The invention provides an apparatus of an antenna, especially a multi-band planar antenna.
The rapid growth of the wireless communication technology and the maturated 3rd generation portable wireless technology resulted to the trend of the integration of multi-band signal processing circuitry into the portable electronic devices, such as the wireless portable device, personal digital assistant and computer. The integration of multi-band signal processing circuitry enables the electronic devices to support multi-band portable network. Antenna, as a component to transmit and receive wireless signals is one of the key components of the above apparatus. The size of the antenna will need to be reduced to fulfill the trend to the slimmer and more compact design of the electronic devices.
The planar inverted-F antenna is widely applied to the communication system of the high-end electronic devices, due to its simple structure, ease of design and good antenna characteristics.
However, the 3-dimensional structure of the planar inverted-F antenna, which is needed to transmit and receive signals, becomes a limitation to the integration of varies electronic devices and the antenna. Varies electronic devices has different expectation to the size and outlook of the antenna; Also, planar inverted-F antenna needs high frequency inductive reactance and capacitive reactance to transmit and receive RF signals. Thus, resizing any part of the planar inverted-F antenna, such as changing the distance between the first metal plate 12 and the second metal plate 14, will change the capacitance of the antenna, consequently causing the differences in frequency response. Therefore, a same 3-dimensional planar inverted-F antenna cannot be applied into different electronic devices.
In the related art, for the same band, different antenna structures need to be designed to fulfill the requirement of the antenna size and structure from varies electronic devices. Therefore, the cost of the antenna design, and the cost of different molds to manufacture different antenna structures will increase the product manufacturing cost, consequently reduce the profit of the products. Thus, the present invention helps to reduce the manufacturing cost of the products to raise the product's competitiveness.
Present invention provides the apparatus of a multi-band planar antenna, and also provides the method to configure the multi-band planar antenna. The multi-band planar antenna is formed as a metal plate; therefore, it's easy to be integrated with the structure of electronic devices. The size of the grounding section of the antenna can be adjusted so that it can fits into different electronic devices.
The multi-band planar antenna revealed in present invention comprising a metal plate, a first radiation conductor, second radiation conductor and a grounding conductor. The metal plate comprises of a first edge and a second edge, and the first edge and the second edge is configured at each side of the metal plate respectively. The first radiation portion is configured on the upper of the metal plate by the first slot, and the first slot extends to the inner of the metal plate from the first edge. The second radiation portion is configured on the upper side of the metal plate adjacent to the second edge by a second slot and a third slot adjacent to the first radiation portion. The second slot extends to the inner of the plate from the second edge. The third slot is formed between the first and the second slot. The grounding portion is formed on the lower of the plate. The first and the second radiation portion transmit and receive the low-band and the high-band of RF signal respectively.
Present invention also revealed an electronic apparatus, having the multi-band planar antenna from the present invention configured internally. Furthermore, present invention also provides a method to adjust the size of the multi-band planar antenna. The size of the multi-band planar antenna from the present invention can be adjusted by adjusting the size of its grounding portion.
As illustrated in
The second radiation portion 24 comprises a second slot 240 and a third slot 242. The second radiation portion 24 is configured on the upper side of the metal plate 200 adjacent to the second edge 202 by a second slot 240 and a third slot 242. The second slot 240 extends to the inner of the plate from the second edge 202, and form an aperture on the second edge 202. The third slot 242 is formed between the first slot 220 and the second slot 240.
The first radiation portion 22 and the second radiation portion 24 is the structure of the multi-band planar antenna 20 to transmit and receive RF signal. The first radiation portion 22 and the second radiation portion 24 transmit and receive the low-band and the high-band of RF signal respectively. The said low-band RF signal channel comprises of GSM (Global System for Mobile Communication) 900 MHz, and the high-band RF signal channel comprises of GSM 1800 MHz, GSM 1900 MHz and WCDMA (Wideband Code Division Multiple Access) 2100 MHz.
In order to achieve the high frequency RF characteristic, as illustrated in
Multi-band planar antenna 20 is suitable to be embedded into the shell of an electronic device. As the multi-band planar antenna 20 is formed on the surface of a single metal plate 200, thus, it's easy to be assembled with the electronic device structures. The feeding dot F of the multi-band antenna is configured to the RF signal processing circuit of the electronic device, while the ground point G of the multi-band antenna is configured to the grounding conductor of the electronic device.
The overall size of the multi-band planar antenna 20 in present invention can be adjusted by adjusting the size of the grounding portion 26.
According to the research done by the inventor of present invention, adjusting the size of the grounding portion 36, 46 will not significantly alter the high frequency characteristic of multi-band planar antenna 30, 40.
Besides, the multi-band planar antenna 30, 40 are suitable for different electronic device because of the difference in size.
Based on the specification from
First, provides a multi-band planar antenna 20;
Second, with regards to the assembly requirement, adjust the size of the grounding portion 26.
Therefore, without altering the microwave characteristic, the size of the multi-band planar antenna 20 can be adjusted to fulfill the antenna size requirement from the electronic device, without the need to redesign first radiation portion 22 and second radiation portion 24.
Based on the above description of the embodiment, the flat structure of the multi-band planar antenna revealed in present invention benefits its assembly with the electronic device. At the same time, in order to fulfill the antenna size requirement from different electronic device without incurring extra cost to design and manufacture new molds, the overall size of the antenna can be adjusted by adjusting the size of the grounding portion, without altering its high frequency characteristic. Thus, the multi-band antenna and the associated electronic device revealed by present invention can save the antenna design and manufacture cost to increase the product's competitiveness.
Although the invention has been described with reference to a particular embodiment thereof, it will be apparent to one of the ordinary skill in the art that modifications to the described embodiment may be made without departing from the spirit of the invention. Accordingly, the scope of the invention will be defined by the attached claims not by the above detailed description.
Number | Date | Country | Kind |
---|---|---|---|
96115876 | May 2007 | TW | national |