Embodiments discussed herein generally relate to signal transmission devices. More particularly, certain embodiments include, but are not limited to, an antenna array configured to provide a signal phase difference.
Various directional antenna systems, including flat panel antennae with limited apertures, exhibit a response outside a main beam, known as side lobes. During radio frequency (RF) reception, side lobes can cause unintended reception of adjacent satellite signals. During RF transmission, side lobes can cause unintended interference with other RF signals on adjacent satellites. The Federal Communications Commission (FCC) regulates the levels of these side lobes.
A width of the main beam and the size of side lobes are indicative of antenna performance characteristics. More particularly, a relatively narrow main beam and small side lobes correspond to better directional transmission characteristics. In the case of radio communications, good directional transmission enables more selective communication with a target device and/or better distinguishing by the target device of one transmitter from another nearby transmitter.
In a typical example of a conventional flat panel traveling-wave antenna array, multiple identical waveguides (channels), arranged in parallel with each other, variously transmit respective signals. Radiating elements of these waveguides generate identical sets of side lobes. As a result, the side lobes constructively interfere with one another (sum together), producing significant side lobe levels.
As the number and variety of devices in different environments continue to grow, the amount of wireless communication traffic in such environments will only increase over time. Accordingly, there is expected to be greater value placed on incremental improvements in the suppression of side lobe signal components for directional antenna transmissions.
The various embodiments of the present invention are illustrated by way of example, and not by way of limitation, in the figures of the accompanying drawings and in which:
Embodiments described herein variously provide techniques and/or mechanisms to transmit signals with an antenna array. In an embodiment, an antenna array includes a first antenna and a second antenna, where a first signal is provided at a first input of the first antenna while a second signal is provided at a second input of the second antenna. Signal emission from the first antenna and the second antenna may be characterized by a phase differential other than a phase differential corresponding to the first input and the second input. For example, as the first signal and the second signal variously propagate away from the first input and the second input, respectively, the first antenna and the second antenna may passively induce a change in a phase differential between the first signal and the second signal. As a result, side lobe characteristics may be mitigated for electromagnetic (EM) emissions from the array. For example, a phase difference between respective portions of the first signal and the second signal may be emitted from the first antenna and second antenna respectively, wherein a passively-induced phase difference between these portions facilitates destructive interference of the first signal and the second signal with each other and/or with other signals that might be concurrently transmitted with the antenna array.
Embodiments described herein variously provide for multiple antennae (channels) of an antenna array to each emit the same main beam energy, so that respective main beams of the channels sum across the array. However, some or all such channels may each emit a slightly different side lobe pattern. This difference between side lobe patterns may be achieved at least in part by different respective physical characteristics of various antennae—e.g., where such different characteristics induce one or more signal phase changes.
Differences in the physical characteristics of antennae may include, for example, different physical positions of emitters along channel waveguides of the array. In some embodiments, emitters of antennae are at different distances from the respective inputs of said antennae. As a result of such differences in emitter positions, a phase at a given resonator (emitter) of one antenna may be slightly different than a signal phase at a corresponding resonator of another antenna.
Alternatively or in addition, differences in physical characteristics of antennae may include different respective lengths of a propagation media (e.g., a dielectric material), and/or may include lengths of propagation media having different dielectric properties. For example, a delay of a signal—and a corresponding phase shift of that signal—may be provided by a change in dielectric material along the length of an antenna. In an embodiment, an antenna includes multiple sections of different propagation media to induce successive wave propagation rate changes along the length of the antenna.
In one embodiment, phase differentials between antennae of an array may avoid modes or other constructive interference patterns by the array. For example, the array may provide a set of phase differences each between a respective pair of antennae. The set of phase differences may be chosen to avoid any two phase differences being integer multiples of one another. By way of illustration and not limitation, a distribution of phase differentials may be according to a distribution analogous to the “Circle of Fifths” for musical tones.
The Circle of Fifths provides an audio frequency corollary to phase differentiation according to one embodiment, wherein a middle C note is at 256 Hz, and the G note above middle C is 1.5 times that frequency. Each successive tone in the Circle of Fifths (C, G, D, A, E, B, F#, C#, G#, D#, A#, F) is 1.5 times that of the preceding tone. In an analogous application to difference values for phase differentials according to an embodiment, values may be variously divided—e.g., by 2, one or more several times as necessary—to facilitate placement of a set of corresponding difference values each in a 0° to 360° (0 to 2π radian) range.
Certain features of various embodiments are discussed herein with respect to an antenna array that is to operate as a transmitter, where antennas of the array are each provided with a respective signal that propagates along a length of that array. The antenna array may induce a difference between phase differentials each for a given pair of signals to be variously transmitted from the array. However, in some embodiments, an antenna array may additionally or alternatively act as a receiver, where antennas of the array each receive a respective signal that has been transmitted from a remote device. In such an embodiment, the antenna array may induce a difference between phase differentials each of a given pair of the signals that are received from the remote device.
Certain features of various embodiments are discussed herein with respect to an antenna array that induces a difference between phase differentials each for a given pair of signals that are to be transmitted from (or alternatively, have been received by) the antenna array. However, in some embodiments, a difference in phase differentials may be additionally or alternatively induced at circuitry that is coupled to the antenna array. By way of illustration and not limitation, transmitted circuity and/or receiver circuity may be coupled to such an antenna array, the circuitry to exchange different signals each with a respective antenna of the antenna array. The circuitry may selectively delay or otherwise offset a phase of one or more such signals to provide for a difference between phase differentials each for a given pair of signals. Such a phase offset may be distinguishable from phase modulation schemes, for example, at least insofar as the phase offset may be a static, unchanging offset applied throughout a communication exchange. The phase differentials may aid in mitigating side lobes of a signal to be transmitted by the array and/or mitigate the effects of side lobes in a signal that has been received by the array.
In the following description numerous specific details are set forth to provide a thorough understanding of the embodiments. One skilled in the relevant art will recognize, however, that the techniques described herein may be practiced without one or more of the specific details, or with other methods, components, materials, etc. In other instances, well-known structures, materials, or operations are not shown or described in detail to avoid obscuring certain aspects.
Reference throughout this specification to “one embodiment” or “an embodiment” means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one embodiment of the present invention. Thus, the appearances of the phrases “in one embodiment” or “in an embodiment” in various places throughout this specification are not necessarily all referring to the same embodiment. Furthermore, the particular features, structures, or characteristics may be combined in any suitable manner in one or more embodiments.
In the illustrative embodiment shown, system 100 includes an antenna array 110 comprising a plurality of antennae—e.g., such as the illustrative antennae 112a, 112b, . . . , 112n. The particular number of antennae 112a, 112b, . . . , 112n, and their particular configuration with respect to one another, is merely illustrative, and not limiting on some embodiments. Antennae 112a, 112b, . . . , 112n may be configured each to transmit a respective one or more signals provided, for example, by a splitter 130. In an embodiment, system 100 includes a source 120—e.g., a radio signal source or a radar signal source—coupled to provide to splitter 130 a signal 122 that, for example, represents information to be communicated from system 100 via antenna array 110 to a remote device (not shown). Based on signal 122, splitter 130 may generate a set 132 of signals to be variously transmitted each with a different respective antenna of antenna array 110. By way of illustration and not limitation, generation of set 132 may include variously splitting power of signal 122, and outputting portions of such power each as a respective one of signals 134a, 134b, . . . , 134n.
Antenna array 110 is an example of an antenna array configured to mitigate side lobes according to an embodiment. Antennae 112a, 112b, . . . , 112n may each include a respective waveguide structure and a propagation media (not shown) disposed therein. In the example embodiment shown, respective inputs 116a, 116b, . . . , 116n of antennae 112a, 112b, . . . , 112n are each coupled to be provided from splitter 130 a respective one of signals 134a, 134b, . . . , 134n. Subsequently, signals 134a, 134b, . . . , 134n variously propagate away from inputs 116a, 116b, . . . , 116n each along the length of a respective one of antennae 112a, 112b, . . . , 112n.
Antennae 112a, 112b, . . . , 112n may include emitters variously configured to emit portions of signals 134a, 134b, . . . , 134n for transmission. By way of illustration and not limitation, emitters 114a may be variously disposed along a length of antenna 112a, where different portions of signal 134a are to variously propagate to, and through, respective ones of emitters 114a. Emitters 114a may provide openings, apertures or other such structures to allow a signal pass-through at a sidewall in the waveguide of antenna 112a (where the signal propagates between sidewalls of the waveguide toward a far end of the waveguide). Similarly, emitters 114b may be additionally or alternatively disposed along antenna 112b to variously emit portions of signal 134b, and/or emitters 114c disposed along antenna 112c may be variously configured to emit portions of signal 134c.
Although certain embodiments are not limited in this regard, some or all of emitters 114a, 114b, . . . , 114n may be variously controllable to shape the form of a beam generated with antenna array 110. For example, system 100 may further comprise a pattern generator 140 including logic (e.g., circuitry and/or software) configured to determine a transmission pattern to be provide with antenna array 110. The pattern may be described by or otherwise communicated to drive electronics 150 based on pattern information 142 from pattern generator 140.
Based on pattern information 142, drive electronics 150 may generate a set 152 of control signals to regulate signal emission from antenna array 110. By way of illustration and not limitation, set 152 may include control signals 154a, 154b, . . . , 154n to be received, respectively, at antennae 112a, 112b, . . . , 112n. In response to control signals 154a, 154b, . . . , 154n, antennae 112a, 112b, . . . , 112n may selectively open and/or close various respective ones of emitters 114a, 114b, . . . , 114n. Such selectively control of emitters 114a, 114b, . . . , 114n may enable shaping of a waveform—e.g., where such shaping is performed in concert with signal power allocation by splitting 130.
Certain embodiments variously provide for a difference between two phase differentials, where such difference is a result of signal propagating in antenna having different respective configurations. As used herein, “phase differential” refers to a difference, at a particular time, between the respective phases of two signals each propagating in a different respective antenna of an antenna array. A phase of a signal may depend on a location in the antenna—e.g., where, at a particular time under consideration, the signal in question has a first phase value at a particular location along a length of a given antenna.
In an embodiment, propagation of two signals in different respective antennae, in combination with different respective configurations of such antennae, results in a difference between phase differentials for different locations of the antennae. By way of illustration and not limitation, at some time t1, signal 134a may have a phase φ11 at input 116a, while signal 134b may have a concurrent phase φ12 at input 116b. A phase differential, corresponding to time t1, between inputs 116a, 116b may thus be Δφ1=(φ12−φ11). Between time t1 and a later time t2, signal 134a may propagate away from input 116a and toward one of emitters 114a, where signal 134b concurrently propagates away from input 116b and toward one of emitters 114b. At time t2, signal 134a may have a phase φ21 at a location other than input 116a—e.g., where signal 134b has a phase φ22 a location other than input 116b. Thus, a corresponding phase differential, for time t2, between such locations of antennae 112a, 112b, may be Δφ2=(φ22−φ21). Although certain embodiments are not limited in this regard, either of Δφ2 and Δφ1 may be zero, a negative value or a positive value.
In an embodiment, φ21 corresponds to a particular one of emitters 114a and/or to a particular distance from input 116a. Additionally or alternatively, φ22 may correspond to a particular one of emitters 114b and/or to a particular distance from input 116b. For example, φ21 may correspond to an emitter that is the Nth closest one of emitters 114a to input 116a (where N is a positive integer), and φ22 may correspond to an emitter that is the Nth closest one of emitters 114b to input 116b. In such a scenario, a difference between Δφ2 and Δφ1 may be based at least in part on a difference between a configuration of antenna 112a and a configuration of antenna 112b. Such a difference between Δφ2 and Δφ1 may be independent, for example, of any changing phase of signal 134a over time and/or independent of any changing phase of signal 134b over time. For example, the difference between Δφ2 and Δφ1 attributable to the different configurations of antennae 112a, 112b may be in addition to, but distinguishable from, any other change in phase difference that might be the result of phase modulation of signal 134a and/or signal 134b.
By way of illustration and not limitation, a difference (Δφ2−Δφ1) may result at least in part from emitters 114a having a distribution along antenna 112a that is different than a distribution of emitters 114b having along antenna 112b. For example, a total number of emitters 114a may be different than a total number of emitters 114b. Additionally or alternatively, antennae 112a, 112b may have different respective overall lengths and/or a distance of input 116a from an Nth one of emitters 114a may be different than a distance of input 116b from an Nth one of emitters 114b. In some embodiments, an arrangement of one or more propagation materials in antenna 112a is different than an arrangement of one or more propagation materials in antenna 112b.
Antenna array 110 may include any of a variety of combinations of fewer, more and/or different antennae, according to different embodiments. Additionally or alternatively, certain embodiment may vary with respect to the number of emitters on any one antenna of array 110, and/or the positions of emitters on various antennae.
In an embodiment, method 200 includes, at 210, receiving, at a first time, a first signal at a first input of a first antenna. Method 200 may further comprise, at 220, receiving, at the first time, a second signal at a second input of a second antenna. By way of illustration and not limitation, the receiving at 210 may include input 116a receiving signal 134a, where the receiving at 220 includes input 116b receiving signal 134b.
At 230, method 200 may include propagating the first signal at a first emitter of the first antenna. A portion of the signal may propagate through the first emitter, although certain embodiments are not limited in this regard. Of all emitters of the first antenna, the first emitter may be an Nth closest emitter to the first input, wherein N is a positive integer. For example, the first emitter may be the Nth emitter in a sequence of a first plurality of emitters from along a path extending from the first input along a length of the first antenna—e.g., where the first signal is to propagate along said path.
Method 200 may further comprises, at 240, propagating the second signal at a second emitter of the second antenna—e.g., wherein, of all emitters of the second antenna, the second emitter is an Nth closest emitter to the second input. In an embodiment, a difference between a configuration of the first antenna and a configuration of the second antenna contributes to a difference between a first phase differential, at the first time, between the first signal at the first input and the second signal at the second input and a second phase differential, at a second time, between the first signal at the first emitter and the second signal at the second emitter.
For example, the difference between the first phase differential and the second phase differential may be based at least in part on a first difference between a distance of the first emitter from the first input, and a distance of the second emitter from the second input. By way of illustration and not limitation, the first difference may be equal to or greater than a width of the first emitter (or alternatively, greater than a width of the second emitter). In an embodiment, the first distance may be at least three (3) times—e.g., five (5) times or more than—the width of an emitter.
Additionally or alternatively, the difference between the first phase differential and the second phase differential may be based at least in part on different arrangements of respective propagation media of the first antenna and the second antenna having different configurations of respective propagation media. For example, the first antenna may comprise a first medium disposed between the first input and the first emitter, where the second antenna comprises a second medium disposed between the second input and the second emitter. The first signal may propagate from the first input to the first emitter via the first medium, and the second signal may propagate from the second input to the second emitter via the second medium. In such an embodiment, the difference between the first phase differential and the second phase differential may be based at least in part on a difference between a permittivity of the first medium and a permittivity of the second medium.
Additionally or alternatively, a configuration of the first medium in the first antenna—e.g., including an extent of the first medium along the length of the first antenna—may be different than configuration of the first medium in the first antenna. By way of illustration and not limitation, the first medium may adjoin the first input and further adjoin the first emitter, wherein the second medium adjoins only one of (or neither of) the second input and the second emitter. Alternatively, the first medium may adjoin neither the first input nor the first emitter, where the second medium adjoins neither the second input nor the second emitter, but where a length of the first medium along the first antenna is different than a length of the second media along the second antenna.
Such embodiments are merely some examples of how a difference between respective characteristics, intrinsic to antennae, may give rise to a change in phase differential as respective signals propagate through such antennae. Such changes in phase differential may be said to be passively induced, at least insofar as they are not the result of phase changes due to circuitry that is coupled to, and drives transmission by, the antenna array.
In the embodiment shown, antenna array 300 includes a plurality of antennae each including a respective waveguide structure and a propagation medium disposed therein. By way of illustration and not limitation, array 300 may include antennae 310, 320, 330 comprising respective waveguide structures 312, 322, 332 and respective dielectric structures 314, 324, 334 variously disposed therein. Although certain embodiments are not limited in this regard, waveguide structures 312, 322, 332 may each be straight and arranged in parallel with each other.
Signals 350 may be variously provided to antennae 310, 320, 330—e.g., from power splitter circuitry (not shown) coupled thereto. Antennae 310, 320, 330 may further comprise respective emitters 340 variously distributed each on a respective one of waveguide structures 312, 322, 332. Control signals 360 may be further coupled, in some embodiments, to selectively determine how signal power is to be variously output from different ones of emitters 340.
Antenna array 300 is one example of an array, according to an embodiment, including two antennae to concurrently be provided with different respective signals for transmission, where a difference between respective physical characteristics of the antennae results in a difference between phase differentials (each phase differential between the two signals). The top view 305 of antenna array 300 shows one example of various physical differences—between different pairs of antennae 310, 320, 330—that variously facilitate differences in phase differentials for different pairs of signals 350.
As shown in 305, respective inputs 316, 326, 336 of 310, 320, 330 may be coupled each to receive a different respective one of signals 350. Two or more of antennae 310, 320, 330 may vary from one another at least with respect to a total numbers of emitters and/or a distribution of emitters. By way of illustration and not limitation, respective inputs 316, 326, 336 of antennae 310, 320, 330 may each be coupled to receive a respective one of signals 350. Inputs 316, 326, 336 may be aligned with each other, for example, along a line x0. In such an embodiment, an emitter of antenna 310 that is closest to input 316 may be offset from input 316 by a distance c1, where two other emitters of antenna 310 are variously offset by distances c2, c3. Additionally or alternatively, an emitter of antenna 320 that is closest to input 326 may be offset from input 326 by a distance b1 (e.g., different than c1), where three other emitters of antenna 320 are variously offset by distances b2, b3, b4. In some embodiments, an emitter of antenna 330 that is closest to input 336 may be offset from input 336 by a distance a1 (which may be equal to, or different than, c1), where two other emitters of antenna 330 are variously offset by distances a2, a3.
Due to variation between the respective total number of emitters for antennae 310, 320, 330 (and/or due to variation between the respective distributions of such emitters) antenna array 300 may provide for a different phase differentials each between two signals—e.g., wherein a phase differential changes along the length of antennae as said signals variously propagate each in a respective one of antennae 310, 320, 330. For example, an amount of a phase differential for signals at inputs 316, 326 (e.g., the amount being zero) may be different than an amount of a phase differential for such signals at respective corresponding emitters of antennae 310, 320.
Antenna arrays 400, 450 illustrate embodiments that variously provide for change in signal phase differentials between two (or more) antennae, where the change is due in part to the propagation of signals, in respective antennae, through different dielectric structures. In the illustrative embodiment of array 400, respective inputs 418, 428 of antennae 410, 420 are coupled each to receive a respective signal. Inputs 418, 428 may be aligned with one another along a line x1 that, for example, is perpendicular to a direction of alignment of antennae 410, 420. Although certain embodiments are not limited in this regard, antennae 410, 420 may have the same number and arrangement of respective emitters. For example, offsets xa, xb, xc, xd from line x0 may variously define locations of the respective emitters of antennae 410, 420.
In an embodiment, a dielectric 424, disposed in a waveguide structure 422 of antenna 420, has a first permittivity and extends along the entire length of antenna 420. By contrast, a dielectric 414 and a dielectric 416, disposed in a waveguide structure 412 of antenna 410, may variously extend each only partially along the length of antenna 410, where one or each of dielectric 414 and dielectric 416 has a respective permittivity other than the first permittivity. Due to variation between the respective dielectric structures of antennae 410, 420, an amount of a phase difference for signals at respective ones of inputs 418, 428 may be different—e.g., less than—a phase difference for the same signals at respective ones of the emitters at offset xa (for example).
In the embodiment of array 450, an antenna 460 includes a waveguide structure 462 and a dielectric material 464 disposed therein, wherein dielectric material 464 extends the entire length of antenna 460. Additionally or alternatively, an antenna 470 of array 450 may include a waveguide structure 472 and a dielectric material 474 disposed therein, wherein dielectric material 474 extends the entire length of antenna 470. A permittivity of dielectric material 464 may be equal to that of dielectric material 474.
Inputs 468, 478 of antennae 460, 470 may be variously coupled each to receive a respective signal. Respective emitters of antennae 460, 470 may have the same total number and may have the same arrangement relative to one another—e.g., where offsets xa, xb, xc, xd variously define distances between pairs of such emitters. However, inputs 468, 478 may be offset by different respective distances each from a respective closest emitter. For example, inputs 468, 478 may be aligned with respective lines x2a, x2b that are offset from one another by a distance Δx. Whereas offset xa separates input 478 from a closest emitter of antenna 470, a greater distance (Δx+xa) separates input 468 from a closest emitter of antenna 460. Due to variation between the respective dielectric structures of antennae 460, 470, an amount of a phase difference for signals at respective ones of inputs 468, 478 may be different—e.g., less than—a phase difference for the same signals at the respective Nth emitters closest to inputs 468, 478.
Method 500 may comprise, at 505, setting respective values for variables and constants used to determine a set of difference values. In the illustrative embodiment shown, values w and y represent, respectively, a total number of difference values (Δs) to be determined by method 500, and a phase difference variable. Values x1, x2, x3 are constant values to be used in recursive processing with the value y.
At 510 of method 500, a counter value i may be set to an initial value (e.g., 1), where i represents a count of the current loop of method 500 (e.g., the loop to be not more than the value of w). At 515, the value y is multiplied by x1, and an evaluation is made at 515 as to whether the resulting value of y is greater than x2. The value of y may be divided at 525 by scale factor x3—one or more times, as necessary—until y is less than (or equal to) x2. In response to the value of y being less than (or equal to) x2, method 500 may, at 530, set a value for the ith difference Δ(i)—e.g., by setting Δ(i) equal to 360(y−1). If it is determined at 535 that additional difference values are to be calculated, method 500 may increment the counter value i, at 540, and return to another multiplication of y by x1, at 515. Otherwise, method 500 may finish if all difference values have been calculated.
Method 500 may enable mitigation of constructive interference between signals variously emitted by an antenna array. For example, method 500 may generate a set of difference values, where, for a given difference value, none of the difference values is an integer multiple of that difference value. This may aid in the set of phase difference characteristics providing a pseudo-random distribution of differences between phase differentials.
Method 500 is one example of an algorithm to generate a set of difference values wherein, for each difference value of the set, the difference value corresponds to (e.g., is based on) a respective quotient of a respective first value and a second value (x3) raised to a first respective power. The respective first value is equal to a product of a third value (y) and a fourth value (x1) raised to a second respective power. Based on the values—e.g., where x3 is not an even integer multiple of x1—such a set of difference values may provide for a pseudo-random distribution of phase differentials in the 0° to 360° (0 to 2π radian) range.
In an embodiment, system 600 includes antennae 602, 604, 606, where respective inputs 612, 614, 616 of antennae 602, 604, 606 are coupled each to receive a respective signal. Different respective configurations of antennae 602, 604, 606 may provide for changes in phase differentials between such signals. Such changes may be provided by different dielectric structures in antennae 602, 604, 606, different respective arrangements of emitters 608 in array 600 and/or the like. In one embodiment, constructive interference may be further mitigated by one or more curved shapes of antennae 602, 604, 606. Such curved shapes may break up a symmetry and/or alignment between different emitted signals that might otherwise contribute to the size of side lobes.
In another embodiment, system 630 includes antennae 632, 634, 636, 638, where respective inputs 642, 644, 646, 648 of antennae 632, 634, 636, 638 are coupled each to receive a respective signal. Similar to array 600, for example, different respective configurations of antennae 632, 634, 636, 638 may provide for changes in phase differentials between signals. In one embodiment, side lobe elements may be further mitigated by variously offsetting inputs 642, 644, 646, 648 from one another along a direction of alignment for antennae 632, 634, 636, 638. For example, inputs 642, 644, 646, 648 may be variously located at different positions—e.g., on alternate ones of lines x3a, x3b. Such linear offsetting of antennae 632, 634, 636, 638 may aid in avoiding regions of constructive interference along the sides of array 630. Any of a variety of additional or alternative positions of fewer antenna inputs or more antenna inputs may be provided, according to different embodiments.
In an embodiment, array 650 includes antennae 654, the respective bottom sides of which are variously positioned along a curved arc 652. Different respective configurations of antennae 654—e.g., including different dielectric structures, different respective numbers of emitters and/or positions of emitters, etc.—may provide for different phase differentials between signals variously propagated in antennae 654. Positioning of antennae 654 along curved arc 652 may further reduce the possibility of areas where signals emitted by array 650 constructively interfere with one another.
In another embodiment, array 660 includes antennae 664, the respective bottom sides of which are parallel to one another, but which are variously positioned each on a respective one of flat planes 662a, 662b. Different respective configurations of antennae 664 may passively induce changes in phase differentials, as discussed herein. The various positioning of antennae 664 on respective ones of flat planes 662a, 662b may aid in breaking up regions of constructive interference near array 660. Any of a variety of additional or alternative positions of antennas along respective flat planes and/or curved planes may be provided, according to different embodiments.
In another embodiment, array 670 includes antennae 674 which have different respective orientations and elevations with respect to a flat plane 672. In addition to changes in phase differentials that might be induced passively by antennae 674, the different respective elevations and orientations of antennae 674 may further reduce the possibility of constructive interfere for signals emitted by array 670.
In an embodiment, antenna array 780 serves as an antenna or other mechanism to facilitate communication on behalf of a host of platform 700. By way of illustration and not limitation, such a host may include one or more processors, such as the illustrative processor 710. One or more interconnects, as represented by the illustrative bus 720, may couple processor 710 to controller 770, Tx/Rx circuitry 775 and/or one or more components of platform 700.
In an embodiment, such one or more components may include a memory system 730 comprising a memory controller 732 and a memory device 734 (e.g., a dynamic random access memory). Memory device 734 may store instructions, data and/or other information that, for example, support execution of an operating system or other software by processor 710. A storage 740 of platform 700—e.g., including a hard disk drive and/or a solid state drive—may provide non-volatile storage of data to be made available to processor 710. In an embodiment, one or more input/output (I/O) devices 750—e.g., including a touchscreen, touchpad, keyboard, speaker, network interface and/or the like—may support exchanges to and/or from the platform 700 that are based on and/or determine signal exchanges via antenna array 780.
Techniques and architectures for transmitting electromagnetic signals are described herein. In the above description, for purposes of explanation, numerous specific details are set forth in order to provide a thorough understanding of certain embodiments. It will be apparent, however, to one skilled in the art that certain embodiments can be practiced without these specific details. In other instances, structures and devices are shown in block diagram form in order to avoid obscuring the description.
Reference in the specification to “one embodiment” or “an embodiment” means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one embodiment of the invention. The appearances of the phrase “in one embodiment” in various places in the specification are not necessarily all referring to the same embodiment.
Some portions of the detailed description herein are presented in terms of algorithms and symbolic representations of operations on data bits within a computer memory. These algorithmic descriptions and representations are the means used by those skilled in the computing arts to most effectively convey the substance of their work to others skilled in the art. An algorithm is here, and generally, conceived to be a self-consistent sequence of steps leading to a desired result. The steps are those requiring physical manipulations of physical quantities. Usually, though not necessarily, these quantities take the form of electrical or magnetic signals capable of being stored, transferred, combined, compared, and otherwise manipulated. It has proven convenient at times, principally for reasons of common usage, to refer to these signals as bits, values, elements, symbols, characters, terms, numbers, or the like.
It should be borne in mind, however, that all of these and similar terms are to be associated with the appropriate physical quantities and are merely convenient labels applied to these quantities. Unless specifically stated otherwise as apparent from the discussion herein, it is appreciated that throughout the description, discussions utilizing terms such as “processing” or “computing” or “calculating” or “determining” or “displaying” or the like, refer to the action and processes of a computer system, or similar electronic computing device, that manipulates and transforms data represented as physical (electronic) quantities within the computer system's registers and memories into other data similarly represented as physical quantities within the computer system memories or registers or other such information storage, transmission or display devices.
Certain embodiments also relate to apparatus for performing the operations herein. This apparatus may be specially constructed for the required purposes, or it may comprise a general purpose computer selectively activated or reconfigured by a computer program stored in the computer. Such a computer program may be stored in a computer readable storage medium, such as, but is not limited to, any type of disk including floppy disks, optical disks, CD-ROMs, and magnetic-optical disks, read-only memories (ROMs), random access memories (RAMs) such as dynamic RAM (DRAM), EPROMs, EEPROMs, magnetic or optical cards, or any type of media suitable for storing electronic instructions, and coupled to a computer system bus.
The algorithms and displays presented herein are not inherently related to any particular computer or other apparatus. Various general purpose systems may be used with programs in accordance with the teachings herein, or it may prove convenient to construct more specialized apparatus to perform the required method steps. The required structure for a variety of these systems will appear from the description herein. In addition, certain embodiments are not described with reference to any particular programming language. It will be appreciated that a variety of programming languages may be used to implement the teachings of such embodiments as described herein.
Besides what is described herein, various modifications may be made to the disclosed embodiments and implementations thereof without departing from their scope. Therefore, the illustrations and examples herein should be construed in an illustrative, and not a restrictive sense. The scope of the invention should be measured solely by reference to the claims that follow.
The present application is a continuation of and claims the benefit of U.S. patent application Ser. No. 14/875,651, filed on Oct. 5, 2015 which is a nonprovisional application based on U.S. Provisional Patent Application No. 62/060,370 filed Oct. 6, 2014, and claims the benefit of priority of that provisional application and is hereby incorporated by reference.
Number | Date | Country | |
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Parent | 14875651 | Oct 2015 | US |
Child | 16351309 | US |