1. Conductive region 68, which can sometimes be referred to as a grounding plane or a grounding plane element, it can be formed from one or more conductive structures (e.g., flat conductive traces on printed circuit board 46, internal structural members on device 10, components electrics 44 on board 46, radio frequency shield boxes mounted on board 46, etc.) The conductive region 68 in region 66 is sometimes referred to as forming a "grounding region" for the antenna 40. The conductive structures 70 of Figure 4 can be formed by bevel 16. Regions 70 are sometimes referred to as the ground plane extensions. Space 18 can be formed in this conductive bevel portion (as shown in Figure 1).
The ground plane extensions 70 (i.e., the bevel portions 16) and the region portions 68 that lie along the edge 76 of the ground region 68 form a conductive loop around the opening 72. The opening 72 may be formed from air, plastic or other solid dielectric. If desired, the contour of opening 72 can be curved, can have more than four straight segments, and/or can be defined by the contours of the conductive components. The rectangular shape of the dielectric region 72 in Figure 4 is merely illustrative.
The conductive structures of Figure 4, if desired, can be powered by coupling the radio frequency transceiver 60 through the ground antenna feed terminal 62 and the positive antenna feed terminal 64. As shown in Figure 4, in this type of arrangement, the feed to the antenna 40 is not located in the vicinity of the space 18 (i.e. the feed terminals 62 and 64 are located to the left of the laterally centered dividing line 74 of the opening 72, while the space 18 is located to the right of the division line 74 along the right side of the device 10). Although this type of arrangement may be satisfactory in many situations, antenna feed arrangements which locate the antenna feed terminals at terminal locations 62 and 64 of Figure 4 tend to accentuate the electric field strength of the radio frequency antenna signals in the vicinity. of space 18. If a user happens to place an external object such as a finger 80 in the vicinity of space 18 by moving finger 80 in direction 78 (for example, when holding device 10 in the user's hand), the presence of the User's finger may disturb the operation of the antenna 40.
To ensure that antenna 40 is not overly sensitive to touch (i.e., to desensitize antenna 40 to touch events involving the device 10 user's hand and other external objects), antenna 40 can be powered using power supply terminals. antenna located in the vicinity of space 18 (for example, where shown by positive antenna feed terminal 58 and ground antenna feed terminal 54 in the example of Figure 4). When the antenna feed is located to the right of line 74, and more particularly when the antenna feed is located near space 18, the electric fields that are produced in space 18 tend to be reduced. This helps to minimize the sensitivity of antenna 40 to the presence of the user's hand, ensuring satisfactory operation regardless of whether or not an external object is in contact with device 10 in the vicinity of space 18.
In the arrangement of Figure 4, antenna 40 is being fed in series. A schematic diagram of a series-powered loop antenna of the type shown in Figure 4 is shown in Figure 5. As shown in Figure 5, the series-powered loop antenna 82 may have a conductive path in a loop shape, such as the loop 84. A transmission line composed of a positive transmission line conductor 86 and a ground transmission line conductor 88 can be coupled to antenna feed terminals 58 and 54, respectively.
It can be challenging to effectively use a series-fed power supply arrangement of the type shown in figure 5 to power a multi-band loop antenna. For example, it may be desired to operate a loop antenna in a lower frequency band that covers the GSM subbands at 850 MHz and 900 MHz and a higher frequency band covering the GSM subbands at 1800 MHz and 1900 MHz and the data subband at 2100 MHz. This type of arrangement can be considered to be a dual band arrangement (eg 850/900 for the first band and 1800 / 1900 / 2100 for the second band), or can be considered to have five bands (850, 900, 1800, 1900 and 2100). In multiband arrangements such as these, serially powered antennas, such as loop antenna 82 of Figure 5, may exhibit substantially better impedance combination in the high frequency communications band than in the low frequency communications band. .
A graph of permanent wave ratio (SWR) versus frequency illustrating this effect is shown in Figure 6. As shown in Figure 6, the SWR 90 graph can display a satisfactory resonant peak (peak 94) in the high frequency band f2 ( for example, to cover the 1800 MHz, 1900 MHz and 2100 MHz subbands). The SWR 90 graph, however, may exhibit relatively poor performance in the low frequency band centered on frequency f1 when antenna 40 is fed in series. For example, the SWR 90 plot for the series-powered loop antenna 82 of Figure 5 can be characterized by the weak resonant peak 96. As this example demonstrates, series-powered loop antennas can provide a satisfactory impedance combination for the transmission line 52 (figure 3) in the higher frequency band at f2, but cannot provide a satisfactory impedance combination for transmission line 52 (figure 3) in the lower frequency band f1.
A more satisfying level of performance (illustrated by the low-band resonant peak 92) can be achieved using a powered-in parallel arrangement with appropriate impedance-matching capabilities.
An illustrative parallel powered loop antenna is shown schematically in Figure 7. As shown in Figure 7, a parallel powered loop antenna 90 may have a conductor loop, such as a loop 92. The loop 92 in the example of Figure 7 is shown as being circular. This is for illustrative purposes only. Loop 92 can have other shapes if desired (eg rectangular shapes, shapes with both curved and straight sides, shapes with irregular edges, etc.). The TL transmission line may include a positive signal conductor 94 and a ground signal conductor 96. Paths 94 and 96 may be contained in coaxial cables, microstrip transmission lines or flexible circuits and rigid printed circuit boards, etc. . Transmission line TL can be coupled to antenna feed 90 using a positive antenna feed terminal 58 and a ground antenna feed terminal 54. Electrical element 98 can bridge terminals 58 and 54, thereby "closing" the loop formed by path 92. When the loop is closed in this way, element 98 is interposed in the conductive path that forms loop 92. The impedance of loop antennas fed in parallel, such as loop antenna 90 of the Figure 7, can be adjusted by the proper selection of element 98 and, if desired, other circuits (for example, capacitors or other elements interposed in one of the supply lines, such as line 94 or line 96).
Element 98 can be formed from one or more electrical components. Components that can be used as all or part of element 98 include resistors, inductors, and capacitors. Desired resistances, inductances and capacitances for element 98 can be formed using integrated circuits, using discrete components, and/or using dielectric and conductive structures that are not part of a discrete component or an integrated circuit. For example, a resistor can be formed using thin lines of a resistive metal alloy, a capacitance can be formed by spacing two conductive shims close together so that they are separated by a dielectric, and an inductance can be formed by creating a dielectric path on a printed circuit board. These types of structures can be referred to as resistors, capacitors and/or inductors, or they can be referred to as capacitive antenna feed structures, resistive antenna feed structures and/or inductive antenna feed structures.
An illustrative configuration for antenna 40 in which component 98 of the schematic diagram of Figure 7 has been implemented using an inductor is shown in Figure 8. As shown in Figure 8, loop 925 (Figure 7) can be implemented using the conductive regions 70 and the conductive portions of region 68 running along edge 76 of opening 72. The antenna 40 of Figure 8 can be powered using the positive antenna feed terminal 58 and the ground antenna feed terminal 54. The terminals 54 and 58 may be located in the view of space 18 to reduce electric field concentrations in space 18 and thereby reduce the sensitivity of antenna 40 to touch events.
The presence of inductor 98 can help, at least partially, in matching the impedance of transmission line 52 with antenna 40. If desired, inductor 98 can be formed using a discrete component, such as an inductor of mounting technology. surface (SMT). The inductance of inductor 98 can also be implemented using an arrangement of the type shown in figure 9. With the configuration of figure 9, the antenna loop conductor in parallel supply loop 40 can have an inductive segment SG that runs. parallel to the GE ground plane edge. The SG segment can be, for example, a conductive trace on a printed circuit board or other conductive member. A dielectric opening DL (for example, an opening filled with air or filled with plastic) can separate the ground edge GE portion 68 from the segment 25 SG from the conductive loop portion 70. The segment SG can have a length in the shape of L. Segment SG and associated ground GE form a transmission line with an associated inductance (ie, segment SG and ground GE form inductor 98). Inductor inductance 98 is connected in parallel with power terminals 54 and 58 30 and therefore forms a parallel inductive tuning element of the type shown in figure 8. Due to the fact that inductive element 98 of figure 9 is Formed using a transmission line structure, the inductive element 98 of Figure 9 can introduce less losses into the antenna 40 than arrangements in which a discrete inductor is used to bridge the supply terminals. For example, a transmission line inductive element 98 can preserve high-band performance (illustrated as the satisfying resonant peak 94 of Fig. 6), whereas a discrete inductor could reduce high-band performance.
Capacitive tuning can also be used to improve impedance matching for antenna 40. For example, capacitor 100 of Figure 10 can be connected in series with center conductor 56 of coaxial cable 52 or other suitable arrangements can be used for the introduction of a series capacitance in the antenna supply. As shown in Figure 10, capacitor 100 may be interposed on the coaxial cable center conductor 56 or other conductive structures that may be interposed between the transmission line end 52 and the positive antenna power terminal 58. Capacitor 100 may be formed by one or more discrete components (eg, SMT components), one or more capacitive structures (eg, superimposed printed circuit board traces that are separated by a dielectric, etc.), lateral spaces between conductive traces on printed circuit boards or other substrates, etc.
The conductive loop for the loop antenna 40 of Figure 10 is formed by conductive structures 70 and the conductive portions of conductive ground structures 66 along edge 76. Loop currents can also pass through other ground plane portions 68. as illustrated by current paths 102. Positive antenna supply terminal 58 is connected to one end of the loop path and ground antenna supply terminal 54 is connected to the other end of the loop path. Inductor 98 forms a bridge between terminals 54 and 58 of antenna 40 of Figure 10 so that antenna 40 forms a loop antenna fed in parallel with a bridging inductance (and a capacitance in series from of the capacitor 100).
During an operation of antenna 40, a variety of current paths 102 of different lengths can be formed across the ground plane 68. This can help to broaden the frequency response of antenna 40 in bands of interest. The presence of tuning elements such as parallel inductance 98 and series capacitance 100 can help form an efficient impedance matching circuit for antenna 40, which allows antenna 40 to operate efficiently in high and low bands (e.g. , such that antenna 40 exhibits a high-band resonance peak 94 of Fig. 6 and a low-band resonance peak 92 of Fig. 6).
A simplified Smith graph showing the possible impact of tuning elements, such as inductor 98 and capacitor 100 of figure 10, on the parallel feed loop antenna 40 is shown in figure 11.0 Y point in the center of graph 104 represents the transmission line impedance 52 (for example, a coaxial cable impedance of 50 Ohms with which the antenna 40 is to be combined). Configurations in which antenna impedance 40 is close to the Y point in both the low and high bands will exhibit satisfactory operation.
With the parallel powered antenna 40 of Figure 10, the highband combination is relatively insensitive to the presence or absence of inductive element 98 and capacitor 100. However, these components can significantly affect the lowband impedance. Consider, as an example, an antenna configuration without inductor 98 or capacitor 100 (ie, a parallel-powered loop antenna of the type shown in figure 4). In this type of configuration, the low band (for example, the band at frequency f1 in figure 6) can be characterized by an impedance represented by point X1 in graph 104. When an inductor, such as a parallel inductance 98 of figure 9, is added to the antenna, the lowband antenna impedance can be characterized by point X2 of graph 104. When a capacitor such as capacitor 100 is added to the antenna, the antenna can be configured as shown in figure 10. type of configuration, the antenna impedance40 can be characterized by point X3 of graph 104.
At point X3, antenna 40 is well matched with cable impedance 50 in both the high band (frequencies centered around frequency f2 in figure 6) and low band (frequencies centered around frequency f1 in figure 6). This can allow antenna 40 to support the desired communications bands of interest. For example, this combination arrangement can allow antennas, such as antenna 40 of Figure 10, to operate in bands such as the 850 MHz and 900 MHz communications bands (collectively forming the lowband region at frequency f1) and the communications bands at 1800 MHz, 1900 MHz and 2100 MHz (collectively forming the highband region at frequency f2).
Furthermore, the placement of the X3 point helps to ensure that a tune-out due to touch events is minimized. When a user touches housing 12 of device 10 in the vicinity of antenna 40, or when other external objects are brought into close proximity with antenna 40, these external objects affect the antenna impedance. In particular, these external objects may tend to introduce a capacitive impedance contribution to the antenna impedance. The impact of this type of contribution to the antenna impedance tends to move the antenna impedance from point X3 to point X4, as illustrated by line 106 of graph 104 in figure 11. Due to the original location of point X3, point X4 does not is too far away from the optimal point Y. As a result, antenna 40 can exhibit satisfactory operation under a variety of conditions (eg, when device 10 is being touched, when device 10 is not being touched, etc.).
Although the diagram in Figure 11 represents impedances as points for various antenna configurations, antenna impedances are typically represented by a collection of points (for example, a curved line segment in graph 104), due to the frequency dependence of the impedance of antenna. The general behavior of graph 104, however, is representative of the behavior of the antenna at the frequency of interest. The use of curved line segments to represent frequency-dependent antenna impedances has been omitted from Figure 11 to avoid overcomplicating the design.
Antenna 40 of the type described with respect to Figure 10 may be capable of supporting wireless communications in the first and second radio frequency bands (see, for example, Figure 6). For example, antenna 40 may be operable in a lower frequency band covering the GSM subbands at 850 MHz and 900 MHz and a higher frequency band covering the GSM subbands at 1800 MHz and 1900 MHz and the data subband at 2100 MHz.
It may be desirable for device 10 to be capable of supporting wireless communication bands other than the first and second bands. For example, it may be desirable for antenna 40 to be able to operate in a higher frequency band covering the GSM subbands at 1800 MHz and 1900 MHz and the data subband at 2100 MHz, a first band of a lower frequency band covering the GSM subbands at 850 MHz and 900 MHz, and a second lower frequency band covering the LTE band at 700 MHz, the GSM subbands at 710 MHz and 750 MHz, the UMTS subband at 700 MHz, and other desired wireless communications bands.
Antenna band 40 coverage of the type described with respect to Figure 10 may be limited by the volume (e.g., the volume of the aperture defined by the conductive loop 70) of loop antenna 40. In general, for a loop antenna having a given volume, higher bandwidth coverage (or bandwidth) results in a decrease in gain (for example, the product of maximum gain and bandwidth is constant).
Figure 12 is a graph showing how antenna gain varies as a function of antenna bandwidth. Curve 200 represents a gain - bandwidth characteristic for a first loop antenna having a first volume, while curve 202 represents a gain - bandwidth characteristic for a second loop antenna having a second volume that is larger than the first volume. The first and second loop antennas can be antennas of the type described in relation to figure 10.
As shown in Figure 12, the first looped antenna can provide a BW1 bandwidth while exhibiting a g0 gain (dot 204). In order to provide more bandwidth (ie, bandwidth BW2) with the first loop antenna, the gain of the first loop antenna would be decreased to the gain gi (point 205). One way to provide more bandwidth coverage is to increase the volume of the loop antenna. For example, the second loop antenna having a volume greater than the volume of the first loop antenna is capable of providing BW2 bandwidth while displaying g0 (point 206). An increase in the volume of loop antennas, however, may not always be possible if a small form factor is desired.
In another suitable arrangement, the wireless circuitry of device 10 may include a tunable (configurable) antenna circuit. The tunable antenna circuit may allow antenna 40 to be operable in at least three wireless communications bands (as an example). The tunable antenna circuit may include a switchable inductor circuit, such as circuit 210, a tunable combination network circuit, such as combination circuit M1, a variable capacitor circuit, such as circuit 212, and other circuits. suitable tunables (see, for example, figure 13).
As shown in Figure 13, the loop conductor 70 of the parallel feed loop antenna 40 may have a first inductive segment SG and a second inductive segment SG' that run parallel to the ground plane edge GE. Segments SG and SG’ can be, for example, conductive traces on a printed circuit board or other conductive member. A dielectric opening DL (e.g. an opening filled with air or filled with plastic) can separate the ground edge GE portion 68 from the segment SG from the conductive loop portion 70, whereas the dielectric opening DL' can separate the GE edge portion of ground 68 of segment SG' of conductive loop portion 70. The dielectric openingsDL and DL' can have different shapes and sizes.
Segments SG and SG’ can be connected through a portion 99 of conductor 70 that runs perpendicular to the edge of the ground plane GE. A switchable inductor circuit (also referred to as a tunable inductor circuit, a configurable inductor circuit, or an adjustable inductor circuit) 210 may be coupled between portion 99 and a corresponding terminal 101 on the ground plane edge GE. When circuit 210 is switched for use (for example, when circuit 210 is activated), the SG segment and associated ground GE form a first transmission line path with a first inductance (i.e., the SG segment and the ground GE form inductor 98). When circuit 210 is switched out of use (e.g., when circuit 210 is deactivated), segment SG, portion 99, segment SG', and ground GE collectively form a second transmission line path with a second inductance (ie, segment SG' and ground GE form inductor 98' which is coupled in series with inductor 98). The second transmission line path can sometimes be referred to as being a fixed inductor, because the inductance of the second transmission line path is fixed when the switchable inductor 210 is not in use. The switchable inductor 210 serves to bypass the second transmission line path so that the first inductance value is lower than the second inductance value.
The SG and SG’ segment dimensions are selected so that the equivalent inductance values for the first and second inductances are equal to 18 nH and 20 nH, respectively (as an example). The first transmission line path (if circuit 210 is enabled) and the second transmission line path (if circuit 210 is disabled) are connected in parallel with power terminals 54 and 58 and serve as inductive tuning elements parallel them to antenna 40. The first and second transmission line paths can then be referred to, sometimes therefore, as a variable inductor. Because the first and second inductances are provided using transmission line structures, the first and second transmission line paths can preserve high-band performance (illustrated as a satisfactory resonant peak 94 in Figure 6), whereas inductors Discrete could reduce high-band performance.
The presence of inductor 98 may help, at least partially, in matching the impedance of transmission line 52 with antenna 40 when circuit 210 is activated, whereas the presence of series connected inductors 98 and 98' may partially assist in the combination of the impedance of line 52 and antenna 40 when circuit 210 is disabled. If desired, inductors 98 and 98' can be formed using discrete components such as surface mount technology (SMT) inductors. Inductors 98 and 98’ have inductance values that are carefully chosen to provide a desired band coverage.
In another suitable embodiment, a tunable combination network circuit M1 can be coupled between coaxial cable 52 and capacitor 100. For example, tunable circuit M1 can have a first terminal 132 connected to the coaxial cable center conductor and a second terminal 122 connected to capacitor 100. The M1 impedance combination circuit can be formed using conductive structures with associated values of capacitance, resistance and inductance, and/or discrete components such as inductors, capacitors and resistors that form circuits that match the transceiver circuit impedances 38 and antenna 40.
The M1 combination circuit can be fixed or adjustable. In this type of configuration, a control circuit, such as an antenna tuning circuit 220, can output control signals, such as the SELECT signal in path 29, to the configuration of the combination circuit M1. When SELECT has a first value, the combination circuit M1 can be placed in a first configuration. When SELECT has a second value, the M1 combination circuit can be placed in a second configuration. The state of combination circuit M1 can serve to tune antenna 40 so that the desired communication bands are covered by antenna 40.
In another suitable embodiment, a variable capacitor circuit (sometimes referred to as a varator circuit, a tunable capacitor circuit, an adjustable capacitor circuit, etc.) 212 can be coupled between the conductive bevel space 18. The bevel space 18, for example, can have an intrinsic capacitance of 1 pF (eg, an inherent capacitance value formed by the parallel conductive surfaces in space 18. Component 212 can be, for example, a continuously variable capacitor, an adjustable capacitor, semi-continuously that has two to four or more different capacitance values that can be coupled in parallel to the intrinsic capacitance. If desired, component 212 can be a continuously variable inductor or a semi-continuously adjustable inductor that has two to four or more different inductance values. Component capacitance value 212 can serve to fine tune antenna 40 for operation at desired frequencies. at.
The illustrative tunable circuit that can be used for implementing the tunable combination circuit M1 of Figure 13 is shown in Figure 14. As shown in Figure 14, the combination circuit M1 may have switches such as switches 134 and 136. switches 134 and 136 can have multiple positions (shown by illustrative positions A and B in Figure 14). When the SELECT signal has a first value, switches 134 and 136 can be placed in their A positions and the combination circuit MA can be switched for use. When the SELECT signal has a second value, switches 134 and 136 can be placed in their B positions (as shown in figure 14), so that an MB combination circuit is connected between paths 132 and 122.
Fig. 15 shows a suitable circuit implementation of switchable inductor circuit 210. As shown in Fig. 15, circuit 210 includes a switch SW and an inductive element 98' coupled in series. The SW switch can be implemented using a pin diode, a gallium arsenide field effect transistor (FET), a microelectromechanical systems switch (MEMs), a metal-oxide semiconductor field effect transistor (MOSFET) , a high electron mobility transistor (HEMT), a pseudomorphic HEMT (PHEMT), a transistor formed on a silicon substrate on insulator (SOI), etc.
Inductive element 98' can be formed from one or more electrical components. Components that can be used as all or part of the 98’ element include resistors, inductors, and capacitors. The desired resistances, inductances and capacitances for element 98' can be formed using integrated circuits, using discrete components (eg, a surface mount technology inductor) and/or using dielectric and conductive structures that are not part of a component discrete or an integrated circuit. For example, a resistor can be formed using thin lines of a resistive metal alloy, a capacitance can be formed by spacing two conductive shims close together, which are separated by a dielectric, and an inductance can be formed by creating a conductive path (eg, a transmission line) on a printed circuit board.
Figure 16 shows how a varator circuit 212 can receive control voltage signal Vc from antenna tuning circuit 220. As shown in Figure 16, varator circuit 212 can have a first terminal connected to a bevel space end. 18, a second terminal connected to another end of bevel space 18, and a third terminal that receives a control signal Vc. Antenna tuning circuit 220 can orient Vc to different voltage levels to adjust the capacitance of the varator 212. The varator 212 can be formed using integrated circuits, one or more discrete components (eg, SMT components ), etc.
By using antenna tuning schemes of the type described in relation to Figures 13 to 16, antenna 40 may be able to cover a wider range of communications frequencies than would otherwise be possible. Figure 17 shows an illustrative SWR plot for antenna 40 of the type described in relation to Figure 13. The solid line 90 corresponds to a first antenna mode 40 when inductive circuit 220 is enabled.
In this first mode, antenna 40 can operate in bands in a first low-band region at frequency f1 (eg for coverage of GSM bands at 850 MHz and 900 MHz) and in bands in a high-band region at frequency f2 (eg for coverage of the GSM bands at 1800 MHz, 1900 MHz and 2100 MHz).
The dashed line 90' corresponds to a second antenna mode 40 when inductive circuit 220 is disabled. In this second mode, antenna 40 can operate in bands in a second low-band region at frequency f1' (eg for coverage of the LTE band at 700 MHz and other bands of interest), while preserving coverage in the region. high-band at frequency f2. The tunable combination circuit M1 can be configured to provide coverage in the desired subband.
The varator circuit 212 can be used to fine-tune antenna 40 prior to operation of device 10 or in real time, so that antenna 40 functions as desired under a variety of wireless environmental and traffic scenarios and for compensation for process, voltage and temperature variations and other sources of noise, interference or variation.
According to one embodiment, a loop antenna fed in parallel on an electronic device having a periphery is provided, which includes: an antenna feed including first and second antenna feed terminals; a conductive loop coupled between the first and second antenna feed terminals, where the conductive loop is formed at least partially from conductive structures disposed along the periphery; and a variable inductor that forms a bridge between the first and second antenna feed terminals.
According to another embodiment, the variable inductor includes a fixed inductor and a switchable inductor that are coupled in parallel between the first and second antenna supply terminals.
According to another embodiment, the switchable inductor includes an inductor and a switch that are connected in series between the first and second antenna supply terminals.
According to another embodiment, the fixed inductor and the inductor include inductive transmission line structures.
According to another embodiment, the variable inductor is selectively configured to operate in a first mode in which the variable inductor exhibits a first inductance between the first and second antenna supply terminals, and a second mode in which the variable inductor exhibits a second inductance between the first and second antenna supply terminals, where the first inductance is different from the second inductance.
According to another embodiment, where the conductive structures include at least one space, the parallel powered loop antenna further includes a variable capacitor circuit that forms a bridge in at least one space.
According to another embodiment, the electronic device further includes a wireless transceiver circuit and a tunable impedance combining circuit interposed between the transceiver circuit and the antenna feeds.
According to another embodiment, the electronic device further includes: a wireless transceiver circuit; and a tunable impedance combining circuit interposed between the transceiver circuit and the antenna feeds.
According to another embodiment, the parallel powered loop antenna further includes: an antenna feed line which carries antenna signals between a transmission line and the first antenna feed terminal; and a capacitor interposed in the antenna supply line.
According to the embodiment, a portable electronic device is provided, which includes: an antenna feed including the first and second antenna feed terminals; a conductive loop coupled between the first and second antenna feed terminals; a wireless transceiver circuit; and a tunable impedance matching circuit interposed between the wireless transceiver circuit and the antenna feed.
According to another modality, the portable electronic device also includes: an accommodation that has a periphery; and a conductive structure that runs along the periphery and has at least one space on the periphery.
According to another embodiment, the portable electronic device further includes: a variable capacitor circuit that bridges at least one space.
According to another embodiment, the tunable impedance combining circuit includes at least two impedance combining network circuits and a switching circuit that configures the tunable impedance combining circuit for switching for use in a circuit selected from the two circuits. impedance matching network.
According to another embodiment, the antenna includes a loop antenna fed in parallel.
According to another embodiment, the electronic device further includes: a transmission line having positive and grounding conductors, wherein the grounding conductor is coupled to the second antenna power terminal and wherein the positive conductor is coupled to the first terminal antenna power supply; and a capacitor interposed on the positive conductor of the transmission line.
According to another embodiment, the electronic device further includes: an inductor circuit that forms a bridge between the first and second antenna feed terminals.
According to an embodiment, a wireless electronic device is provided, which includes: a housing having a periphery; a conductive structure that runs along the periphery and has at least one space on the periphery; and an antenna formed at least partially from the conductive structure, wherein the antenna comprises an antenna tuning circuit that configures the antenna to operate in: a first mode of operation in which the antenna is configured to operate in a first communications band and a second communications band which is higher in frequency than the first communications band; and a second mode of operation, in which the antenna is configured to operate in a third communications band that is lower in frequency than the first communications band and the second communications band.
According to another modality, the first communications band is centralized at 900 MHz, the second communications band is centralized at 1850 MHz, and the third communications band is centralized at 700 MHz.
According to another embodiment, the antenna tuning circuit includes: a variable capacitor circuit that bridges at least one space.
According to another embodiment, the antenna includes positive and negative feeds and the antenna tuning circuit includes: a variable inductor that forms a bridge between the positive and negative antenna feed terminals.
According to another embodiment, the antenna further includes an antenna feed, and the antenna tuning circuit includes a tunable impedance combining circuit having: a radio transceiver circuit, where the tunable impedance combining circuit is interposed between the radio transceiver circuit and the antenna supply.
The foregoing is merely illustrative of the principles of this invention, and various modifications may be made by those skilled in the art, without departing from the scope and spirit of the invention. The preceding modalities can be implemented individually or in any combination.

权利要求:
Claims (18)
[0001]
1. Loop antenna powered in parallel in an electronic device having a periphery, comprising: an antenna feed including first and second antenna feed terminals; a conductive loop coupled between the first and second antenna feed terminals, wherein the conductive loop is formed at least partially from conductive structures disposed along the periphery; characterized by a variable inductor that forms a bridge between the first and second antenna power terminals, the variable inductor comprising: a first segment, wherein the first segment forms a part of a transmission line path with a first inductance and a first length; and a second segment, wherein the second segment and the first segment are part of a second transmission line path with a second inductance and a second length that is different from the first length.
[0002]
2. Parallel powered loop antenna according to claim 1, characterized in that the variable inductor comprises a switch that is connected in series with the first segment between the first and second antenna feed terminals, and in which the second segment and the switch are coupled in parallel between the first segment and the second antenna feed terminal.
[0003]
3. Parallel powered loop antenna, according to claim 2, characterized in that the fixed inductor and the inductor comprise inductive transmission line structures.
[0004]
4. Parallel powered loop antenna, according to claim 1, characterized in that the first inductance is different from the second inductance.
[0005]
5. Parallel powered loop antenna, according to claim 1, characterized in that the conductive structures comprise at least one space, further comprising: a variable capacitor circuit that forms a bridge in at least one space.
[0006]
6. Parallel powered loop antenna according to claim 5, characterized in that the electronic device further comprises a wireless transceiver circuit and a tunable impedance combination circuit interposed between the transceiver circuit and the first terminal antenna power supply.
[0007]
7. Parallel powered loop antenna, according to claim 1, characterized in that the electronic device further comprises: a wireless transceiver circuit; and a tunable impedance combining circuit interposed between the transceiver circuit and the first antenna feed terminal.
[0008]
8. Parallel powered loop antenna, according to claim 1, characterized in that it further comprises: an antenna feed line that carries antenna signals between a transmission line and the first antenna feed terminal; and a capacitor interposed in the antenna supply line.
[0009]
9. A portable electronic device having a length, a width less than the length and a height less than the width, the electronic device comprising: an antenna feed including the first and second antenna feed terminals; a conductive loop coupled between the first and second antenna feed terminals; a wireless transceiver circuit; a tunable impedance combination circuit interposed between the wireless transceiver circuit and the antenna feed, a housing having a periphery, an upper surface and a lower surface; characterized by: a conductive housing structure, wherein the conductive housing structure extends across the height of the portable electronic device and runs along the periphery, the conductive housing structure has at least one gap that extends across the height of the device electronic from the upper surface of the housing to the lower surface of the housing and the conductive circuit is formed at least partially from the structure of the conductive housing.
[0010]
10. Portable electronic device according to claim 9, characterized in that it further comprises: a variable capacitor circuit that forms a bridge in at least one space.
[0011]
11. Portable electronic device according to claim 10, characterized in that the tunable impedance combining circuit comprises at least two impedance combining network circuits and a switching circuit configuring the tunable impedance combining circuit to switch on using a circuit selected from the two impedance combination network circuits.
[0012]
12. Electronic device according to claim 10, characterized in that the antenna comprises a loop antenna fed in parallel.
[0013]
13. Electronic device according to claim 9, characterized in that it further comprises: a transmission line having positive and grounding conductors, in which the grounding conductor is coupled to the second antenna supply terminal and in which the positive lead is coupled to the first antenna feed terminal; and a capacitor interposed on the positive conductor of the transmission line.
[0014]
14. Electronic device according to claim 9, characterized in that it further comprises: an inductor circuit that forms a bridge between the first and second antenna supply terminals.
[0015]
15. Wireless electronic device, comprising: a housing having a periphery; a conductive structure that runs along the periphery and has at least one space on the periphery; characterized by an antenna formed at least partially from the conductive structure, wherein the antenna comprises an antenna tuning circuit that configures the antenna to operate in: a first mode of operation in which the antenna is configured to operate in a first band communications and a second communications band that is higher in frequency than the first communications band; and a second mode of operation, in which the antenna is configured to operate in a second communication band and a third communication band that is lower in frequency than the first communication band and the second communication band.
[0016]
16. Wireless electronic device according to claim 15, characterized in that the antenna tuning circuit comprises: a variable capacitor circuit that forms a bridge in at least one space.
[0017]
17. Wireless electronic device according to claim 15, characterized in that the antenna comprises positive and negative feeds and in which the antenna tuning circuit comprises: a variable inductor that forms a bridge between the feed terminals of positive and negative antenna.
[0018]
18. Wireless electronic device according to claim 15, characterized in that the antenna further comprises an antenna feed, and wherein the antenna tuning circuit comprises a tunable impedance combining circuit, which further comprises: a radio transceiver circuit, wherein the tunable impedance combination circuit is interposed between the radio transceiver circuit and the antenna supply.

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同族专利:

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公开号 | 公开日

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JP2012186810A|2012-09-27|

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EP2498337A1|2012-09-12|

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AU2012200977B2|2014-06-12|

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KR101357365B1|2014-02-03|

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CN102683861A|2012-09-19|

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WO2012121861A1|2012-09-13|

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JP5666497B2|2015-02-12|

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HK1175891A1|2013-07-12|

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CN102683861B|2016-02-03|

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US9246221B2|2016-01-26|

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US20120231750A1|2012-09-13|

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KR20120102517A|2012-09-18|

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TW201242169A|2012-10-16|

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法律状态:
2018-11-21| B03A| Publication of a patent application or of a certificate of addition of invention [chapter 3.1 patent gazette]|

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2018-12-18| B06F| Objections, documents and/or translations needed after an examination request according [chapter 6.6 patent gazette]|

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2020-07-07| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|

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2021-04-06| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|

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2021-05-25| B16A| Patent or certificate of addition of invention granted [chapter 16.1 patent gazette]|Free format text: PRAZO DE VALIDADE: 20 (VINTE) ANOS CONTADOS A PARTIR DE 02/03/2012, OBSERVADAS AS CONDICOES LEGAIS. |

优先权:

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申请号 | 申请日 | 专利标题

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US13/041,934|US9246221B2|2011-03-07|2011-03-07|Tunable loop antennas|

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US13/041,934|2011-03-07|

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