1. Field of the Invention
The present disclosure relates to a radio-frequency processing device and method and related wireless communication device, and more particularly, to a radio-frequency processing device and method and related wireless communication device capable of obtaining different matching states, varying VSWR and extending operating bandwidth to lower bands without extending the dimension of an antenna.
2. Description of the Prior Art
Mobile devices utilize antennas to emit and receive radio waves, so as to access a mobile system. Therefore, to facilitate a user's access to the mobile system, an ideal antenna should maximize its bandwidth within a permitted range, while minimizing physical dimensions to accommodate the trend for smaller-sized electronic products. However, with the advance of wireless communication technology, more and more bands are used for the mobile system, such as 850 band (824-894 MHz), 900 band (880-960 MHz), 1800 Band (1710-1880 MHz) , 1900 band (1850-1990 MHz) and 2100 band (1920-2170 MHz). Recently, the mobile system is going to evolve from 3G to 4G, i.e. Long-Term Evolution (LTE) system, and extra bands below the 850 band, i.e. BC13 (764 MHz to 787 MHz) and BC17 (704 MHz to 746 MHz), are added. In such a situation, an antenna of a 4G mobile device covers more frequency ranges and has larger dimension due to the extra bands below the 850 band. Besides, MIMO (Multiple Input Multiple Output) technology has been involved to improve data throughput, which means that the mobile device needs 2 or more antennas for 4G, and thus, a much fewer volumes are available for these antennas.
Therefore, how to efficiently increase operating bands for a mobile antenna while meeting the small-sized requirement has become a challenge for this industry.
The disclosure therefore provides a radio-frequency processing device and method and related wireless communication device.
A radio-frequency (RF) processing device, for a wireless communication device, is disclosed. The RF processing device comprises an antenna, an RF-signal processing module, a controller, for generating a control signal according to a band switching signal, and a matching adjustment module for adjusting an impedance between the antenna and the RF-signal processing module according to the control signal.
A radio-frequency (RF) processing method, for a wireless communication device, is disclosed. The RF processing method comprises adjusting an impedance between an antenna and an RF-signal processing module of the wireless communication device according to a band switching signal.
A wireless communication device is disclosed, and comprises a baseband module, and a radio-frequency (RF) processing device. The RF processing device comprises an antenna, an RF-signal processing module, a controller, for generating a control signal according to a band switching signal provided by the baseband module, and a matching adjustment module for adjusting an impedance between the antenna and the RF-signal processing module according to the control signal.
These and other objectives of the present invention will no doubt become obvious to those of ordinary skill in the art after reading the following detailed description of the preferred embodiment that is illustrated in the various figures and drawings.
Please refer to
Therefore, the impedance between the antenna 104 and the RF-signal processing module 106 corresponds to the used frequency band. As a result, different impedances generated by the matching adjustment module 110 correspond to different frequency bands delivered to the RF-signal processing module 106.
In addition, the sensor 112 is utilized for sensing a surrounding status of the wireless communication device 10, e.g. whether an object is approaching or whether a user holds the wireless communication device 10, and generates a sensing result SEN for the controller 108, such that the controller 108 can further control the matching adjustment module 110 to adjust the impedance between the antenna 104 and the RF-signal processing module 106.
Note that,
For example, please refer to
Note that,
On the other hand, the controller 108 shown in
In the prior art, a common method to broaden operating bandwidth of a mobile antenna, especially to expand the lower bands, is increasing the current flow route, meaning extension of the antenna. Oppositely, the present disclosure utilizes the matching adjustment module 110 and the controller 108 to obtain different impedances between the antenna 104 and the RF-signal processing module 106, so as to vary the VSWR and extend the operating bandwidth of the antenna 104 without extending the antenna 104. In such a situation, a 3G antenna can further support BC13 (764 MHz to 787 MHz) and BC17 (704 MHz to 746 MHz) with the matching adjustment module 110 and the controller 108, and may be reused in a 4G (LTE) system, so as to decrease manufacturing cost and time to market.
The operating principle of the controller 108 can further be summarized in a process 30 as shown in
Step 300: Start.
Step 302: Receive the band switching signal BD from the baseband module 100.
Step 304: Generate the control signal CTRL according to the band switching signal BD and output the control signal CTRL to the matching adjustment module 110 to adjust impedance between the antenna 104 and the RF-signal processing module 106.
Step 306: End.
Detailed description of the process 30 as well as related modifications or alternations can be referred in the above.
In addition, as aforementioned, the matching adjustment module 110 can obtain different impedances between the antenna 104 and the RF-signal processing module 106 according to the control signal CTRL generated by the controller 108. Thus, the operating bandwidth of the antenna 104 can be extended, and as a result, the wireless communication device 10 can support multiple frequency bands. For example, please refer to
Step 400: Start.
Step 402: The baseband module 100 determines which frequency band the wireless communication device 10 is using to connect with a mobile system. If the wireless communication device 10 uses the frequency band BND_1, proceed to step 404; if the wireless communication device 10 uses the frequency band BND_2, proceed to step 406.
Step 404: The baseband module 100 generates the band switching signal BD including frequency band information of the frequency band BND_1.
Step 406: The baseband module 100 generates the band switching signal BD including frequency band information of the frequency band BND_2.
Step 408: The control 108 generates the control signal CTRL for the matching adjustment module 110 according to the band switching signal BD including frequency band information of the frequency band BND _1.
Step 410: The control 108 generates the control signal CTRL for the matching adjustment module 110 according to the band switching signal BD including frequency band information of the frequency band BND_2.
Step 412: The matching adjustment module 110 adjusts the impedance between the antenna 104 and the RF-signal processing module 106 according to the control signal CTRL in response to the frequency band BND_1.
Step 414: The matching adjustment module 110 adjusts the impedance between the antenna 104 and the RF-signal processing module 106 according to the control signal CTRL in response to the frequency band BND_2.
Step 416: The wireless communication device 10 disconnects from a mobile system, and then performs step 402.
The process 40 is an example illustrating how to switch the frequency band between BND_1 and BND_2. However, the number of the frequency bands is not limited to 2, and each of the frequency bands BND_1 and BND_2 may further include multiple sub-bands. In one preferred embodiment, BND_1 may be a frequency between 764 MHz and 787 MHz for LTE system or a frequency band between 704 MHz and 746 MHz for LTE system, and BND_2 may be a frequency band between 824 MHz and 894 MHz for 3G system or a frequency band between 880 MHz and 960 MHz for 3G system.
In summary, the present disclosure can obtain different matching states, vary VSWR and extend the operating bandwidth to lower bands without extending the dimension of the antenna.
Those skilled in the art will readily observe that numerous modifications and alterations of the device and method may be made while retaining the teachings of the invention. Accordingly, the above disclosure should be construed as limited only by the metes and bounds of the appended claims.
This application claims the benefit of U.S. Provisional Application No. 61/360,929, filed on Jul. 2, 2010 and entitled “Continuously tunable antenna matching circuit for a compact multi-band mobile antenna”, the contents of which are incorporated herein in their entirety.
Number | Date | Country | |
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61360929 | Jul 2010 | US |