1. Field of the Invention
The present invention relates generally to an antenna, and more particularly to a multi-band antenna used in a portable electronic device, such as a notebook.
2. Description of the Prior Art
With the development of wireless communication, more and more people hope to own portable electronic devices, such as a notebook, capable of connecting to Internet. The systems of the WLAN (Wireless Local-area Network) and the GPRS (General Packer Radio Service) can make the portable electronic devices, such as a notebook, work in Internet. The GPRS is a wide-area network and the data transfer speed thereof is 30 Kbps˜50 Kbps. The WLAN is a local-area network and the data transfer speed is 11 Mbps. The portable electronic device, such as a notebook can choose different Wireless cards for jointing to Internet.
At present, the WLAN is based on Bluetooth technology standard or IEEE802.11 series technology standard. The frequency band of an antenna is 2.4 GHz and 5 GHz in IEEE802.11 series technology standard, but is 900 Mhz, 1800 MHz and 1900 MHz in GPRS technology standard. So, most antennas used in the notebooks work at the above-mentioned frequency bands in recent years.
PIFA (Planar Inverted-F Antenna) is a kind of minitype antenna usually used in a portable electronic device, such as a notebook. PIFA has compact structure, light weight, perfect impedance match, desired horizontal polarization and vertical polarization, and is easy to achieve multi-bands. So, more and more PIFAs are used in the portable electronic devices.
IEEE802.11 series technology standard comprises IEEE802.11a, IEEE802.11b and other different technology standards. The corresponding frequencies are different because of the different technology standards. So, PIFA usually has two radiating elements for providing two different frequencies.
The two different frequencies of the PIFA basically satisfy the requirements of the frequency band, while the radiating field usually has blind field making the signal not being radiated in some directions because of the characteristics of the two frequencies of the PIFA.
In the prior art, two same PIFAs being mirror image arranged to consist a PIFA system decrease radiating blind field. However, because the two PIFAs are mirror image arranged, a pair of radiating element ends of providing common frequency are mirror image arranged too, the PIFA system cannot distinguish which PIFA being a primary antenna and which being a secondary antenna, thus making the PIFA system occurring self-excitation. The self-excitation influences the natural work of the PIFA system. The radiating fields of the two mirror image arranged radiating elements occur superposition and radiating blind field.
Hence, in this art, a multi-band antenna to overcome the above-mentioned disadvantages of the prior art will be described in detail in the following embodiment.
A primary object, therefore, of the present invention is to provide a multi-band antenna which can avoid self-excitation and fetch up radiating blind field.
In order to implement the above object and overcome the above-identified deficiencies in the prior art, a multi-band antenna adapted for used in a portable electronic device, comprising: a first antenna comprising a radiating element comprising a first radiating element, a grounding element, and a first connecting element connecting the radiating element and the grounding element; a second antenna comprising a radiating portion comprising a first radiating portion, the grounding element share with the first antenna, and a second connecting element connecting the radiating portion and the grounding element; wherein the free ends of the first radiating element and the first radiating portion locate on different lines.
Other objects, advantages and novel features of the invention will become more apparent from the following detailed description of a preferred embodiment when taken in conjunction with the accompanying drawings.
Reference will now be made in detail to a preferred embodiment of the present invention.
Referring to
The first radiating element 11 comprises a first radiating arm 111 partaking with the second radiating element 12, a second radiating arm 112 perpendicularly extending from one end of the first radiating arm 111, a third radiating arm 113 being coplanar with the second arm 112 and located at different beelines, and a fourth radiating arm 114 connecting the second radiating arm 112 and the third radiating arm 113. The third radiating arm 113 and the fourth radiating arm 114 together form an L-shape. The second radiating element 12 comprises a fifth radiating arm 115 extending from one end of the first radiating arm 111 and located in the common beeline with the second radiating arm 112 extending along an opposite direction. The third radiating element 13 perpendicularly extends from the other end of the first radiating arm 111 and is parallel to the fifth radiating arm 115.
The first feeding cap 14 is a rectangular sheet and perpendicularly extends from the joint of the third radiating element 13 and the first radiating arm 111. The First feeding line comprises an inner conductor soldering at the first feeding cap 14 and an outer conductor soldering at the grounding element 16.
The grounding element 16 comprises a smaller first grounding plane 161 being coplanar with the three radiating elements 11, 12, 13 of the first antenna 1 and a bigger second grounding plane 162 perpendicular to the first grounding plane 161. A rectangular gap 17 is formed at a middle portion of the first grounding plane 161 for avoiding the third radiating arm 113 and the fourth radiating arm 114 extending and contacting the first grounding plane 161. Two longitudinal ends of the second grounding plane 162 each have an installing section 3 coplanar with the first grounding plane 161. The installing section 3 has an installing hole 30 for locking the multi-band antenna 10 on a portable electronic device, such as a notebook.
The first connecting element 15 extends from one end of the first grounding plane 161 connecting to the joint of the third radiating element 13 and the first radiating arm 111.
The first radiating element 11, the second radiating element 12, the third radiating element 13, the first connecting element 15, and the first grounding plane 161 are coplanar.
The first radiating portion 21 of the second antenna 2 operates at 2.4 GHz of a lower frequency band of the IEEE802.1 a technology standard. The second radiating portion 22 operates at 5 GHz of a higher frequency band of the IEEE802.11b/g technology standard. The third radiating portion 23 is complementarity to the second radiating portion 22 and enhances frequency band of the higher frequency.
The first radiating portion 21 comprises a first radiating branch 211, a second radiating branch 212 extending perpendicularly from one end of the first radiating branch 211 and being coplanar with the first radiating branch 211, a third radiating branch 213 extending from one end of the second radiating branch 212 and perpendicular to the plane in which the second radiating branch 212 is located. The third radiating branch 213 of the second antenna 2 and the first radiating arm 11 of the first antenna 1 are not coplanar. The second radiating branch 212 and the third radiating branch 213 together form an L-shape structure. The second radiating portion 22 comprises the common first radiating branch 211 sharing with the first radiating portion 21 and a fourth radiating branch 214 extending perpendicularly from one end of the first radiating branch 211 to an opposition direction compared with the second radiating branch 212.
The second connecting element 25 extends from the other end of the first grounding plane 161 to a joint of the third radiating portion 23 and the first radiating branch 211. The second connecting element 25 and third radiating portion 23 locate on one common line.
The second feeding cap 24 is a rectangular sheet and perpendicularly extends from the joint of the third radiating portion 23 and the first radiating branch 211. The First feeding line comprises an inner conductor soldering at the second feeding cap 24 and an outer conductor soldering at the grounding element 16.
The first radiating element 11 and the first radiating portion 21 operate at the same frequency, two free end portions of the first radiating element 11 and the first radiating portion 21 locate in different planes and are not arranged in a line because of the above design of the first radiating element 11 of the first antenna 1 and the first radiating portion 21 of the second antenna 2. The radiating field of the first antenna 1 and the second antenna 2 are not overlapped because of above design. The antenna module (not shown) connecting to the multi-band antenna 10 is easy to distinguish which is the main antenna and which is the secondary antenna for avoiding the multi-band antenna 10 occurring self-excitation. The secondary antenna can fully fetch up radiating blind field of the main antenna and the multi-band antenna 10 has better radiating performance of the lower frequency.
It is to be understood, however, that even though numerous characteristics and advantages of the present invention have been set forth in the foregoing description, together with details of the structure and function of the invention, the disclosure is illustrative only, and changes may be made in detail, especially in matters of shape, size, and arrangement of parts within the principles of the invention to the full extent indicated by the broad general meaning of the terms in which the appended claims are expressed.
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94141658 A | Nov 2005 | TW | national |
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Number | Date | Country | |
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20070120753 A1 | May 2007 | US |