This description relates to a reconfigurable antenna array of individual reconfigurable antennas. mm-wave spectrum offers wide-band RF channels that can support the highest possible data rates available in 5G networks based on the 3GPP New Radio (NR) standard. Due to the high path loss in mm-wave bands, antennas with high gain are necessary for such 5G networks. Large phased arrays of antennas are traditionally used to obtain high gain. Yet higher cost and power consumption of legacy phased arrays make this approach prohibitive. Sparse arrays (i.e., inter-element spacing>one-λair, that is, one wavelength in air at the frequency of interest), where for a given array size a smaller number of antenna elements are provided, have been used to reduce the complexity and cost of legacy phased arrays. However, due to large inter-element spacing, the side lobe levels for sparse arrays become excessively large. While amplitude tapering can be used to reduce the high side-lobe levels of sparse arrays, this comes at the cost of reduced gain.
Traditionally, quarter wavelength thick superstrates placed above driven antennas have been shown to increase gain. Increase in gain is proportional to the dielectric constant of the superstrate and inversely proportional to bandwidth.
In general, in an aspect, a reconfigurable antenna array (RAA) includes individual pattern reconfigurable antennas (PRA). Each of the PRAs has (a) an antenna, (b) components controllable to generate and effect any of two or more modes of the PRA, the modes having respectively different steered radiation patterns, and (c) inputs to receive drive signals for the antenna and control signals for the controllable components. Control circuitry (e.g., a beam former circuit and a beam control unit) has outputs coupled to the inputs of the PRAs to drive the antennas of the PRAs to form an array beam having an array peak in a particular direction and at the same time to deliver control signals for the controllable components to effect a selected mode of each of the PRAs for which the steered radiation pattern has a peak in the particular direction of the array beam and has one or more nulls in the directions of one or more of the side-lobes of the array beam.
Implementations may include one, or a combination of two or more, of the following features. The different steered radiation patterns include different polarizations. The different steered radiation patterns include different frequencies. The RAA includes a reconfigurable sparse antenna array (RSAA). The controllable components include switching devices. The switching devices include PIN diodes. The individual pattern reconfigurable antennas are sparsely spaced. There is a superstrate spaced apart from the individual pattern reconfigurable antennas. The controllable components include a reconfigurable parasitic layer. The control circuitry includes a beam former circuit. The control circuitry includes a processor executing an algorithm.
In general, in an aspect, pattern reconfigurable antennas (PRAs) that are part of a reconfigurable antenna array (RAA) are driven to form an array beam having an array peak in a particular direction. At the same time components of each of the PRAs are controlled to effect a selected mode of each of the PRAs for which the steered radiation pattern has a peak in the particular direction of the array beam and has one or more nulls in the directions of one or more of the side-lobes of the array beam.
Implementations may include one, or a combination of two or more, of the following features. The different steered radiation patterns include different polarizations. The different steered radiation patterns include different frequencies. The RAA includes a reconfigurable sparse antenna array (RSAA). The controlling of the components includes switching the states of switching devices. The controlling of the components includes switching the states of PIN diodes.
These and other aspects, features, implementations, and advantages (a) can be expressed as methods, apparatus, systems, components, program products, means or steps for performing functions, and in other ways, and (b) will become apparent from the following description and from the claims.
In mm-wave 5G systems, base stations will dynamically steer the phased array beams toward intended users to provide best data rate and reduce interference for other users.
Let us consider a 4×1 linear phased array antenna (PAA) 28 as shown in
F(θ,ϕ)=Ea(θ,ϕ)xFa(θ,ϕ) (1)
In (1), Ea(θ,ϕ) is the normalized pattern of each of the individual radiator elements, which is also called the element factor. Fa(θ,ϕ) is the normalized array factor, which for uniform amplitude excitations in the y-z plane is given as follows,
In (2), N=4 is the total number of array elements (the example of
In legacy PAAs, the element factor in (1) remains fixed by initial design, which means that the radiation properties of the individual radiators cannot be changed during operation of the PAA, and thus the element factor cannot play a role in the beam-steering function. The only degree of freedom for beam steering is the array factor, which therefore determines the total radiation pattern. This limitation of legacy phased antenna arrays results in scan loss. This is due to the broadening of the beam width of the array factor when the beam is steered away from the broadside direction. The result is a reduction in the array gain, which becomes significant as the beam is steered farther away from the broadside.
The technology that we describe here includes a reconfigurable sparse antenna array (RSAA) which utilizes individual pattern reconfigurable antenna (PRA) elements along with superstrates to obtain high-gain beam scanning with low side lobe levels.
In some implementations of the technology, an individual PRA element's driven antenna may be a patch antenna, among other possible kinds of antennas. In the near-field region of each patch antenna are placed one or more solid or liquid metallic layers having embedded switching elements (e.g., PIN diodes, varactor, MEMS, CNT (carbon nano tubes), microfluidics, etc., and combinations of them). These metallic layers, which are called reconfigurable parasitic layers, enable the radiation pattern of each individual PRA element to be changed by turning on and off a specific group of the switching elements for that antenna, as explained later.
In some examples of the technology, the inter-element spacing between adjacent PRA elements is made larger than one-λair (wavelength in air), which not only results in a larger antenna aperture and thus larger antenna gain but also enables better control of the mutual coupling between the PRA elements and the reconfigurable parasitic layers, which in turn results in being able to achieve finer reconfiguration of each PRA element's radiation pattern. One or more superstrates with quarter-wave thickness placed above the driven antenna elements are used to further enhance the gain of the antenna array.
A beamformer circuit (e.g., a beamformer integrated circuit, or chip) is used to feed the individual antenna elements of the antenna array by exciting the array coefficients, i.e., phases and amplitudes, of the phased array to dynamically control and adjust the array factor. In conjunction with controlling and adjusting the array coefficients of the beamformer circuit to control the array factor, by judiciously driving a control circuit for the switch elements, a peak of each of the PRA element's radiation pattern is steered toward a peak of the radiation pattern of the array factor to increase the antenna array gain, and the nulls of each of the PRA elements is steered toward the side lobes of the array factor to reduce the antenna array side lobes. Therefore, the reconfigurable sparse antenna array (RSAA) of the technology that we describe here has individual radiators (antenna elements) for each of which maximum radiation beam directions can be changed. In other words, the element factor is not fixed and can be dynamically varied. This additional degree of freedom in conjunction with higher individual element gain translates into higher array gain and lower side lobes.
For the RSAA that we describe here, (1) therefore can be rewritten as follows,
F(θ,ϕ)=EαM(θ,ϕ)xFa(θ,ϕ) (3)
In (3), subscript M represents a reconfigurable antenna mode where M=1, 2, . . . m. Each of the modes corresponds to particular reconfigurations of one or more of the individual antenna elements achieved, for example, by control of the switch elements of the respective individual antenna elements.
Simulated beam steering for both a legacy PAA with a half-wave length inter-element spacing and an example RSAA using the technology that we describe here are shown in
A comparison is shown in
As shown in
In some examples of the technology that we describe here, as shown in
In some implementations, the beamforming coefficients can be stored in the core chip memory and activated or latched by the beam control unit by sending proper activation signals to the core chip. In such implementations, the joint controller will send both core chip and pin diode activation signals at the same instant (synchronously).
In some implementations, the beamforming coefficients are then applied to all of the individual PRA antenna elements simultaneously (synchronously) when the pin diode activation signals are sent to the switch elements of the respective PRA elements.
As shown in
As shown in
In the PRA element shown in
The partially reflective surface (PRS) 120 in
The superstrate (indicated as core-5 in
For comparison, the schematics for a legacy sparse array are shown in
Other implementations are also within the scope of the following claims.
For example, although we have described examples of controlling the individual antenna elements synchronously with the antenna array factor (that is, exactly with respect to the direction and timing of the steering and the polarization and frequency of the beam), useful implementations may entail variations in that approach in which the individual antenna elements are steered in directions that are not exactly matched with the steered direction of the antenna array or are not steered at precisely the same moment as the antenna array or both. In addition, although we have described examples in which all of the individual antenna elements are steered together in the same direction and at the same time, in other instances, it may be useful to steer different ones of the antenna elements in different directions or at different times relative to one another in war relative to the antenna array. Different antenna elements can also be controlled to produce beams of different polarizations (linear, circular, elliptical) and frequencies within the frequency band of interest (e.g., at 28 GHz within the 25-29 GHz band).
This invention was made with Government support under (NSF award #1758543) awarded by the National Science Foundation. The Government has certain rights in this invention.