A novel loaded antenna is defined in the present invention. The radiating element of the loaded antenna consists of two different parts: a conducting surface and a loading structure. By means of this configuration, the antenna provides a small and multiband performance, and hence it features a simil
A novel loaded antenna is defined in the present invention. The radiating element of the loaded antenna consists of two different parts: a conducting surface and a loading structure. By means of this configuration, the antenna provides a small and multiband performance, and hence it features a similar behavior through different frequency bands.
대표청구항▼
1. A portable communications device comprising: a case operable to be held in a user's hand;a grounding element;an antenna mounted entirely within the case and coupled to the grounding element, the antenna being configured to both radiate and receive electromagnetic waves corresponding to at least t
1. A portable communications device comprising: a case operable to be held in a user's hand;a grounding element;an antenna mounted entirely within the case and coupled to the grounding element, the antenna being configured to both radiate and receive electromagnetic waves corresponding to at least two non-overlapping frequency bands, wherein:the antenna comprises a radiating element comprising a first part and a second part, the first part comprising at least one conducting surface, the at least one conducting surface being configured to radiate and receive electromagnetic waves corresponding to at least two non-overlapping frequency regions and comprising a surface whose entire perimeter is a space-filling perimeter, the space-filling perimeter including at least ten segments connected such that no pair of adjacent segments defines a longer straight segment, all of the segments of the space-filling perimeter being smaller than a tenth of an operating free-space wavelength of the antenna, and the second part comprising a loading structure extending along at least one path having a length between two tips, the length of the at least one path of the loading structure being smaller than an eighth of the longest operating free-space wavelength of the antenna;at least one tip of the loading structure is connected along a width dimension of the loading structure to at least a portion of an edge of the at least one conducting surface; anda maximum width of the loading structure is smaller than a quarter of a longest edge of the perimeter of the at least one conducting surface. 2. The portable communications device of claim 1, wherein one of the at least two non-overlapping frequency bands is a frequency band that comprises 900 MHz. 3. The portable communications device of claim 2, wherein one of the at least two non-overlapping frequency bands is a frequency band that comprises 1800 MHz. 4. The portable communications device of claim 1, wherein the grounding element comprises a ground plane. 5. The portable communications device of claim 4, wherein one of the at least two non-overlapping frequency bands is a frequency band that comprises 900 MHz and one of the at least two non-overlapping frequency bands is a frequency band that comprises 1800 MHz. 6. The portable communications device of claim 4, wherein the antenna is configured to radiate and receive electromagnetic waves corresponding to at least three frequency bands, and wherein the loading structure is configured to cause a bandwidth of the radiating element to be greater than a bandwidth of the first part in a second frequency region. 7. The portable communications device of claim 6, wherein one of the at least three frequency bands is a frequency band that comprises 1800 MHz. 8. The portable communications device of claim 7, wherein one of the at least three frequency bands is a frequency band that comprises 900 MHz. 9. The portable communications device of claim 6, wherein the at least one conducting surface and the loading structure lie on a common curved surface. 10. The portable communications device of claim 6, wherein the perimeter of the loading structure is shaped as a space-filling curve, the space-filling curve including at least ten segments connected such that no pair of adjacent segments defines a longer straight segment, the segments being smaller than a tenth of an operating free-space wavelength of the antenna. 11. The portable communications device of claim 1, wherein the loading structure is configured to adjust a spacing between the at least two non-overlapping frequency bands. 12. The portable communications device of claim 11, wherein the width of the loading structure is non-uniform. 13. The portable communications device of claim 11, wherein a distance between the at least one point and a feeding point is smaller than a quarter of a longest operating wavelength, and wherein the distance is measured as a shortest distance through the perimeter of the at least one conducting surface. 14. The portable communications device of claim 11, wherein a tip of the at least one conducting strip is open ended. 15. The portable communications device of claim 11, wherein one of the at least two non-overlapping frequency bands comprises UMTS. 16. The portable communications device of claim 1, wherein the antenna is configured to radiate and receive electromagnetic waves corresponding to at least three frequency bands. 17. The portable communications device of claim 16, wherein a minimum operating frequency of the first part is substantially similar to a minimum operating frequency of the radiating element. 18. The portable communications device of claim 16, wherein the loading structure is not an inductive loading element or a capacitive loading element. 19. The portable communications device of claim 16, wherein the antenna maintains similar radio-electric parameters at the at least two non-overlapping frequency bands. 20. A portable communications device comprising: a case operable to be held in a user's hand;a grounding element;an antenna mounted entirely within the case in operative relation to the grounding element, the antenna being configured to both radiate and receive electromagnetic waves corresponding to at least two non-overlapping frequency bands, wherein:the antenna comprises a radiating element comprising a first part and a second part, the first part comprising at least one conducting surface, the at least one conducting surface being configured to radiate and receive electromagnetic waves corresponding to at least two non-overlapping frequency regions and comprising a surface whose entire perimeter is a space-filling perimeter, the space-filling perimeter including at least ten segments connected such that no pair of adjacent segments defines a longer straight segment, all of the segments of the space-filling perimeter being smaller than a tenth of an operating free-space wavelength of the antenna, and the second part comprising a loading structure, a perimeter of the loading structure comprising a minimum of two segments and a maximum of nine segments, the segments being connected such that no pair of adjacent segments defines a longer straight segment;the loading structure is connected at least at one point to an edge of the at least one conducting surface;a maximum width of the loading structure is smaller than a quarter of a longest edge of the perimeter of the at least one conducting surface; anda portion of the edge of the at least one conducting surface to which at least one tip of the loading structure is connected is smaller than half of the edge of the at least one conducting surface to which the at least one tip of the loading structure is connected. 21. The portable communications device of claim 20, wherein the grounding element comprises a ground plane. 22. The portable communications device of claim 21, wherein the loading structure is placed over a supporting dielectric. 23. The portable communications device of claim 22, wherein a tip of the loading structure is open ended. 24. The portable communications device of claim 22, wherein the loading structure is a non-symmetric loading structure at least one conducting strip comprises a polygonal shape. 25. The portable communications device of claim 22, wherein a distance between the at least one point and a feeding point is smaller than a quarter of a shortest operating wavelength, and wherein the distance is measured as a shortest distance through the perimeter of the at least one conducting surface. 26. The portable communications device of claim 21, wherein the antenna is configured to radiate and receive electromagnetic waves corresponding to at least three frequency bands, and wherein the loading structure is configured to cause a bandwidth of the radiating element to be greater than a bandwidth of the first part in a second frequency region. 27. The portable communications device of claim 26, wherein the width of the loading structure is non-uniform. 28. The portable communications device of claim 26, wherein the at least one conducting surface and the loading structure lie on a common curved surface. 29. The portable communications device of claim 26, wherein the antenna maintains similar radio-electric parameters at the at least three frequency bands. 30. The portable communications device of claim 20, wherein the loading structure is configured to adjust a spacing between the at least two non-overlapping frequency bands. 31. The portable communications device of claim 30, wherein one of the at least two non-overlapping frequency bands is a frequency band that comprises 900 MHz. 32. The portable communications device of claim 30, wherein the antenna is shorter than a quarter of a central operating wavelength of a first of the at least two non-overlapping frequency bands. 33. The portable communications device of claim 32, wherein the antenna maintains similar radio-electric parameters at the at least two non-overlapping frequency bands. 34. The portable communications device of claim 33, wherein a distance between the at least one point and a feeding point is smaller than a quarter of a shortest operating wavelength, wherein the distance is measured as a shortest distance through the perimeter of the at least one conducting surface. 35. The portable communications device of claim 33, wherein a tip of the loading structure is open ended. 36. The portable communications device of claim 31, wherein one of the at least two non-overlapping frequency bands comprises UMTS. 37. The portable communications device of claim 36, wherein the width of the loading structure is non-uniform. 38. The portable communications device of claim 36, wherein the antenna is configured to radiate and receive electromagnetic waves corresponding to at least three frequency bands, and wherein a minimum operating frequency of the first part is substantially similar to a minimum operating frequency of the radiating element. 39. A portable communications device comprising: a case operable to be held in a user's hand;a grounding element;an antenna mounted entirely within the case and coupled to the grounding element, the antenna being configured to both radiate and receive electromagnetic waves corresponding to at least two non-overlapping frequency bands, wherein:the antenna comprises a radiating element comprising a first part and a second part, the first part comprising at least one conducting surface, and the second part comprising a loading structure, the loading structure having a space-filling perimeter, the space-filling perimeter including at least ten segments connected such that no pair of adjacent segments defines a longer straight segment, the segments being smaller than a tenth of an operating free-space wavelength of the antenna;the loading structure is connected at least at one point to an edge of the at least one conducting surface;the loading structure extends along at least one path having a length between two tips;a maximum width of the loading structure is smaller than a quarter of a longest edge of the perimeter of the at least one conducting surface; anda length of the at least one path of the loading structure is greater than the width of the loading structure. 40. The portable communications device of claim 39, wherein the grounding element comprises a ground plane. 41. The portable communications device of claim 40, wherein at least a part of a perimeter of the at least one conducting surface is shaped as a multi-segment curve comprising a plurality of segments, wherein each segment of the plurality of segments is smaller than a tenth of a longest operating free-space wavelength, and wherein the segments of the plurality of segments are arranged in such a way that no pair of adjacent and connected segments form another longer straight segment. 42. The portable communications device of claim 41, wherein the at least two non-overlapping frequency bands comprise multiple cellular telephone electromagnetic waves. 43. The portable communications device of claim 41, wherein a tip of the loading structure is open ended. 44. The portable communications device of claim 43, wherein the width of the loading structure is non-uniform. 45. The portable communications device of claim 39, wherein the antenna is configured to radiate and receive electromagnetic waves corresponding to at least three frequency bands, and wherein the loading structure is configured to cause a bandwidth of the radiating element to be greater than a bandwidth of the first part in a second frequency region. 46. The portable communications device of claim 45, wherein a distance between the at least one point and a feeding point is smaller than a quarter of a shortest operating wavelength, and wherein the distance is measured as a shortest distance through a perimeter of the at least one conducting surface. 47. The portable communications device of claim 45, wherein the at least one conducting surface and the loading structure lie on a common curved surface. 48. The portable communications device of claim 47, wherein the loading structure is placed over a supporting dielectric. 49. The portable communications device of claim 45, wherein one of the at least three frequency bands comprises UMTS. 50. The portable communications device of claim 39, wherein the loading structure is configured to adjust a spacing between the at least two non-overlapping frequency bands. 51. The portable communications device of claim 50, wherein the loading structure is placed over a supporting dielectric. 52. The portable communications device of claim 51, wherein the width of the loading structure is non-uniform. 53. The portable communications device of claim 52, wherein a tip of the loading structure is open ended. 54. The portable communications device of claim 39, wherein the at least two non-overlapping frequency bands comprise 900 MHz and 1800 MHz. 55. The portable communications device of claim 54, wherein the antenna is shorter than a quarter of a central operating wavelength of a first of the at least two non-overlapping frequency bands. 56. The portable communications device of claim 55, wherein the antenna maintains similar radio-electric parameters at the at least two non-overlapping frequency bands. 57. The portable communications device of claim 56, wherein a distance between the at least one point and a feeding point is smaller than a quarter of a shortest operating wavelength, and wherein the distance is measured as a shortest distance through a perimeter of the at least one conducting surface. 58. The portable communications device of claim 57, wherein a tip of the loading structure is open ended. 59. The portable communications device of claim 40, wherein the antenna is configured to radiate and receive electromagnetic waves corresponding to at least three frequency bands, and wherein a minimum operating frequency of the first part is substantially similar to a minimum operating frequency of the radiating element. 60. The portable communications device of claim 59, wherein the at least one of the three frequency bands comprises UMTS. 61. The portable communications device of claim 59, wherein the width of the loading structure is non-uniform. 62. The portable communications device of claim 59, wherein the loading structure is a non-symmetric loading structure.
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