This application is based upon and claims the benefit or priority from Japanese patent application No. 2007-122373, filed on May 7, 2007, the disclosure of which is incorporated herein its entirety by reference.
This invention relates to an antenna unit and, more particular, to an antenna unit for use in a frequency band of a wireless Local Area Network (LAN).
In the manner which is well known in the art, the wireless LAN is an LAN using a transmission path except for a wired cable, such as electric waves, infrared rays, or the like.
Standardization of the wireless LAN is developed in IEEE (Institute of Electrical and Electronics Engineers) 802.11 Committee. That is, the IEEE 802.11 Committee develops specifications of the standard of the wireless LAN.
For example, IEEE 802.11a is a specification of a high-speed wireless LAN and a wireless access for 5 GHz band where the IEEE 802.11 Committee develops. A communication rate (a transfer rate) is about 20 Mbits/sec to 50 M bits/sec. A CSMA/CD (carrier sense multiple access with collision detection) is used as an MAC (media access control). A modulation method of a physical layer is an OFDM (orthogonal frequency division multiplex).
On the other hand, IEEE 802.11b is a specification of the wireless LAN where the IEEE 802.11 Committee standardizes in September, 1999. The IEEE 802.11b uses frequencies of 2.4 GHz band and uses a direct spread (DS) as a modulation method. A transmission rate (a transfer rate) is 11 Mbits/sec or 5.5 Mbits/sec.
Furthermore, IEEE 802.11g is one of standards for the wireless LAN where the IEEE 802.11 Committee develops in June, 2003 and a specification for carrying out communications about 54 Mbits/sec at 2.4 GHz band. The OFDM is used as a modulation method. Accordingly, the IEEE 802.11g uses the frequencies of 2.4 GHz band which is similar to that of the IEEE 802.11b and supports the transfer rate of 54 Megabits/sec which is about five times of that of the IEEE 802.11b. In contrast to the IEEE 802.11a for supporting the transfer rate of 54 Mbits/sec, the IEEE 802.11g maintains compatibility with the IEEE 802.11b. In addition, although a maximum transfer rate of 54 Mbits/sec is similar to that of the IEEE 802.11a. the 2.4 GHz band is a “busy” frequency band where a lot of equipments except for the wireless LAN use. Therefore, it is said that a real transfer rate in the IEEE 802.11g becomes later than that of the IEEE 802.11a.
Inasmuch as the IEEE 802.11b and the IEEE 802.11g use the same use frequency band of 2.4 GHz band in the manner which is described above, both are collectively called IEEE 802.11b/g herein.
Various antenna devices used in the frequency band of the wireless LAN are already known in the art. By way of example, JP 2006-50517 A, which corresponds to U.S. Pat. No. 7,084,820 B2, discloses an antenna device having a resonance frequency of 2.456 GHz. This patent document will be called a first patent document. The first patent document discloses, in
At any rate, the first patent document discloses the antenna device which comprises the board having the first surface and the antenna pattern (a first transmission/reception pattern), formed on the first surface, for transmitting and receiving a radio signal (the radio wave) having a first frequency band.
On the other hand, JP 2005-79867 A discloses a flat-shaped antenna which has a sufficient input impedance and carries out efficient operation as the antenna although a metallic cabinet or a metallic part exists nearby. This patent document will be called a second patent document. The second patent document disclosed the flat-shaped antenna where favorable impedance matching is carried out at a frequency band of 2.4 GHz. More specifically, the flat-shaped antenna disclosed in the second patent document comprises a printed board made of a dielectric, a first antenna radiation element serving as one radiation element of a dipole antenna, a second antenna radiation element serving as another radiation element of the dipole antenna, a non-feeding element formed by a conductive pattern, a microstrip line serving as a feeding line for a radio wave, and a ground conductor for forming a ground side of the feeding line. The first antenna radiation element, the non-feeding element, and the microstrip line are formed on one surface (a front side, a first surface) of the printed board by a conductive pattern. The second antenna radiation element and the ground element are formed on another surface (a back side, a second surface) of the printed board by a conductive pattern. The dipole antenna is composed by feeding a high-frequency signal from an end portion of the microstrip line. The first antenna radiation element and the microstrip line are connected to each other around a central portion of the printed board. In addition, the non-feeding element may be omitted.
At any rate, the second patent document discloses the flat-shaped antenna (an antenna device) comprising a board having first and second surfaces (front and back sides) opposite to each other and the conductive pattern (a first transmission/reception pattern), formed on the first and the second surfaces, for transmitting and receiving the radio signal (the radio wave) having the first frequency bond.
In addition, JP 6-188610 A discloses a printed circuit board where patterns for antenna and a balun are formed on both sides or one side of the printed circuit board. This patent document will be called a third patent document. In the third patent document, a pattern for a dipole antenna and a coaxial guide fixing pattern for the balun are formed on a first surface (a frond side) of the printed circuit board while a branch conductive pattern is formed on a second surface (a back side) or the first surface of the printed circuit board. A central line of the coaxial guide is soldered to a feeding point of the dipole antenna while an outer conductor of the coaxial guide is soldered to the feeding point of the dipole antenna and the branch conductive pattern. The antenna and the balun disclosed in the third patent document are mounted inside a case of a portable radio equipment and use a frequency band between 421 MHz and 440 MHz.
At any rate, the third patent document discloses the printed circuit board (an antenna device) comprising a board having first and second surfaces (front and back sides) opposite to each other and the conductive pattern (a first transmission/reception pattern), formed on the first and the second surfaces (or the first surface) of the printed circuit board, for transmitting and receiving a radio signal (a radio wave) having a first frequency band.
Inasmuch as each of the antenna devices disclosed in the above-mentioned first through third patent documents is an antenna device where the antenna pattern is formed on the board, they are called board antennas.
In the manner which is described above, each of the antenna devices disclosed in the first through the third patent documents discloses only the antenna device (the board antenna) comprising the board and the antenna pattern (the first transmission/reception pattern) formed on one side (or both sides) of the board. The antenna devices can transmit and receive only the radio signal (the radio wave) having one kind of frequency band (the first frequency band).
It is therefore an exemplary object of the present invention to provide an antenna unit which is capable of transmitting and receiving radio signals (radio waves) having different two kinds of frequency bands.
It is another exemplary object of the present invention to provide an antenna unit which is capable of transmitting and receiving radio signals (radio waves) having different two kinds of frequency bands used in a wireless LAN.
Other objects of this invention will become clear as the description proceeds.
According to an exemplary aspect of this invention, an antenna unit comprises a board having first and second surfaces opposite to each other, a first antenna pattern, formed on the first surface of the board, for transmitting and receiving a first radio wave having a first frequency band, and a second antenna pattern, formed on the second surface of the board, for transmitting and receiving a second radio wave having a second frequency band different from the first frequency band. The first antenna pattern and the second antenna pattern are disposed so as to be opposed to each other through the board with they electrically disconnected.
Referring to
The antenna unit 10 comprises a board or substrate 12 having a first surface (a front side, an upper surface) 12u and a second surface (a rear side, a lower surface) 12d which are opposite to each other.
Herein, an orthogonal coordinate system (X, Y, Z) having, as an origin point thereof, a center of the board 12 is used as shown in
The board 12 has a substantially rectangular parallelepiped (rectangular plate) shape which has a length B, a width W, and a thickness (a height) T. In the example being illustrated, the length B is equal to 18.6 mm, the width W is equal to 25.5 mm, and the thickness (the height) T is equal to 0.8 mm. In addition, in the example being illustrated, the board (the substrate) 12 is made of a dielectric board having relative permittivity εr of 4.4.
The board 12 has the upper surface (the front side) 12u, the lower surface (the rear side) 12d, a front surface 12f, a back surface 12b, a right-side surface 12rs, and a left-side surface 12ls. As shown in
The antenna unit (the board antenna) 10 comprises a first antenna pattern 20 formed on the first surface (the upper surface, the front side) 12u of the board 12 and a second antenna pattern 30 formed on the second surface (the lower surface, the rear side) 12d of the board 12. The first antenna pattern 20 is for transmitting and receiving a first radio wave having a first frequency band which will later be described. The second antenna pattern 30 is for transmitting and receiving a second radio wave having a second frequency band which will later be described. The first frequency band and the second frequency band are different from each other. As shown in
In the example being illustrated, the first frequency band is a frequency band of 2.4 GHz which is used in IEEE 802.11b/g while the second frequency band is a frequency band of 5 GHz which is used in IEEE 802.11a.
As shown in
Referring now to
More specifically, the first antenna pattern 20 comprises first and second L-shaped wiring pattern 21 and 22, an L-shaped ground pattern 24, and an L-shaped signal pattern 26.
The first and the second L-shaped wiring pattern 21 and 22 are formed at a first side (a right-hand side) and a second side (a left-hand side) which are opposite to each other with respect to the center line X of the board 12, respectively. The first and the second L-shaped wiring patterns 21 and 22 have first and second tips 21a and 22a, respectively, which are disposed at a distance from each other through the center line X of the board 12. The first L-shaped wiring pattern 21 and the second L-shaped wiring pattern 22 are formed on the upper surface 12u of the board so as to be substantially symmetric with respect to the center line X of the board 12.
The first L-shaped wiring pattern 21 comprises a first orthogonal wiring portion 211 and a first parallel wiring portion 212. The first orthogonal wiring portion 211 extends in a direction (a right direction) Y orthogonal to the center line X along the front surface 12f of the board 12 so as to leave the center line X of the board 12. The first parallel wiring portion 212 extends in parallel with the center line X along the right-side surface 12rs of the board 12 from a tip of the first orthogonal wiring portion 211.
Likewise, the second L-shaped wiring portion 22 comprises a second orthogonal wiring portion 221 and a second parallel wiring portion 222. The second orthogonal wiring portion 221 extends in a direction (a left direction) Y orthogonal to the center line X along the front surface 12f of the board 12 so as to leave the center line X of the board 12. The second parallel wiring portion 222 extends in parallel with the center line X along the left-side surface 12ls of the board 12 from a tip of the second orthogonal wiring portion 221.
In addition, each of the first and the second L-shaped wiring patterns 21 and 22 has a line width of 1 mm.
The L-shaped ground pattern 24 has an end 24a which is electrically connected to the second tip 22a of the second L-shaped wiring pattern 22. The L-shaped ground pattern 24 is formed on the first surface 12u of the board 12 such that the L-shaped ground pattern 24 lies inside the second L-shaped wiring pattern 22 with a space and along the second L-shaped wiring pattern 22. On the other hand, the L-shaped signal pattern 26 has an end 26a which is electrically connected to the first tip 21a of the first L-shaped wiring pattern 21. The L-shaped signal pattern 26 is formed on the first surface 12u of the board 12 such that the L-shaped signal pattern 26 lies inside the L-shaped ground pattern 24 with a space and along the L-shaped ground pattern 24.
The antenna unit (the board antenna) 10 employs, as a feeding line, a coaxial cable 40 shown in
As shown in
That is, at the tip portion 40a of the coaxial cable 40, the central conductor 42 is electrically connected to another end 26b of the L-shaped signal pattern 26 by a solder (not shown) and the outer conductor 41 is electrically connected to another end 24b of the L-shaped ground pattern 24 by a solder (not shown).
Referring now to
More specifically, the first conductive pattern 31 comprises a first widened portion 311 having a rectangular shape of a length B1 and a width W1, a first main wiring pattern 312, and a first sub wiring pattern 313. The first widened portion 311 is disposed at a position corresponding to a curved portion of the first L-shaped wiring pattern 21 and has the width B1 which is wider than the line width of the first L-shaped wiring portion 21. The first main wiring pattern 312 extends in parallel with the center line X of the board 12 along the right-side surface 12rs of the board 12 from the first widened portion 311 so as to be opposed to the first parallel wiring portion 212. The first main wiring pattern 312 has a tip portion 312a which is bended at the right angle in a direction to get near the center line X of the board 12. The first sub wiring pattern 313 extends from the first widened portion 311 and has a length L2 which is shorter than a wiring length L1 (see
Similarly, the second conductive pattern 32 comprises a second widened portion 321 having a rectangular shape of the length B1 and the width W1, a second main wiring pattern 322, and a second sub wiring pattern 323. The second widened portion 321 is disposed at a position corresponding to a curved portion of the second L-shaped wiring pattern 22 and has the width B1 which is wider than the line width of the second L-shaped wiring portion 22. The second main wiring pattern 322 extends in parallel with the center line X of the board 12 along the left-side surface 12ls of the board 12 from the second widened portion 321 so as to be opposed to the second parallel wiring portion 222. The second main wiring pattern 322 has a tip portion 322a which is bended at the right angle in a direction to get near the center line X of the board 12. The second sub wiring pattern 323 extends from the second widened portion 321 and has the length L2 which is shorter than the wiring length L1 (see
Referring to
In the manner which is known in the art, it is generally preferable that a voltage standing wave ratio (VSWR) of an antenna unit is close to one as much as possible as a necessary antenna characteristic. Desirably, the VSWR may be two or less.
As apparent from
On the other hand, as apparent from
That is, it is possible for the antenna unit (the board antenna) 10 according to the first exemplary embodiment of this invention to obtain a matching characteristic not only at the 2.4 GHz band but also at the 5 GHz band. In other words, the antenna unit (the board antenna) 10 according to the first exemplary embodiment of this invention serves as a wireless LAN multi-band board antenna which is possible to transmit and receive the first radio wave having the first frequency band of 2.4 GHz for the IEEE 802.11b/g and the second radio wave having the second frequency band of 5 GHz for the IEEE 802.11a.
Herein, in the pair of conductive patterns 31 and 32 of the second antenna pattern 30, the first and the second widened portions 311 and 321 are for covering (securing) a band width of the second frequency band of 5 GHz and a combination of the first and the second main wiring patterns 312 and 322 and the first and the second sub wiring patterns 313 and 323 is for bring the VSWR near to one.
In addition, the second antenna pattern 30 formed on the second surface (the lower surface, the rear side) 12d of the board 12 is not restricted to that illustrated in
The first main wiring pattern 312A has a tip portion which is not bended. The first main wiring pattern 312A extends in parallel with the center line X of the board 12 along the right-side surface 13rs of the board 12 from the first widened portion 311 so as to be opposed to the first parallel wiring portion 212. The first main wiring pattern 312A had the wiring length L1 of 9 mm.
The first sub wiring pattern 313A is disposed opposite to the first orthogonal wiring portion 211 (
The first sub wiring pattern 313B comprises a first sub wiring portion 313B-1 and a second sub wiring portion 313B-2. The first sub wiring portion 313B-1 is apart from the first main wiring pattern 312 by the predetermined distance D1 and extends in parallel with the first main wiring pattern 312. The second sub wiring portion 313B-2 is apart from the first sub wiring portion 313B-1 by the predetermined distance D1 and extends in parallel with the first main wiring pattern 312.
In the above-mentioned exemplary aspect of this invention, the first frequency band may, for example, be a frequency band of 2.4 GHz and the second frequency band may, for example, be a frequency band of 5 GHz. The board may have a center line. In this event, the first antenna pattern may extend in an L-shaped fashion at both sides with respect to the central line of the board and the first antenna pattern may have a substantially U-shape as a whole. The second antenna pattern may include a pair of conductive patterns which are symmetrically formed at the both sides with respect to the center line of the board.
The first antenna pattern preferably may include first and second L-shaped wiring pattern formed at first and second sides opposite to each other with respect to the center line of the board, an L-shaped ground pattern, and an L-shaped signal pattern. The first and the second L-shaped wiring patterns may have first and second tips, respectively, which are opposed to each other with a space through the center line of the board. The first and the second L-shaped wiring patterns may be substantially symmetric with respect to the center line of the board. The L-shaped ground pattern may have a first end which is electrically connected to the second tip of the second L-shaped wiring pattern. The L-shaped ground pattern may be formed on the first surface of the board such that the L-shaped ground pattern lies inside the second L-shaped wiring pattern with a space and along the second L-shaped wiring pattern. The L-shaped signal pattern may have a first end which is electrically connected to the first tip of the first L-shaped wiring pattern. The L-shaped signal pattern may be formed on the first surface of the board such that the L-shaped signal pattern lies inside the L-shaped ground pattern with a space and along the L-shaped ground pattern. The antenna unit may further include a coaxial cable having a tip portion which is connected to the first antenna pattern. In this event, the coaxial cable includes a central conductor and an outer conductor. The central conductor is connected to a second end of the L-shaped signal pattern at the tip portion of the coaxial cable. The outer conductor is connected to a second end of the L-shaped ground pattern at the tip portion of the coaxial cable.
On the other hand, the pair of conductive patterns preferably may include a first conductive pattern disposed on the second surface of the board so as to be opposed to the first L-shaped wiring pattern through the board, and a second conductive pattern disposed on the second surface of the board so as to be opposed to the second L-shaped wiring pattern through the board.
The first L-shaped wiring pattern may include a first orthogonal wiring portion extending in a direction orthogonal to the center line of the board so as to leave the center line of the board, and a first parallel wiring portion extending in parallel with the center line of the board from a tip of the first orthogonal wiring portion. The said second L-shaped wiring pattern may include a second orthogonal wiring portion extending in a direction orthogonal to the center line of the board so as to leave the center line of the board, and a second parallel wiring portion extending in parallel with the center line of the board from a tip of the second orthogonal wiring portion. In this event, the first conductive pattern preferably may include, at least, a first widened portion and a first main wiring pattern. The first widened portion is disposed at a position corresponding to a curved portion of the first L-shaped wiring pattern. The first widened portion has a rectangular shape of a width which is wider than a line width of the first L-shaped wiring pattern. The first main wiring pattern extends in parallel with the center line of the board from the first widened portion so as to be opposed to the first parallel wiring portion. The second conductive pattern preferably may include, at least, a second widened portion and a second main wiring pattern. The second widened portion is disposed at a position corresponding to a curved portion of the second L-shaped wiring pattern. The second widened portion has a rectangular shape of a width which is wider than a line width of the second L-shaped wiring pattern. The second main wiring pattern extends in parallel with the center line of the board from the second widened portion so as to be opposed to the second parallel wiring portion. The first main wiring pattern may have a tip portion which is bended at the right angle in a direction to get near the center line of the board. The second main wiring portion may have a tip portion which is bended at the right angle in a direction to get near the center line of the board.
Furthermore, the first conductive pattern preferably may further include a first sub wiring pattern which extends from the first widened portion. The first sub wiring pattern has a length which is shorter than a wiring length of the first main wiring pattern. The second conductive pattern preferably may further include a second sub wiring pattern which extends from the second widened portion. The second sub wiring pattern has a length which is shorter than a wiring length of the second main wiring pattern. The first sub wiring pattern may be apart from the first main wiring pattern by a predetermined distance and may extend in parallel with the first main wiring pattern. The second sub wiring pattern may be apart from the second main wiring pattern by the predetermined distance and may extend in parallel with the second main wiring pattern. Alternatively, the first sub wiring pattern may be disposed to be opposed to the first orthogonal wiring portion so as to get near the center line of the board from the first widened portion. The second sub wiring pattern may be disposed to be opposed to the second orthogonal wiring portion so as to get near the center line of the board from the second widened portion.
An exemplary advantage according to the invention is that the antenna unit can transmit and receive radio signals (radio waves) having different two kinds of frequency bands. This is because the first antenna pattern for transmitting and receiving the first radio wave having the first frequency band is formed on the first surface of the board, the second antenna pattern for transmitting and receiving the second radio wave having the second frequency band is formed on the second surface of the board, and the first antenna pattern and the second antenna pattern are disposed so as to be opposed to each other through said board with they electrically disconnected.
While the invention has been particularly shown and described with reference to exemplary embodiments thereof, the invention is not limited to these embodiments. it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the sprit and scope of the present invention as defined by the claims. For example, the first and the second antenna patterns are restricted to those in the above-mentioned exemplary embodiments, any pattern having various shapes may be adopted. At any rate, the first antenna pattern may transmit and receive the first radio wave having the first frequency band while the second antenna pattern may transmit and receive the second radio wave having the second frequency band. In addition, although each of the pair of conductive patterns composing the second pattern comprises the widened portion, the main wiring pattern, and the sub wiring pattern in the above-mentioned exemplary embodiments, the sub wiring pattern may be deleted from the conductive pattern.
Number | Date | Country | Kind |
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2007-122373 | May 2007 | JP | national |