The present application relates to an antenna decoupling technology, in particular, to an apparatus and a method for decoupling multiple antennas in a compact antenna array.
To satisfy the fast growing demands from mobile internet market for higher data rate on wireless communication systems, many advanced technologies for increasing the data throughput have been put into use. Among them, Multiple Input Multiple Output (MIMO) data accessing scheme, a proven technology to effectively use the multi path environment, has been becoming a compulsory option in today's wireless communication systems both in base stations and mobile terminals.
Due to an inevitable strong electromagnetic wave mutual coupling between closely spaced antennas in a MIMO wireless terminal, such as a 4G LTE smart phone, the mutual coupling and spatial correlation between antennas are severely high, which lowers the channel capacity gain due to a strong signal correlation. Therefore, how to reduce the unwanted mutual couplings of coupled antennas is a very important issue.
U.S. Ser. No. 13/691,227 by Wu et al. proposed a new technique named Coupled Resonator Decoupling Network (CRDN) for decoupling two coupled antennas. The basic principle underlying is to design a second or higher order coupled resonator network that is connected to the two coupled antennas in parallel and is with its mutual admittance opposite to that of the two coupled antennas such that the unwanted mutual coupling of two antennas can be canceled in a relatively wide frequency band.
However, to apply the new technology in a mobile terminal, a small form factor integrated decoupling apparatus that is independent to the form factors of the antennas is highly desirable. In addition, the circuitry of using the integrated CRDN is also critical in applying the unique technology.
The present application proposes an apparatus for decoupling two antennas in a compact antenna array and a method for decoupling two antennas in a compact antenna array.
According to an embodiment of the present application, disclosed is an apparatus for decoupling two antennas in an antenna array, in which the two antennas transmit and receive signals via a first input/output port and a second input/output port of the apparatus. The device may comprise a first adjusting device connected between a first antenna of the two antennas and the first input/output port, a second adjusting device connected between a second antenna of the two antennas and the second input/output port, and one or more decoupling networks connected between the first input/output port and the second input/output port. The first adjusting device and the second adjusting device are configured to have admittance adjustable to compensate an admittance of the decoupling networks such that an isolation coefficient between the two input/output ports approaches zero and as well as reflection coefficients of each input/output port are minimized.
According to another embodiment of the present application, disclosed is an apparatus for decoupling a plurality of antennas in an antenna array, in which the plurality of antennas transmit and receive signals via respective one of a plurality of input/output ports. The device may comprise a plurality of adjusting devices, each of which connected between a respective antenna of the plurality of antennas and a respective one input/output port of the plurality of input/output ports, and one or more decoupling networks connected between the respective input/output ports of the plurality of input/output ports. The plurality of adjusting devices are configured to have an admittance adjustable to compensate an admittance of the decoupling networks such that an isolation coefficient between the input/output ports approach zero as well as reflection coefficients of each input/output port are minimized.
According to a further embodiment of the present application, disclosed is a method for decoupling two antennas in a antenna array, in which the two antennas transmit and receive signals via a first input/output port and a second input/output port. The method may comprise: inserting a first adjusting device between a first antenna of the two antennas and the first input/output port; inserting a second adjusting device between a second antenna of the two antennas and the second input/output port; connecting one or more decoupling networks between the first input/output port and the second input/output port; and adjusting an admittance of each of the first and the second adjusting devices to compensate an admittance of the decoupling networks such that an isolation coefficient between the two input/output ports approach zero as well as reflection coefficients of each input/output port are minimized.
Exemplary non-limiting embodiments of the invention are described below with reference to the attached figures. The drawings are illustrative and generally not to an exact scale.
References will now be made in detail to exemplary embodiments, examples of which are illustrated in the accompanying drawings. When appropriate, the same reference numbers are used throughout the drawings to refer to the same or like parts.
As shown in
The apparatus 1000 may comprise a first adjusting device 300 and a second adjusting device 400. As shown, the first adjusting device 300 is connected between the first antenna 100 and the first input/output port 1, and the second adjusting device 400 is connected between the second antenna 200 and the second input/output port 2. According to an embodiment, the first adjusting device 300 and the second adjusting device 400 may be made of distributed element circuits, such as a transmission line or stepped impedance resonators circuits. Alternatively, the first adjusting device 300 and the second adjusting device 400 may be made of any form of lumped element circuits, such as a single inductor, a single capacitor, an LC ‘π’ network, an LC ‘L’ network or combination of them.
As shown in
In an embodiment, the first adjusting device 300 and the second adjusting device 400 may be configured to have admittance adjustable to compensate an admittance of the decoupling network 500 such that an isolation coefficient between the two input/output ports approaches zero. According to the embodiment, the first adjusting device 300 and the second adjusting device 400 are configured to have an electrical length and characteristic impedance, both of which are adjustable to compensate the admittance of the decoupling network 500.
Referring to
The CRDN module 530 may be implemented by using different passive integration technologies, including LTCC (Low Temperature Co-fired Ceramic) and multi-layered PCB. An illustrative example of a CRDN module 530 in the form of a LTCC will be given hereinafter.
A schematic circuit diagram of the illustrative example LTCC CRDN module 530 is shown in
The isolation coefficient between the two ports 1 and 2 is diminished by setting a coupling coefficient between the first resonant loop (L1, C1) and the second resonant loop (L2, C2) based on a constraint that the mutual admittance in the whole network composed of the two antennas, the first adjusting device and the second adjusting device, and the decoupling network approaches zero, whiles the self-admittances approach to the characteristic admittance of ports 1 and 2, respectively.
According to another embodiment, the CRDN module 530 may be implemented by using lumped elements or distributed elements or mixture of both as long as desired isolation coefficient is obtained.
In an embodiment, the first I/O coupling module 510 and the second I/O coupling module 520 are configured to have adjustable electrical parameters such that the decoupling network 500 has an adjustable working frequency and adjustable decoupling level.
In an embodiment, the first I/O coupling module 510 and the second I/O coupling module 520 may be made of distributed element circuits, such as a transmission line or stepped impedance resonators circuits. Alternatively, the first I/O coupling module 510 and the second I/O coupling module 520 may be made of any form of lumped element circuits, such as a single inductor, a single capacitor, an LC ‘π’ network, an LC ‘L’ network or combination of them.
According to an embodiment, the apparatus 1000 may further comprise a controlling module 600 (shown in
As shown in
As shown in
According to this embodiment, the decoupling networks 500″ and 700 are connected in parallel and each of the decoupling networks 500″ and 700 may work in different frequency bands such that decoupling of the antennas 100″ and 200″ at different frequency bands are achievable.
According to the present application, the two antennas 100, 100′, 100″ and 200, 200′, 200″ may work in the same or different frequency bands. In the case of two antennas working in the same band, the two resonant loops may also be identical with each other. Otherwise, the two resonant loops may be in different resonant frequency from one another. Some illustrative prototype examples are shown in
In an embodiment, the decoupling network may be used for diminishing mutual couplings of two MIMO antennas working in the same frequency band in a mobile phone.
In another embodiment, the decoupling network may be used for diminishing mutual couplings of adjustable I/O coupling for two antennas operating in the same frequency band. In this embodiment, the lumped capacitor C1 is used to adjust I/O coupling of the decoupling network in order to realize different I/O couplings of the decoupling network, thus various levels of decoupling performance can be obtained.
At step S801, inserting a first adjusting device between a first antenna and the first input/output port 1 is proceeded. At step S802, inserting a second adjusting device between a second antenna of the two antennas and the second input/output port is proceeded. According to an embodiment, the first adjusting device and the second adjusting device may be configured to transmission lines. Alternatively, the first adjusting device and the second adjusting device may be configured to lumped element π networks.
At step S803, connecting one or more decoupling networks between the first input/output port and the second input/output port is proceeded. In an embodiment, the decoupling networks are connected between the first input/output port 1 and the second input/output port 2. As mentioned above, each of the decoupling networks may comprise a first I/O coupling module, a second I/O coupling module and a CRDN module.
According to an embodiment, the step S803 of connecting may further comprise: inserting the first I/O coupling module between the first input/output port and the CRDN module; inserting the second I/O coupling module between the first input/output port and the CRDN module; and adjusting electrical parameters of the first and second I/O coupling modules such that the decoupling networks have an adjustable working frequency and an adjustable decoupling level.
According to an embodiment, the first adjusting device and the second adjusting device may be made of distributed element circuits, such as a transmission line or stepped impedance resonators circuits. Alternatively, the first adjusting device and the second adjusting device may be made of any form of lumped element circuits, such as a single inductor, a single capacitor, an LC ‘π’ network, an LC ‘L’ network or combination of them.
According to an embodiment, the CRDN module may be composed of two or more resonators or resonant loops having at least one resonator, in which the resonator is configured to cooperate with the adjustable electrical length and characteristic impedance of each of the first and the second adjusting devices so as to isolate the two ports electrically.
The CRDN module may be implemented by using different passive integration technologies, including LTCC (Low Temperature Co-fired Ceramic) and multi-layered PCB. An illustrative example of a CRDN module in the form of a LTCC will be given hereinafter. In an embodiment, the CRDN module may be implemented by using lumped elements or distributed elements or mixture of both as long as desired isolation coefficient is obtained.
At step S804, adjusting an admittance of each of the first and the second adjusting devices to compensate an admittance of the decoupling networks such that an isolation coefficient between the two input/output ports approaches zero is proceeded. According to the embodiment, the first adjusting device and the second adjusting device are configured to have an electrical length and characteristic impedance, both of which are adjustable to compensate the admittance of the decoupling network.
According to another embodiment, the method 8000 may further comprise: connecting a controlling module to the first adjusting device and the second adjusting device, and the first I/O coupling module and the second I/O coupling module, and controlling the adjustment of the first adjusting device and the second adjusting device, and the adjustment of the first I/O coupling module and the second I/O coupling module so as to shift their working frequency bands, respectively.
According to another embodiment, the method 8000 may further comprise: adding a first matching network at one port of the two ports, adding a second matching network at the other port of the two ports, and adjusting the first matching network and the second matching network to broaden a matching bandwidth of the two antennas.
According to a further embodiment, the method 8000 may further comprise: connecting a plurality of the decoupling networks in parallel, each of the decoupling networks having different working frequency band such that decoupling of the antennas in multiple work frequency bands are achievable.
With the device for decoupling two antennas in a compact antenna array according to the present application, the proposed decoupling scheme can be applied to various antenna arrays. Taking the advantage of the LTCC multilayer technology, the device according to the present application can be made in a compact volume.
Furthermore, with the device according to the present application, good decoupling and matching conditions can be achieved over a wide frequency range. Besides, a tradeoff between decoupling bandwidths and levels of isolation can also be realized without reconfiguring the device.
Such effects and advantages will be further verified with reference to the following experimental results shown in
An example configuration of the entire apparatus, the detailed layout of the LTCC CRDN module together with the PCB board to be mounted is illustrated in
Therefore, with this antenna-independent LTCC CRDN module and appropriate adjusting devices and I/O coupling devices, a tradeoff between the decoupling bandwidth and level can be realized without reconfiguring the entire CRDN network. This attractive feature allows a mass production of one LTCC device for various applications as long as the frequency band is right.
The embodiments of the present invention may be implemented using certain hardware, software, or a combination thereof. In addition, the embodiments of the present invention may be adapted to a computer program product embodied on one or more computer readable storage media (comprising but not limited to disk storage, CD-ROM, optical memory and the like) containing computer program codes.
In the foregoing descriptions, various aspects, steps, or components are grouped together in a single embodiment for purposes of illustrations. The disclosure is not to be interpreted as requiring all of the disclosed variations for the claimed subject matter. The following claims are incorporated into this Description of the Exemplary Embodiments, with each claim standing on its own as a separate embodiment of the disclosure.
Moreover, it will be apparent to those skilled in the art from consideration of the specification and practice of the present disclosure that various modifications and variations can be made to the disclosed systems and methods without departing from the scope of the disclosure, as claimed. Thus, it is intended that the specification and examples be considered as exemplary only, with a true scope of the present disclosure being indicated by the following claims and their equivalents.
Number | Name | Date | Kind |
---|---|---|---|
20100156745 | Andrenko | Jun 2010 | A1 |
20100225543 | Kakitsu | Sep 2010 | A1 |
20130314294 | Hsieh | Nov 2013 | A1 |
20140118214 | Tanaka | May 2014 | A1 |
20140152523 | Wu | Jun 2014 | A1 |
20140159986 | De Luis | Jun 2014 | A1 |
20140320372 | Wu | Oct 2014 | A1 |
20150255863 | Yoshida | Sep 2015 | A1 |
20150255865 | Nishimoto | Sep 2015 | A1 |
20150288075 | Milroy | Oct 2015 | A1 |
Number | Date | Country |
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2320816 | Aug 1996 | GB |
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20160006119 A1 | Jan 2016 | US |