The subject matter described herein relates to antenna array formed to transmit information via a radio-frequency beam focused on a selected location. In some examples, multiple communication channels may be transmitted simultaneously to different locations. The transmitter may be formed by an array of optically fed antennas.
Conformal, low profile, and wideband phased arrays have received increasing attention due to their potential to provide multiple functionalities over several octaves of frequency, using shared common apertures for various applications, such as radar and communications.
In the disclosed optically-fed transmitting phased-array architecture, transmitting signals are converted between the electrical domain and the optical domain by using electro-optic (EO) modulators and photodiodes. RF signal(s) generated from a relatively low frequency source modulate an optical carrier signal. This modulated optical signal can be remotely imparted to photodiodes via optical fibers. Desired RF signals may be recovered by photo-mixing at the photodiodes whose wired RF outputs are then transmitted to radiating elements of the antennas.
The antenna array may generate a physical RF beam that transmits an RF signal that is focused on one or more selectable locations. Multiple RF beams may be simultaneously generated, each RF beam being capable of being directed to focus on a unique location or set of locations.
The accompanying drawings are included to provide a further understanding of exemplary device, system and method embodiments of the invention. In the drawings:
The present disclosure now will be described more fully hereinafter with reference to the accompanying drawings, in which various exemplary implementations are shown. The invention may, however, be embodied in many different forms and should not be construed as limited to the exemplary implementations set forth herein. These example exemplary implementations are just that—examples—and many implementations and variations are possible that do not require the details provided herein. It should also be emphasized that the disclosure provides details of alternative examples, but such listing of alternatives is not exhaustive. Furthermore, any consistency of detail between various examples should not be interpreted as requiring such detail—it is impracticable to list every possible variation for every feature described herein. The language of the claims should be referenced in determining the requirements of the invention.
In the drawings, the size and relative sizes of layers and regions may be exaggerated for clarity. Like numbers refer to like elements throughout. Though the different figures show variations of exemplary implementations, these figures are not necessarily intended to be mutually exclusive from each other. Rather, as will be seen from the context of the detailed description below, certain features depicted and described in different figures can be combined with other features from other figures to result in various exemplary implementations, when taking the figures and their description as a whole into consideration.
The terminology used herein is for the purpose of describing particular exemplary implementations only and is not intended to be limiting of the invention. As used herein, the singular forms “a”, “an” and “the” are intended to include the plural forms as well, unless the context clearly indicates otherwise. As used herein, the term “and/or” includes any and all combinations of one or more of the associated listed items and may be abbreviated as “/”.
It will be understood that when an element is referred to as being “connected” or “coupled” to or “on” another element, it can be directly connected or coupled to or on the other element or intervening elements may be present. In contrast, when an element is referred to as being “directly connected” or “directly coupled” to another element, or as “contacting” or “in contact with” another element, there are no intervening elements present. Other words used to describe the relationship between elements should be interpreted in a like fashion (e.g., “between” versus “directly between,” “adjacent” versus “directly adjacent,” etc.). As used herein, elements described as being “electrically connected” are configured such that an electrical signal can be passed from one element to the other. Similarly, “optically connected” or “in optical communication” may be used refer to elements configured such that an optical signal can be passed from one element to another.
Terms such as “about” or “approximately” or “on the order of” may reflect amounts, sizes, orientations, or layouts that vary only in a small relative manner, and/or in a way that does not significantly alter the operation, functionality, or structure of certain elements.
Use of ordinal numbers “first” “second” “third” etc., may be used as labels in this application simply to distinguish one element from another. As these ordinal numbers are typically used in a sequence corresponding to the introduction of the otherwise similarly named elements (a sequence that may be different in different claims and/or the specification), it may be the case that different ordinal numbers may be used to refer to the same/similar element. Thus, a term that is referenced with a particular ordinal number (e.g., “first” in a particular claim) may be referenced elsewhere with a different ordinal number (e.g., “second” in the specification or another claim).
The phase locked optical source 10 generates two light beams 12a, 12b, represented at the output of the phased locked optical source as 12a-1, 12b-1. It should be appreciated that use of reference numerals 12a, 12b refer generally to these two light beams, while reference numerals having suffixes added to these reference numerals 12a, 12b (e.g., 12a-1, 12b-1) may be used to identify a particular configuration or stage of the light beams 12a, 12b. It should also be appreciated that combined beams 12c-1, 12c-2 (discussed below) are formed by combining light beams 12a, 12b and thus should be understood to still include light beams 12a, 12b (in their combined form).
The wavelengths (and frequencies) of light beams 12a-1 and 12b-1 are offset by a fixed amount (although this fixed offset may be adjusted). The lasers may be correlated by injection locking, and the wavelength offset between the light beams 12a-1, 12b-1 emitted by the lasers is determined by an RF reference source (e.g., an RF electrical signal output by the RF reference source).
Such modification of the RF frequency and corresponding RF carrier frequency of the antenna transmitter 10 allows the same antenna transmitter 100 to be used with a variety of RF carrier frequencies, which may only limited by bandwidths of frontend components, such as antennas and RF amplifiers (driving such antennas). In the event desired RF carrier frequencies of the antenna transmitter 10 fall outside operating ranges of frontend components (e.g., antennas, RF amplifiers and/or RF transmission lines connecting the same), the user and/or manufacturer may select and/or replace such frontend components with other frontend components that are optimized to operate with the desired RF carrier frequency (or frequencies). It will also be appreciated that the same backend of the antenna transmitter 10 may be used with several frontends that operate at different RF carrier frequencies, where a demultiplexer (or controllable switch) may select which frontend may be operably connected to and controlled by the backend. Thus, the bandwidth of the antenna transmitter 100 may be formed by a combination of two or more frontends, where some or all of these frontends have operational frequencies lying outside operational frequencies of other frontends. Further exemplary details of an antenna transmitter having a backend that may operate with multiple frontends (via swapping, multiplexing, etc.) that may be used with the present invention are disclosed in U.S. application Ser. No. 16/198,652 filed Nov. 21, 2018, the contents of which are hereby incorporated by reference.
In some examples, the phase locked optical source 10 may be a tunable optical paired source (or TOPS) comprising the pair of lasers 11a, 11b that respectively emit light beams 12a-1 and 12b-1. Further details of exemplary TOPS operation and structure are disclosed in provisional Application No. 62/289,673, U.S. non-provisional application Ser. No. 15/410,761 and Schneider et al. “Radiofrequency signal-generation system with over seven octaves of continuous tuning,” Nat. Photonics, vol. 7, no. 2, pp. 118-122, February 2013.
It will be appreciated that the optical beams 12a-1 and 12b-1 are processed differently as compared to Application No. 62/289,673 and U.S. non-provisional application Ser. No. 15/410,761. As shown in
The optical beams 12a-1 and 12b-1 thus form diverged optical beams 12a-2 and 12b-2. Each of the diverged optical beams 12a-2, 12b-2 are captured by a respective collimating lens 20a, 20b to form respective collimated optical beams 12a-3, 12b-3. It should be appreciated that although
Although not shown in
Collimated beams 12a-3 and 12b-3 are then transmitted to beam splitter/combiner 40. Prior to input into beam splitter/combiner 40, collimated beam 12b-3 may be subject to spatial filtering by spatial light modulator 30 to form modulated beam 12b-4. The modulated beam 12b-4 and collimated beam 12a-3 are input to beam splitter/combiner 40 where they are combined and split to form combined beams 12c-1 and 12c-2. The beam splitter/combiner 40 may comprise a partially transparent mirror having surfaces that partially reflect and partially receive the optical beams 12a-3, 12b-4 as shown. As shown in
Photomixer array 50 may comprise an array of high speed photodiodes 52, each photodiode 52 generating an RF electrical signal corresponding to the portion of the combined beam 12c-1 it senses. Each photodiode 52 may be connected to a corresponding antenna element 72 of the wideband antenna array 70. Specifically, a photodiode 52 of photomixer array 50 provides an RF electrical signal that controls operation of the corresponding antenna element 72 to which it is connected. Only one connection between a photodiode 52 of photomixer array 50 and an antenna element 72 of antenna array is shown in
As shown in
In the example of
In operation, the architecture of the transmitter 10 uses light of two different wavelengths, with the respective sources phase-locked to one another, to generate an RF wave-front (a beam or multiple beams) output from the antenna array 70. The RF wave-front originates in optical domain where the wave-front of light of one of the optical wavelengths (lambda 2) is modulated with SLM (spatial light modulator) 30 before combining it with light of the other wavelength (lambda 1) using beam splitter/combiner 40. As shown in
In the optical beam-forming transmitter 10, the spatial light modulator (SLM) 30 may comprise a phase-only SLM. For example, SLM 50 may be a liquid crystal (LC) SLM where the SLM pixels (separately controlled SLM elements each formed of a LC material) may have their optical indices (i.e., refractive indices) individually controlled by an applied voltage respectively provided by controller 60. Large analog phase shift of the light beam 12b (e.g., selected portions thereof), >4π, can be generated with a minimum applied voltage, i.e., a few volts. As a result, an electrically addressed SLM 30 provide parallel control of the time delays of the RF signals provided to the antenna array 70. Although the SLM 30 is illustrated as having the light beam 12b transmitted therethrough, the SLM 30 may also be formed as a reflective SLM (where beam 12b is transmitted through a liquid crystal to a reflector, which then reflects the light back through the liquid crystal).
In addition, the SLM may modulate other characteristics of the light beam 12b (in addition to or alternatively to phase modulation). For example, the amplitude of the light beam 12b may be modulated, such as by attenuating the intensity of the light beam 12b (or portions thereof). For example, the light beam 12b may be generated as a polarized light beam and the SLM may rotate a polarization direction of the light beam 12b, and the rotated polarized light beam being transmitted through a polarizer. Thus, when the light beam is transmitted through a polarizer having a polarizing direction parallel to that of the polarizer, the light transmitted may correspond to a maximum intensity (and amplitude). When the light beam is transmitted through a polarizer having a polarizing direction orthogonal to that of the polarizer, the light may be fully blocked to correspond to minimum intensity (and amplitude). Intermediate polarization directions (between parallel and orthogonal) provide intermediate intensities of the transmitted beam. Amplitude modulation of the light beam may provide a corresponding amplitude modulation of the RF beat signal of the corresponding combined beam and corresponding amplitude modulate of the generated RF electrical signal (e.g., generated photomixer 50). As noted, both phase and amplitude may be modulated. Thus, QAM modulation may be performed.
It should be appreciated that while only one of the beams 12a, 12b is modulated, both of the beams may be modulated. For example, providing a second SLM 30 may be interposed between lens 20a and beam splitter/combiner 40 that may operate in conjunction with the SLM shown in
The modulation described herein may result in a similarly modulation of one or more spatially separate RF beams generated by the antenna array 70 so that each RF beam may provide encoded data on a channel of the RF beam via such modulation.
Each of the switchable elements, or pixels, of the SLM 30 may be individually controlled (e.g., as with a conventional active matrix liquid crystal display) to separately alter the phase of light passing through. Each portion of beam 12b output by an SLM pixel of SLM 30, after combining with a respective portion of beam 12a light by beam splitter/combiner 40, is directed onto a corresponding photodiode of the photomixer array 50. The photomixer array 50 comprises a plurality of photodiodes that each operate to convert the received light to an RF electrical signal which is then used to control and/or drive a corresponding antenna element 72 (e.g., one of the horn antennas) of the wide band antenna array 70. The frequency of the electrical signals generated by the photodiodes corresponds to the difference in frequency of the light beams 12a, 12b (as determined by the phase-locked optical source 10).
Altering the phase of the light passing through an SLM pixel acts to make a corresponding phase change of the RF signal generated by the corresponding photodiode on which such light impinges. For example, changing the phase of light passing through a pixel of the SLM by n degrees (e.g., by 90, 180, 270, etc. degrees) causes the RF signal generated by this corresponding photodiode by n degrees (e.g., by 90, 180, 270, etc. degrees).
The lower portion of
It can thus appreciated that the phase modulation of the SLM 50 of a portion of the optical beam 12b causes a corresponding a corresponding phase modulation of the corresponding portion of the combined beam 12c with respect to its beat frequency, and thus with respect to the RF electrical signal fed to and the RF electromagnetic wave output by the corresponding antenna 72.
The m×n portions 12bi of light beam 12b are then combined with collimated light beam 12a-3 by beam splitter/combiner 40 to form an m×n matrix of modulated combined light beam portions 12ci (together forming combined light beam 12c-1 discussed herein). Each modulated combined light beam portion 12ci is then impinged on a corresponding photodetector (e.g., photodiode) 52 of the photomixer array 50 which generates a corresponding RF electrical signal. As shown in
Thus, m×n RF electrical signals are generated by the photomixer array 50 and provided to a corresponding one of m×n antenna elements 72 forming antenna array 70. The arrangement of the antenna elements 72 may have the same or different spatial arrangement as the arrangements of the SLM pixels 32 and photodetectors 52.
As noted, each of the antennas 72 in the transmitter antenna array 70 transmits an RF electromagnetic wave at a frequency determined by or as a function of the wavelength offset (or difference) between the first and second optical beams 12a, 12b. The RF electromagnetic wave frequency (antenna operating frequency) may be substantially the same as the inverse of the wavelength offset. For example, if the RF reference 16 of
As noted, the positions of each of the photodiodes 52 of the photomixer array 50 may correspond to positions of the pixels 32 of the SLM 30. Alternatively, light guides (not shown) may be interposed between the beam splitter/combiner 40 and the photomixer array 50 to separately transmit and/or redirect the modulated combined beam portions 12ci output by the pixels 32 of the SLM to photodiodes that have some other arrangement than corresponding to pixels of the SLM. For example, a two dimensional array of lenslets may be provided in the location of the photomixer array 50, with each lenslet replacing a corresponding photodiode (in location) of that described herein with respect to
Each modulated beam 12b-6 is output from an EO modulator 140 on a corresponding optical fiber of fiber bundle 120b. The group of modulated beams 12b-6 output from the EO modulators 140 may form modulated beam 12b-4 of
Modulation of both the first beam 12a and second beam 12b may assist in separately controlling different aspects of the electromagnetic RF signals produced by the antenna array 70. For example, EO modulators 140 may modulate first light beam 12b to encode data of an RF channel (e.g., produced by a corresponding RF beam) for transmission of encoded information by the transmitter 100. Modulation by SLM 30 may be used to adjust channel formation, e.g., to adjust and/or control RF beam formation of the spatially separate RF beams formed by the antenna array 70. SLM 30 may use channel state information to adjust control channel formation via modulation of first light beam 12a while EO modulators 140 may use data streams Data 1, Data 2, . . . Data N (e.g. each corresponding to data of a communication link) to modulate second light beam 12b. As noted herein, modulation of both the first light beam 12a and the second light beam 12b may be implemented as part of any of the embodiments described herein, including the particular configuration illustrated in
As shown by
In the example of
It should be appreciated that while
Each of the beams 12b-8 may thus be received by the lenslet array 110 at a different angle (e.g., have a different angle of incidence with respect to the plane of the two-dimensional lenslet array 110). The constant phase shift between portions of the beams 12b-8 captured by the lenslet array 110 differ in dependence on the angle of incidence of each of the beams 12b-8, each of the beams may correspond to a different RF beam formed by the antenna array 70. Thus, data Data 1, Data 2, . . . Data N modulated onto the different beams 12b-8 may be transmitted with respective RF beams by antenna array 70 to separate sectors (different physical locations) without interference between other RF beams formed by the antenna array 70.
The light of the other optical beam 12a (of different wavelength) generated by the TOPS serves as a reference and is routed to the focal plane of a second lens 20a placed at the other input port of the beam combiner 40. Prior to combining the reference beam 12a with the N modulated beams, the wave-front of the reference light 12a may be additionally modified (e.g., phase shifted and/or amplitude modulated) with a spatial light modulator (SLM) 30 that takes into account the channel state in the RF environment. The SLM 30 is optional. In the absence of an SLM, the reference beam 12a produces a flat phase across the lenslet-and-fiber array (110, 120c); in the absence of an SLM 30, the portions of the reference beam 12a input to each of the M feeds of the receiving fiber array (e.g., at each of the lenslets and/or fibers) are in phase. Thus, each of the M optical fibers at the output of the beam combiner 40 (forming the receiving fiber array) receives the optical reference light 12a (provided by lens 20a—which may or may not be modulated by the SLM) and portions of each of the N modulated optical beams (provided by lens 20b).
The relative positions of the inputs of the receiving fiber array 120c may correspond to the relative positions of the antenna elements 72 to which they provide their signals. The optical path lengths of each optical path of the receiving fiber array 120c (corresponding to each fiber may be the same and may be formed by the optical path length of the corresponding fiber only or by the optical path length of the corresponding fiber and an adjustable optical delay element (or adjustable phase delay), such as lithium niobate.
In some examples, the xi,yi locations of the inputs of the receiving fiber array may correspond to the xi′,yi′ locations of the antenna elements of the antenna array, where (xi,yi)=n×(xi′,yi′) for each of i=1 to M (although it should be appreciated that the relative Cartesian coordinate system and its origin for the receiving fiber array inputs and the antenna array would likely, but not necessarily, be different). The inputs of the receiving fiber array 120c may be planar (e.g., zi may be the same for each of the M feed inputs) and the antenna array 70 may be planar (e.g., zi′ may be the same for each of the M antenna elements). In some examples, offsets in zi and/or zi′ (e.g., to provide nonplanar inputs of the receiving fiber array and/or antenna array, respectively) may be accommodated by adding a phase delay in the corresponding optical feed. It should be appreciated that the use of the variable “i” herein refers each of the elements of a set (e.g., a set of N or M) individually.
Through the optical lens 20b, each one of the N modulated beams from the left of the lens 20b is collimated into a corresponding plane wave to realize uniform amplitude. Upon being input to the receiving fiber array 120c, for each one of the N modulated beams, portions thereof are phase offset in dependence on the optical path length of the different portions of each modulated beam. For example, each modulated beam may have a linear phase offset with respect to its portions distributed across the receiving fiber array 120c. Each of the M optical fibers of the receiving fiber array 120c may receive a corresponding combined beam comprising corresponding portions of each of the N modulated beams with corresponding linear phase offset (with respect to neighboring optical fibers receiving and corresponding modulated beams) and reference light 12a with flat phase (e.g., reference light 12a in phase at each of the inputs to the receiving fiber array) from the reference TOPS across the array.
Each of the fibers feed such a corresponding combined optical beam to a corresponding one of the photo-diodes 52. Each of the photo-diodes 52 is coupled to a corresponding antenna element 72 (e.g., a corresponding horn antenna) of an antenna array 70. Each photodiode 52 converts a corresponding combined optical beam to an RF signal as described herein (e.g., with an RF frequency equal to the frequency offset of the two beams of laser light 12a, 12b produced by TOPS). With respect to a single combined optical beam (formed from only one of the fibers of optical fiber bundle 120b), RF modulation of the RF signal produced by each photodiode 52 may thus be controlled by the corresponding electro-optic modulator 140 (and if used, the pixel of the SLM) as described herein.
Each of the photodiodes 52 mix the optical reference with the modulated optical beam 12b to produce an RF signal that contains information of all data streams (Data 1, Data 2, . . . Data N). The combination of the RF electromagnetic signals emitted from the antenna elements 72 form RF beams in free space. Each of the RF beams may be separately controlled to radiate in a corresponding desired direction. This way, each of the collimated beams 12b-8 formed in optical domain by lens 40 becomes an RF beam transmitted by the antenna array 70. The wavefront of the RF beams may be additionally modified with the SLM 30 (e.g., as discussed herein) to take RF channel state information into account when forming the RF beams.
Each modulated beam 12b output on a fiber of fiber bundle 120b may produce a sector beam in free space through interference between channels by virtue of all of “M” channels of receiving fibers 120c, photodiodes 52, and antennas 72 (all of the channels after the lens 20b). Adding an additional modulated optical beam (12b-6) will produce an additional RF sector beam in free space that is independent of other RF sector beams. “N” channels of the modulated beams 12b-6 will produce “N” sectors of RF beams by the antenna array 70. When all of the N modulated data streams (Data 1, Data 2, . . . Data N) are incorporated, all channels downstream of the beam combiner 40 carry all of information from all of the N modulated beams. The interference between the corresponding modulated signal (12b-6) and reference light 12a forms multiple RF sector beams emitted from the antenna array 70 that point towards corresponding sector directions. All RF sector beams may be formed independently from each other.
In general, direction of the RF sector beam output by the antenna array 70 may be a function of the position of the modulated beam output from a fiber of fiber bundle 120b onto the lens 20b (e.g., a function of the position of the optical fiber carrying the modulated beam 12b-6). The location of the output of the modulated beam 12b-6 at the lens 20b determines the difference in optical paths the portions of that modulated beam to their respective inputs to the feeds of the receiving fiber array, which in turn determines the respective phase offset of these portions. For each modulated beam, phase offsets may regularly increase (e.g., in a substantially linear manner) in a first direction with respect to its input to the receiving fiber array 120c.
The phase offsets of such portions of an ith one of the N modulated beams as input into the receiving fiber array 120c correspond to the phase offsets of the RF signals generated by the corresponding antennas 72 of the antenna array 70 corresponding to that ith modulated beam (the full RF signal generated by an antenna array 70 may include superimposed portions of RF signals corresponding to all of the N modulated beams). The generation of RF signals by each photodiode antenna pair (52, 72) corresponds in phase and amplitude to the optical signal fed to the photodiode antenna pair (as described herein). Thus, for an ith one of the N modulated signals, the regularly increasing or decreasing phase offsets (which may be substantially linear) of portions of the modulated beam across the input of the receiving fiber array 120c correspond to and are reproduced in the RF signals output by the antenna elements 72 of the antenna array and thus act to steer the corresponding RF beam to a particular spatial sector.
Thus, for the N data streams, the system may include N electro-optic modulators, that separately modulate N portions of a first optical beam 12b split N ways, with the modulated N portions of the first optical beam 12b transmitted through a beam combiner 40 to M optical waveguides (e.g., M optical fibers) 120c. The number of N data streams may be not be the same as the M receiving optical waveguides 120c (optical fibers). The beam combiner 40 combines the N modulated beams with reference light 12a. The first optical beam 12b (and thus the N modulated beams) and the reference light 12a are generated by the TOPS to have wavelengths that are offset from each other as described herein. M receiving fibers capture the combined beams with each directed to a corresponding one of M photodiodes 52 by a corresponding one of M optical waveguides 120c (e.g., M additional optical fibers). The M photodiodes 52 generate M RF signals, each of which controls and/or drives a corresponding one of the M antenna elements 72 of the antenna array 70. When an SLM 30 is implemented, M pixels of the SLM 30 may separately modulate M portions of the beam of reference light 12a to tune the phase in each of M optical fibers 120c. Each SLM pixel may correspond to and be dedicated to one optical fiber 120c (i.e., not shared with other optical fibers 120c).
Depending on implementation, lenses or other light guides may be interposed between fiber optic inputs to the beam combiner. The lenses may be collimating lenses, e.g. In some examples, each optical fiber (e.g., such as those outputting light to the beam combiner) may be provided with a separate lens to separately collimate the light output by each optical fiber.
A transmitter to be used in wireless multi-user MIMO has been described. The system combines the virtues of digital, analog and optical processing to arrive at a solution for scalable, non-blocking, simultaneous transmission to multiple devices (e.g., mobile devices or other user equipment (UE-s). The system architecture is independent of the RF carrier frequency, and different frequency bands can be accessed easily and rapidly by tuning the optical source (TOPS). The data channels are established in the digital domain and the RF beam-forming accuracy is only limited by the available resolution of DAC, which can be as high as 16 bits for 2.8 GSPS in off-the-shelf components.
The antenna transmitters described herein may operate and communicate with a wide range of radio frequencies, such as millimeter wave (e.g., about 30 to 300 GHz), microwave (e.g., 1 to 170 GHz), SHF (3 GHz to 30 GHz), UHF (300 MHz to 3 GHz), VHF (30 to 300 MHz), to radio frequencies as low as 300 KHz or even 30 KHz. The invention may also be used with other communication frequencies outside of radio frequencies. Higher frequencies above millimeter wavelength frequencies (e.g., terahertz radiation band between infrared light and millimeter wavelength RF), with a dependence on the ability to convert the beat frequency of the interfering light beams to an electromagnetic wave. It will be appreciated that while a transmitter 100 may dynamically change the range of frequencies that may be transmitted, real time alteration of the carrier frequency will be limited by the type of antenna of the antenna array 70 (although, these may be physically replaced with other antennas by a user).
The light beams 12a, 12b described herein may be visible light or invisible light (e.g., infrared, ultraviolet). Use of other waveguides other than a fiber optics may also be implemented, however widespread availability and ease of use of fiber optics make such waveguides preferable.
Although aspects of embodiments of the present invention has been described, it will be appreciated that the invention may take many forms and is not limited thereto. It will be apparent to those skilled in the art that various substitution, modifications and changes may be made with respect to the disclosed embodiments without departing from the scope and spirit of the invention.
This application is a continuation of U.S. application Ser. No. 16/386,196, filed Apr. 16, 2019, which is a non-provisional application of U.S. provisional Application No. 62/658,245 filed Apr. 16, 2018, the entire contents of each of these applications being hereby incorporated by reference. This application is related to U.S. provisional Application 62/280,673 filed Jan. 19, 2016 and U.S. non-provisional application Ser. No. 15/410,761, the entire contents of each of these applications being hereby incorporated by reference.
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20220029287 A1 | Jan 2022 | US |
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Parent | 16386196 | Apr 2019 | US |
Child | 17495634 | US |