KR20150118880A - Ultra-wideband antenna - Google Patents

Abstract

Disclosed is an ultra-wideband antenna. The ultra-wideband antenna is an ultra-wideband antenna for ultra-wideband communications with a portable mobile device and comprises: a dielectric substrate; at least one feed line formed on the dielectric substrate; a spiral radiation factor formed on the dielectric substrate and coupled with the feed line; and at least one additional dielectric substrate formed to be horizontal with respect to the dielectric substrate and arranged on the dielectric substrate. A flat printed cavity having an axial direction symmetric shape is formed on the additional dielectric substrate, and a printed cavity is coaxially arranged with the spiral radiation factor.

Description

[0001] ULTRA-WIDEBAND ANTENNA [0002]

The present invention is directed to ultra wideband (UWB) directional circular-field-polarized antennas for transmitting and receiving UWB first pulses and narrowband carrier-frequency-adjusted signals.

UWB circular-field-polarized antennas are actively used in fixed communication systems if it is necessary to transmit data to the end user with the clue that the user's antenna polarization is unknown. Examples of such devices may be communication devices arranged in the vicinity of the body (BAN standard). Flat spiral antennas are known types of UWB emitters that use the principles of self-complementarity and electrodynamic self-similarity. Slot and microstrip helical antennas have been widely used in various systems. In order to make unidirectional radiation of such antennas, an absorber or reflecting surface arranged on one side of the helix has been used. These techniques have fundamentally degraded the efficiency of antenna broadbandness.

(Metal plate) cavities (multilevel strip cavities, which are coupled to the feed line by the slot openings and used as UWB signal emitters are widely covered in the literature.) Non-resonant With the use of non-resonant apertures, similar systems can provide unidirectional characteristics. However, in such a case, difficulties arise due to the requirement to radiate the circularly polarized signal, Structure.

A helical antenna designed to increase cell coverage in a building from US 2012229363 and having a feed-point configured to deliver energy to the antenna, an energy absorbing backing to reduce the back lobe, cable connectors designed to convert input impedance to antenna impedance, coupled to a shaped microstrip line that is coupled to an energy absorbent backing, a logarithmic-spiral slot antenna and a cavity on the front of the energy-absorbing backing, and a feed point. a directional broadband antenna including a cable connector has been known. The problem with this solution is the high losses caused by the absorbent, while the losses could be reduced in the use of stacked strip cavities which complicate the antenna structure.

US 7106255 B2 includes a first patch having at least one slotted portion thereon, a second patch having at least one strip-shaped portion, wherein the slotted portions are at least partially cross- An antenna that forms a coupling region is known. The problem with such an antenna is that its gain rate is insufficient to realize long distance communication. In addition, the present antenna does not have circular polarization, and such absence can cause degradation of communication stability when the mutual position of the receiving and transmitting devices changes, and the member can be used for communication between fixed and portable mobile devices. I did not allow the use of the antenna.

The antenna disclosed in US 20040119642 Al is designed to transmit and receive circularly polarized signals and uses strip elements of special shape. The problems with the antenna were that its gain factor was insufficient for the applications.

It is therefore an object of the present invention to provide a method and apparatus for transmitting and receiving UWB short pulses and narrowband carrier-frequency-adjusted signals in an ultra wideband (UWB) directional circular-field- .

An ultra-wideband antenna according to an embodiment of the present invention for ultra-wideband communication with a portable mobile device includes a dielectric substrate 103, A spiral radiating element (107) formed on the dielectric substrate (103) and coupled to the at least one feed line (101, 102), at least one feed line And at least one additional dielectric substrate (108, 109) parallel to the substrate (103) and arranged on the dielectric substrate (103), wherein the flat printed cavities (110, 111) Is formed on at least one additional dielectric substrate (108, 109), the printing cavity being arranged coaxially with the helical radiating element (107).

In this case, the feed line may be implemented as a feeding microstrip line (MSL) 101 or 102.

On the other hand, the feed line may be implemented as a coplanar line.

On the other hand, on the dielectric substrate 103 side, a conductive material screen is formed facing the at least one additional dielectric substrate 108, 109, and the spiral radiating element 107 is connected to the conductive material screen 104 is formed as a helical slot 107 and the helical slot 107 is coupled to the at least one MSL 101, 102 via respective additional UWB MSL-slot transformers 105, .

In this case, the spiral slot may be embodied in a shape selected from the group including Archimedes spiral and log-periodic spiral.

On the other hand, the printing cavity is a metal printing cavity and can be implemented in the same shape with the same dimensions.

In this case, the shape of the metal printing cavity may be selected from the group including circular, elliptical, octagonal, and hexagonal.

On the other hand, the printing cavity is a metal printing cavity and may have axially symmetrical cut-outs.

On the other hand, on the dielectric substrate side, an absorbing material may be disposed opposite the at least one additional dielectric substrate (108, 109).

On the other hand, the at least one additional dielectric substrate 108, 109 may be separated from the dielectric substrate 103 by an air gap.

On the other hand, the at least one additional dielectric substrate 108, 109 may be spaced from the dielectric substrate 103 by a gap filled with a dielectric having a low dielectric permeability.

On the other hand, the at least one additional dielectric substrate 108, 109 may be spaced from the dielectric substrate 103 by a gap having a high dielectric permeability.

Meanwhile, the antenna system according to an embodiment of the present invention may be formed as an antenna array including at least two UWB antennas.

1 shows an embodiment of an antenna formed with two wire configurations,
FIG. 2 is a detailed view of the planar structure of the antenna structural elements according to FIG. 1. FIG.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figures 1 and 2 show an overall view of the antenna of the present invention when using two threaded spirals and two coupled cavities. The antenna of the present invention includes feeding microstrip lines (MSLs) 101 and 102, MLS substrate 103, MLS screen 104, UWB MLS-slot transformers 105 and 106, two wire spiral slots The substrate 108 and 109 of the coupling cavity, the combined printing cavities 110 and 111, the absorber 112 and the openings 113 and 114 in the cavity.

Referring to the drawings, a helical antenna 100 corresponding to the present invention may have the following structure. That is, the feeding microstrip lines MSLs 101 and 102 are formed on the dielectric substrate 103 and excite the slot line 107 through the respective UWB transformers 105 and 106 And the line may be formed in the MLS screen 104. [ As shown in Figure 1, each linear length of the slot can pass smoothly through the slot of the helix. The spiral may correspond to any of the known shapes, Archimedes, or logarithmic. Two flat support dielectric substrates 108 and 109 may be overlaid on top of the screen 104 of the MSLs 101 and 102 where the slotted spiral 107 is formed. Flat printing cavities 110 and 111 are formed on the substrates 108 and 109. The number and shape of the cavities 110 and 111 may vary, but two orthogonal axes (circular, square, cross, etc.) may be required for the quality of the circular polarization. A layer of absorber 112 may be arranged on the other side of helical antenna 100 to remove residual back radiation of slotted spiral 107. [ To simplify the design, the slotted helix may be formed of a single-thread and two threaded helixes. If two threaded helices are used, an in-phase UWB splitter of the feed line may be used.

The UWB antenna 100 (FIG. 1) implemented in accordance with the present invention can be used in fixed devices to transmit / receive UWB radio signals from small mobile devices operating in communication networks in the immediate vicinity of the body. In order to improve the performance of the networks, the polarization of the transmitted signal must be circular.

The UWB antenna 100 may be made of any material suitable for multilayer printed circuit boards such as FR-4, Rogers, and the like. The UWB antenna 100 may be powered through MSLs 101 and 102 formed on the screen of the dielectric substrate 103. The metal screen 104 is on the upper side of the substrate 103. The UWB MSL-slot transformers 105, 106 and the two threaded spiral slots 107 can be formed directly on the MLS screen 104.

The microwave signals arriving at the MSL 101, 102 come to the MSL-slot transformers 105, 106. Transformers 105 and 106 may transfer signals to spiral slot 107. The helical slot 107 may emit signals externally. In the initial state, the slot 107 may emit into the upper and lower hemispheres. When the cavities 110 and 111 are arranged above the slot 107, the microwave signal can be redistributed to the upper hemisphere.

In one embodiment of the present invention, the MSLs 101 and 102 may be fed from a single point using an additional microwave power splitter.

In one embodiment of the present invention, the MSL may be replaced with another type of conductor, for example a coplanar line. In this case, the transformers 105 and 106 also have to rely on their respective coplanar inputs.

In one embodiment of the invention, the helical slot 7 may be replaced by a helical microstrip line. In this case, the MSL 101,102 can be directly coupled to the helical line and the need to use the transformers 105,106 is weak. In this case, the screen 104 is also not necessary.

In one embodiment of the present invention, the spiral slot 107 may be formed as Archimedes or a log-periodic spiral or any other type of spiral.

Substrates 108 and 109 of bonding cavities are on a MLS substrate 103 at a specific distance from it while the upper surfaces of the substrates 108 and 109 are metallized printing cavities 110 and 111 thereon, Lt; / RTI > The metal bonded printing cavities 110 and 111 have cut-offs 113 and 114, respectively. The cut-offs may allow further improvement of the circular polarization characteristic.

In one embodiment of the present invention, the absorbent material 112 may be disposed on the underside of the MSL substrate 103.

In one embodiment of the present invention, the number of parallel substrates 108, 109 having metal bonded printing cavities 110, 111 may be at least two.

In one embodiment of the present invention, the substrates 108 and 109 and the MLS substrate 103 may have air gaps therebetween.

In one embodiment of the present invention, the substrates 108 and 109 and the MLS substrate 103 have gaps therebetween, and the gaps can be filled with a predetermined dielectric. Here, the predetermined dielectric may be any one of foam plastics, nickel, and cobalt.

In one embodiment of the present invention, the cavities 110 and 111 may be of a shape having substantially the same dimensions across their cross-shaped sections, e.g., circular, elliptical, octagonal, hexagonal, The deformation of the best shape from the circular polarization views of the transmitted signal may be circular while the rectangular strip cavities may cause deterioration of the circular polarization of the signal.

In one embodiment of the present invention, the cavities 110 and 111 have cut-offs therein, and the cut-offs may be formed as circular, elliptical, hexagonal, octagonal, or the like.

The antenna 100 has a beam pattern oriented primarily upward (corresponding to the view of FIG. 1). This characteristic can be achieved by the use of the absorber 112 on the lower side and the combined printing cavities 110, 111. This may enable the location of the mobile device to always use the antenna in applications in front of the antenna 100. It may also be possible to construct the antenna 100 with an array to give a special shape to the beam pattern (e.g., wide in the E-plane and narrow in the H-plane).

In addition, two threaded spiral slots 107 may be used for the antenna 100 as signal emitters. For this reason, wireless communication stability can be provided regardless of the position of the antenna on the mobile device with respect to the antenna 100.

Meanwhile, an antenna according to an embodiment of the present invention includes a substrate formed of a dielectric material, an MSL formed on a lower surface of a dielectric substrate designed as a feed antenna, a metal screen formed on an upper surface of the dielectric substrate, A UWB MSL-slot transformer implemented as a conical expansion at the ends of the MSL as well as the offs, and two threaded Archimedes spiral slots formed in the screen, a dielectric support arranged at a certain distance above the substrate, The set of dielectric support substrates having an air gap between all the layers and arranged on the surfaces of the support substrates and having a circular shape to provide the best characteristic of the circular polarization, A set of cut-offs formed in each of the coupling cavities and having a circular shape, The.

The antenna of the present invention can be used for wireless communications between devices arranged in the vicinity of the body, and the devices can be outside the body. The antenna of the present invention has a wide beam pattern on the horizontal plane and a narrow beam pattern on the vertical plane, so that its beam pattern can be fixed and have a high gain. Due to the high gain of the antenna, it can be used for communication in accordance with IEEE 802.15.6 for wireless networks operating at sufficiently long distances near the surface of the body. A device comprising an antenna of the present invention may be fixed (e. G., A TV set).

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be construed as limiting the scope of the invention as defined by the appended claims. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention.

101, 102: Feeding microstrip lines
103: MLS substrate
104: MLS screen
105, 106: UWB MLS-Slot Transformers
107: Two wire spiral slots
108, 109: substrates of bonding cavities
110, 111: Combined printing cavities
112: absorber
113, 114: openings in the cavities

Claims (13)

An ultra-wideband antenna for ultra-wideband communication with a portable mobile device,
A dielectric substrate;
At least one feed line formed on the dielectric substrate;
A helical radiating element formed on the dielectric substrate and coupled to the at least one feed line; And
And at least one additional dielectric substrate parallel to the dielectric substrate and arranged on the dielectric substrate,
Wherein a flat printed cavity of an axially symmetric shape is formed on the at least one additional dielectric substrate and the printing cavity is arranged coaxially with the helical radiating element. The method according to claim 1,
Wherein the feed line is implemented as a feeding microstrip line (MSL). The method according to claim 1,
Wherein the feed line is implemented as a coplanar line. 3. The method of claim 2,
A conductive material screen is formed on the dielectric substrate side facing the at least one additional dielectric substrate,
Said spiral radiating element being formed as a spiral slot in said conductive material screen,
Wherein the helical slot is coupled to the at least one MSL via a respective additional UWB MSL-slot transformer. 5. The method of claim 4,
Wherein the spiral slot is embodied in a shape selected from the group consisting of an Archimedes spiral and a log-periodic spiral. The method according to claim 1,
Wherein the printing cavity is a metal printing cavity and is implemented in the same shape with the same dimensions. The method according to claim 6,
Wherein the shape of the metal printing cavity is selected from the group consisting of circular, elliptical, octagonal, hexagonal. The method according to claim 1,
Wherein the printing cavity is a metal printing cavity and has axially symmetrical cut-outs. The method according to claim 1,
And an absorbing material may be disposed on the dielectric substrate side in opposition to the at least one additional dielectric substrate. The method according to claim 1,
Wherein the at least one additional dielectric substrate is spaced from the dielectric substrate by an air gap. The method according to claim 1,
Wherein the at least one additional dielectric substrate is spaced from the dielectric substrate by a gap filled with a predetermined dielectric. 12. The method of claim 11,
Wherein the predetermined dielectric material is foam plastics. In an antenna system in which a plurality of antennas are formed as an antenna array,
A first antenna; And
And a second antenna,
Wherein the first antenna is an ultra-wideband antenna according to any one of claims 1 to 12,
Wherein the second antenna is an UWB antenna according to any one of claims 1 to 12.

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