Claims
- 1. A planar inverted-F antenna having a plurality of resonant frequency bandwidths of operation, comprising:
a signal feed; a ground feed; and a conductive element in communication with the signal and ground feed, the conductive element comprising:
a primary branch in communication with the signal and ground feeds, the primary branch having opposing first and second end portions and a first current path length; a secondary branch in communication with the signal and ground feeds, the secondary branch having opposing first and second end portions and a second current path length, the length of the second current path being shorter than the length of the first current path; and a bend segment having opposing end portions positioned intermediate the primary and secondary branches configured to join the primary and secondary branches, wherein the secondary branch is conductively coupled to the signal and ground feeds, wherein the primary branch is conductively coupled to the bend segment that is conductively coupled to the signal and ground feeds thereby allowing the primary branch to radiate at high and low band without requiring capacitive coupling between the primary and secondary branches.
- 2. An antenna according to claim 1, wherein the ground and signal feeds are positioned adjacent each other proximate a common edge portion of the conductive element.
- 3. An antenna according to claim 1, wherein the ground and signal feeds are positioned adjacent each other proximate a common outer edge portion of the conductive element, and wherein the bend segment is configured and positioned with respect to the signal and ground and the secondary branch, so that in low band operation, current flows into the primary branch but the secondary branch has current flow that is reduced from that in high band operation, and so that in high band operation, current flows in at least a major portion of both the primary and secondary branches.
- 4. An antenna according to claim 1, wherein the bend segment provides a current path that is substantially orthogonal to the current path in the secondary branch.
- 5. An antenna according to claim 1, wherein, during operation, the bend segment is configured and positioned with respect to the signal and ground feeds to define a high impedance node in the current path between the bend segment and the primary branch outermost end portion, and wherein at high band, about a ¼ wave resonance is formed in the secondary branch and about a ½ wave resonance is formed in the primary branch and a portion of the bend segment.
- 6. An antenna according to claim 1, wherein, in high band operation, the secondary branch and/or bend segment defines a high impedance node with a current null space in the conductive element current path so that the antenna provides about ½ wave resonance on the primary branch.
- 7. An antenna according to claim 3, wherein a respective one of each of the end portions of the primary and secondary branches are connected to opposing end portions of the bend segment with the remaining end portion of the primary and secondary branches being spaced apart a sufficient distance to insulate them from parasitically coupling during operation.
- 8. An antenna according to claim 1, wherein high band comprises frequencies that are at least equal to or greater than about twice that of the frequencies in the low band.
- 9. An antenna according to claim 1, wherein the primary branch defines a ¼ wave resonator at low band and a ½ wave resonator at high band operation, wherein the secondary branch defines a ¼ wave resonator at high band operation.
- 10. An antenna according to claim 1, wherein the bend segment is located between about 4-15 mm away from the signal feed location.
- 11. A planar inverted-F antenna, comprising:
a planar conductive element having primary and secondary branches comprising:
first, second and third elongated branch segments, each having opposing first and second end portions, wherein the first, second and third elongate elements are spaced apart from each other with the second elongated segment being intermediate of the first and third elongated segments; a first bend segment extending between the first and second elongated segments at a corresponding one of the first or second end portions thereof; and a second bend segment extending between the second and third elongated segments at the other corresponding end portion; a signal feed electrically connected to the conductive element proximate an edge portion thereof; and a ground feed electrically connected to the conductive element proximate the signal feed at the same edge portion thereof,
wherein the antenna is configured to operate at first and second different resonant frequency bands, wherein the conductive element has a primary current path that radiates as about a ¼ wave resonator during the first band of operation and about a ½ wave resonator during the second band of operation and that includes two of the first, second and third elongated segments and at least one of the bend segments, and wherein the conductive element has a secondary current path that radiates primarily during high band operation to provide about a ¼ wave resonator that includes the remaining one of the first, second or third elongated segment, and wherein the primary current path is configured to radiate at the first band independent of proximity coupling to the secondary current path.
- 12. An antenna according to claim 11, wherein the first band is low band and the second band is high band, and wherein the high band frequencies are at least about twice the value of the frequencies of the low frequency band.
- 13. An antenna according to claim 11, wherein the conductive element first and/or second bend segments are configured with a high impedance node to generate at least one current null space in a current path during one of the first or second bands of operation.
- 14. An antenna according to claim 12, wherein the first, second, and third elongate branch segments have current paths that are substantially parallel and the first and second bend segments provide current paths that extend in a direction that is angularly offset from the direction of the first, second and third elongate branch segments.
- 15. An antenna according to claim 14, wherein the first, second and third elongate branch segments are configured to extend in a substantially vertical orientation, and the first and second bend segments are configured to extend in a generally horizontal orientation.
- 16. An antenna according to claim 14, wherein the first and second bend segments are generally perpendicular to the direction of the first, second and third elongate branch segments.
- 17. An antenna according to claim 14, wherein the first, second and third elongate branch segments are configured to extend in a substantially horizontal orientation, and the first and second bend segments are configured to extend in a generally vertical orientation.
- 18. An antenna according to claim 11, wherein the conductive element arranges the segments serially from the first elongate branch segment to the first bend segment to the second elongate branch segment to the second bend segment to the third elongate branch segment, wherein the segments are in conductive communication with the signal and ground feed.
- 19. An antenna according to claim 14, wherein the first, second and third elongate branch segments and the first and second bend segments are formed from a unitary sheet of conductive material.
- 20. An antenna according to claim 12, wherein the primary current path segments are in conductive communication with the signal and ground feeds so as to radiate without parasitic coupling to the secondary current path in low band operation.
- 21. An antenna according to claim 20, wherein the conductive element is sized, configured and connected to the signal and ground feeds such that, in operation, there is a longer current path for the primary current path and a shorter current path for the secondary current path.
- 22. An antenna according to claim 21, wherein the signal and ground are positioned on a common outer edge portion of the conductive element, and wherein the primary current path radiates at about a ¼ wavelength at the low frequency band and at about a ½ wavelength at the high frequency band.
- 23. An antenna according to claim 12, wherein the signal and ground feeds are connected to an outer edge portion of the third elongated branch segment with the ground feed disposed closer to the second elongate branch segment than the signal feed and with the signal and ground feeds disposed closer to the first edge portion of the third elongated branch segment than the second edge portion, and wherein the first bend segment extends between the first and second elongated branch segments at the second end portions thereof and the second bend segment extends between the second and third elongated segments at the first end portions thereof.
- 24. An antenna according to claim 23, wherein the first, second and third elongated branch segments are substantially parallel with each other and the first and second bend segments are substantially perpendicular to the first, second and third elongated branch segments.
- 25. An antenna according to claim 24, wherein at high band operation, the secondary current path comprises the third elongated branch segment and the primary current path comprises the first bend segment and the second and third branches.
- 26. An antenna according to claim 25, wherein at low band operation, the conductive element radiates along the first and second bend segments and the first and second branch segments.
- 27. An antenna according to claim 12, wherein the signal and ground feeds are arranged about an upper edge portion of the conductive element proximate the second bend segment and first end portion of the second elongated branch segment, with the signal feed positioned closer to the third elongated branch segment and the ground feed positioned closer to the first elongated branch segment than the ground feed, wherein, in the low band of operation, the first and second elongated branch segments provide the primary current path for the signal and the third branch segment is substantially devoid of current, and wherein, in the high band of operation, the first, second, and third branch segments and the first and second bend segments radiate.
- 28. An antenna according to claim 27, wherein the first bend segment extends between the first and second elongated branch segments at the second end portions thereof and the second bend segment extends between the second and third elongated branch segments at the first end portions thereof.
- 29. An antenna according to claim 28, wherein the first elongated branch segment is a left branch, the second elongated branch segment is the intermediate branch and the third elongated branch segment is the right branch, and wherein the first, second and third elongated branch segments are generally parallel to each other.
- 30. An antenna according to claim 29, in combination with an elongate printed circuit board, wherein the first, second and third elongated branch segments are oriented to be substantially parallel to the longitudinal direction of the elongate printed circuit board.
- 31. An antenna according to claim 28, in combination with an elongate printed circuit board, wherein the first, second and third elongated branch segments are oriented to be substantially parallel to the lateral direction of the elongate printed circuit board.
- 32. An antenna according to claim 28, wherein the second branch segment is disposed intermediate of the first and third elongated branch segments with elongate gaps of air and/or dielectric material positioned between the first and second elongated branch segments and second and third elongated branch segments.
- 33. An antenna according to claim 12, wherein the signal and ground feeds are configured to connect proximate an outer edge portion of the first elongated branch segment with the ground feed disposed closer to the second elongated branch segment than the signal feed, and wherein the first bend segment extends between the first end portions of the first and second elongated branch segments and the second bend segment extends between the second end portions of the second and third elongated branch segments.
- 34. An antenna according to claim 33, wherein the first, second and third elongated branch segments are generally parallel to each other.
- 35. An antenna according to claim 33, wherein, in operative position in a housing, the first, second and third elongated branch segments are oriented to be substantially parallel to the longitudinal direction of an elongate printed circuit board.
- 36. An antenna according to claim 34, wherein in operative position in a housing, the first, second and third elongated branch segments are oriented to be substantially parallel to the lateral direction of an elongate printed circuit board.
- 37. An antenna according to claim 33, wherein the first elongated branch segment is the right-most or left-most elongated branch segment and the third elongated branch segment is the corresponding other of the left-most or right-most elongated branch segment, respectively.
- 38. An antenna according to claim 33, wherein the first bend segment angles downwardly from the first elongated branch first end portion toward the second elongated branch first end portion.
- 39. An antenna according to claim 37, wherein the second and third elongated branch segments radiate in both low and high band operation while the first elongated branch segment radiates in the high band but is substantially devoid of radiation in the low band of operation.
- 40. An antenna according to claim 39, wherein the first, second and third elongated branch segments and first and second bend segments provide about a ½ wave resonance in high band operation.
- 41. An antenna according to claim 33, wherein the third elongated branch segment first end portion includes an extension that is configured to turn toward the first elongated branch segment and is sized and configured to capacitively couple to the first elongated branch segment first end portion and/or first bend segment during operation.
- 42. An antenna according to, claim 12, wherein the signal and ground feeds are arranged about the second intermediate elongated branch segment of the conductive element, with the signal feed positioned closer to the first elongated branch segment and the ground feed positioned closer to the third elongated branch segment, wherein the conductive element comprises a fourth elongated branch segment, and wherein in low band operation, the first, second, and fourth elongated branch segments provide the primary current path for the signal, wherein, in high band operation, the first, third and fourth elongated branch segments radiate and wherein, the third segment radiates to a greater degree in high band than in low band.
- 43. An antenna according to claim 42, wherein the first bend segment extends between the first and second elongated branch segments at the second end portions thereof and the second bend segment extends between the second and third elongated branch segments at the first end portions thereof.
- 44. An antenna according to claim 42, wherein the fourth elongated branch segment is the right most branch, wherein the first elongated branch segment is the left most elongated branch segment, and the second elongated branch segment is the right intermediate elongated branch segment, and the third elongated branch segment is a left-intermediate elongated branch segment that is disposed closer to the fourth elongated branch segment or the branch segments are formed in a mirror image thereof, and wherein the first, second, third, and fourth elongated branch segments are generally parallel to each other.
- 45. An antenna according to claim 44, wherein, in operative position, the first, second, third and fourth elongated branch segments are oriented to be substantially parallel to the longitudinal direction of an elongate printed circuit board.
- 46. An antenna according to claim 44, wherein the first elongated branch segment first end portion comprises an extension that turns in toward the intermediate second elongated branch segment and then turns down toward the first bend segment.
- 47. A wireless terminal, comprising:
(a) a housing configured to enclose a transceiver that transmits and receives wireless communications signals; (b) a ground plane disposed within the housing; (c) a planar inverted-F antenna disposed within the housing and electrically connected with the transceiver, wherein the antenna comprises:
a planar dielectric substrate; a planar conductive element disposed on the planar dielectric substrate, comprising:
a primary branch having a length and opposing first and second end portions, the primary branch being configured to define about a ¼ wave resonator at a low frequency band; a bend segment having opposing first and second end portions, the first end portion terminating into the second end portion of the primary branch; a secondary branch connected to the second end portion of the bend segment, wherein the secondary branch defines a ¼ wave resonator at the high frequency band, wherein the conductive element is configured to allow the resonances of the secondary and primary branches to provide about a ½ wave resonance at the high frequency band; (d) a signal feed electrically connected to the secondary branch or bend segment of the primary branch of the conductive element proximate a first portion thereof; and (e) a ground feed electrically connected to the conductive element proximate the signal feed about the first portion of the conductive element.
- 48. A wireless terminal according to claim 47, wherein the primary branch second end portion is spaced apart a sufficient distance from the secondary branch so that the primary branch radiates in low band independent of proximity coupling to the secondary branch.
- 49. A wireless terminal according to claim 47, wherein the conductive element is configured to define a current null proximate the primary branch bend region during high band operation.
- 50. A wireless terminal according to claim 47, wherein the primary branch operates as about a ½ wave resonator at the high frequency band, and wherein the high frequency band has frequencies that are equal to or greater than about twice the frequencies of the low band.
- 51. A wireless terminal according to claim 47, wherein the low frequency band comprises at least one of 824-894 MHz and/or 880-960 MHz, and wherein the high frequency band comprises frequencies that are at least twice the value of the frequencies in the low band.
- 52. A wireless terminal according to claim 47, wherein the signal and ground feeds are disposed proximate a common outer edge portion of the conductive element, wherein the bend segment in the primary branch is configured to reside at about 4-15 mm from the signal feed location, and wherein the conductive element has dimensions which reside within an area of about 1200 mm2.
- 53. A wireless terminal according to claim 47, wherein the low frequency band comprises at least one of 850 MHz and/or 900 MHz and the high frequency band comprises at least one of 1800 MHz and/or 1900 MHz.
- 54. A method for exciting a planar inverted F antenna having low and high band operational modes:
providing a conductive element with primary and secondary resonant branches, the conductive element configured so that the secondary branch terminates into a bend region before extending into the primary branch, the primary branch being configured to form about a ¼ wave resonator at a low frequency band, the secondary branch configured to act as about a ¼ wave resonant at a high frequency band; generating a high impedance node to provide a current null proximate the secondary branch and/or the bend region of the primary branch during operation in the high frequency band; and causing the primary branch with the secondary branch resonance to provide about a ½ wave resonator during operation in the high frequency band.
- 55. A method according to claim 54, further comprising configuring the primary and secondary branches so that the primary branch radiates independent of proximity coupling to the secondary branch.
- 56. A method according to claim 54, further comprising coupling the conductive element to signal and ground feeds that are positioned adjacent each other proximate a common edge portion of the conductive element.
- 57. A method according to claim 56, wherein the high band has frequencies that are at least about twice the value of the frequencies of the low band.
- 58. A method according to claim 57, wherein the high impedance node is positioned at between about 4-15 mm away from the signal feed.
- 59. A method according to claim 56, wherein the conductive element is coupled to the adjacent signal and ground feeds at a common outer edge portion of the conductive element.
- 60. A method according to claim 54, wherein the primary branch operates as about a ½ wave resonator at the high frequency band, and wherein the high frequency band has frequencies that are equal to or greater than about twice the frequencies of the low band.
RELATED APPLICATIONS
[0001] This application is a continuation-in-part of U.S. patent application Ser. No. 10/248,082, filed Dec. 17, 2002, entitled Multi-band, Inverted-F Antenna with Capacitively Created Resonance, and Radio Terminal Using Same identified by Docket Nos. U02-0081/0119778-27, the contents of which are hereby incorporated by reference as if recited in full herein.
Continuation in Parts (1)
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Number |
Date |
Country |
Parent |
10248082 |
Dec 2002 |
US |
Child |
10443202 |
May 2003 |
US |