Some devices (e.g., radar) transmit or receive electromagnetic (EM) energy via one or more antennas to detect an object. These antennas may emit EM energy as radiation and can be characterized in terms of a radiation pattern. An effective radiation pattern may include one maximum (e.g., one grating lobe) of the radiation used to determine the location of an object. The radiation pattern may be improved using a waveguide to guide the EM energy to the antennas. However, some waveguides may cause antennas to produce multiple grating lobes in the radiation pattern, partially caused by cross-polarization of the EM energy, which may reduce the accuracy of object detection. An automobile may emit a radiation pattern towards a nearby area to detect if there are any pedestrians. If the radiation pattern, however, includes multiple grating lobes, then the car may incorrectly detect that a pedestrian is standing next to the car, when in fact, the pedestrian is standing in front of the car.
This document describes techniques, apparatuses, and systems directed to a waveguide end array antenna to reduce grating lobes and cross-polarization. The waveguide end array antenna is referred to throughout this document as simply a waveguide for short. The waveguide utilizes a core made of a dielectric material (e.g., air) to guide EM energy from a waveguide input to one or more radiating slots (e.g., an antenna array). The dielectric core includes a main channel and one or more forks. Each fork connects the main channel to one or more tine sections, and each tine section is terminated by a closed end and a radiating slot. These radiating slots are separated from each other by a slot distance to enable at least a portion of the EM energy to dissipate in phase through the radiating slots in phase. The dielectric core of the waveguide reduces grating lobes and cross-polarization associated with the EM energy. An automobile can rely on the waveguide to detect objects with increased accuracy.
Aspects described below include a waveguide end array antenna configured to guide EM energy through a waveguide section comprising a dielectric core. The waveguide section includes a main channel used to guide the EM energy through a first part of the dielectric core. The main channel includes an open end within the first part of the dielectric core. The waveguide section also includes at least one fork arranged orthogonal to the main channel, used to guide the EM energy from the first part to a second part of the dielectric core. The at least one fork is terminated by two or more tine sections that each include a closed end and a radiating slot used to dissipate at least a portion of the EM energy to outside of the dielectric core.
A waveguide end array antenna to reduce grating lobes and cross-polarization is described with reference to the following diagrams. The same numbers are used throughout the drawings to reference like features and components:
As mentioned in the Background, an effective radiation pattern may include one maximum (e.g., one grating lobe) to precisely determine a location of an object. The radiation pattern may be improved using a waveguide to guide the EM energy to an antenna. Some waveguides, however, may produce multiple grating lobes of the radiation pattern due to a size or shape of the waveguide. Furthermore, cross-polarization of the EM energy may occur and produce multiple grating lobes. These multiple grating lobes reduce the accuracy of object detection. For example, a sensor of an automobile emits a radiation pattern with multiple grating lobes into a nearby area and, instead of a primary grating lobe detecting a pedestrian, a secondary grating lobe detects the pedestrian. Therefore, the automobile incorrectly infers that the detection is in response to the primary grating lobe, when in fact, it was in response to the secondary grating lobe. In this example, the automobile incorrectly determines the location of the pedestrian based on the secondary grating lobe. The automobile determines that the pedestrian is standing next to the automobile, but instead, the pedestrian is standing in front of the automobile. Preventing secondary grating lobes and reducing cross-polarization of the EM energy may, therefore, improve the accuracy of object detection.
This document describes a waveguide that utilizes a dielectric core (e.g., comprising air) that includes a main channel used to guide the EM energy from a waveguide input to one or more radiating slots (e.g., the antenna array). This main channel can include a straight channel with a closed end positioned opposite the waveguide input. The waveguide input can be used to set a desired impedance and/or enable impedance match of the EM energy. The dielectric core also includes one or more forks. Each fork is used to connect the main channel to two or more tine sections, and each tine section is terminated with a closed end and a radiating slot (e.g., antenna). Each fork and each tine section are orientated orthogonal to the main channel. The radiating slots are also orientated orthogonal to the main channel and aligned in a row that is parallel to the main channel. The spacing between each radiating slot is set to enable at least a portion of the EM energy to be in phase as it dissipates out of the dielectric core. The features of this waveguide, by design, reduce grating lobes and cross-polarization associated with the EM energy, helping to improve the accuracy of object detections and improve automotive safety.
The automobile 104 includes a device used to transmit and receive electromagnetic (EM) energy to detect objects and perform operations of the automobile 104. This device includes the waveguide 102 coupled to the device. The device can be hardware mounted to the automobile 104 and additionally include multiple waveguides, printed circuit boards (PCBs), electrical components, transducers, receivers, one or more processors, sensors (e.g., proximity sensors, location sensors), and so forth. The device can also include a computer-readable medium (CRM), suitable memory or storage device, an operating system, and so forth, which are executable by processors to enable operations of the automobile 104. The device can include a controller or control unit, a processor, a system on chip, a computer, a tablet, a wearable device, or other hardware.
The waveguide 102 can enable operations of a radar system that uses radio waves with a resonant frequency or range of frequencies that at least partially includes 30 hertz (Hz) to 300 gigahertz (GHz) to detect the presence of objects. While the automobile 104 depicted in the example environment 100 is primarily described in terms of a radar system, the automobile 104 may include other systems that may support the techniques described herein. Other systems can include low-frequency systems that use radio frequency waves at least partially including 30 kilohertz (kHz) to 300 kHz, ultrasonic systems that use ultrasonic waves at least partially including 20 kHz to 1 GHz, and systems that use EM waves outside of the 30 Hz to 300 GHz range.
The device includes EM energy that is generated or received by the device and sent to the waveguide 102. The waveguide 102 includes a hollow core filled with a dielectric material (e.g., a dielectric core) that is enclosed by a waveguide shell and used to transport the EM energy of the device to radiating slots (e.g., an antenna array). The waveguide shell can include multiple layers stacked within a vertical dimension 106 that is orthogonal to a planar dimension 108. The dielectric core includes a main channel aligned parallel to a longitudinal axis 110 and one or more forks connected to the main channel and aligned parallel to a traverse axis 112. Each fork is terminated by two or more tine sections aligned parallel to the traverse axis 112. The tine sections include closed ends and radiating slots which are used to dissipate at least a portion of the EM energy to outside of the dielectric core. Further details regarding the waveguide 102 are described with respect to
The waveguide 102 includes the dielectric core 204, which can be made of a dielectric material including air or other gas, a dielectric substrate, and so forth. The dielectric core 204 is enclosed by the waveguide shell, and the waveguide shell can be made of metal, a substrate, a substrate coated in metal, plastic, composite, fiber glass, other automotive materials, and so forth. The waveguide shell can include one or more layers (e.g., layer 206-1, layer 206-2, and layer 206-3), and each layer can be made of a different or similar material as another layer. While the example environment 200-1 illustrates the layers stacked along the vertical dimension 106, the layers can also be stacked parallel to the longitudinal axis 110 and traverse axis 112. Together, the dielectric core 204 and waveguide shell enable EM energy to be transported from a waveguide input 208 to radiating slots 210.
A size and a shape of the waveguide input 208 can set an initial impedance of the EM energy as it enters the dielectric core 204 and/or enable impedance matching. For example, the waveguide input 208 can excite a dominant mode (e.g., TE10) of the EM energy or enable impedance matching to a desired mode. The waveguide input 208 in example environments 200-1 and 200-2 is depicted with a rectangular opening and a notch inside the dielectric core 204. Though not depicted, the waveguide input 208 can include other shapes including a slit, an ellipse, a taper, and so forth.
After EM energy enters the waveguide 102 via the waveguide input 208, the EM energy is transported through the main channel 212. A size (e.g., a length, a width, a height) and shape of the main channel 212 can provide boundary conditions that enable a desired mode of the EM energy. The main channel 212 is shown in the example environment 200-2 as a straight channel aligned parallel to the longitudinal axis 110 with a closed end positioned opposite the waveguide input 208. Note that the layer 206-1 is removed in 200-2 to enable discussion of the dielectric core 204. Though not depicted, the main channel 212 can include any shape, for example, a curved shape, a shape with bends, and so forth.
While an aperture size (e.g., a size of a cross-section taken along the vertical dimension 106) of the main channel 212 is depicted to be the same along the longitudinal axis 110, in general, the aperture size can change at any location. For example, the aperture size can transition from a small aperture to a large aperture along the main channel 212. Though the aperture is depicted with a rectangular shape in 200-2, a shape of the aperture can include a square, a circle, an ellipse, a taper, and so forth.
The dielectric core 204 also includes one or more forks 214 connected to the main channel 212. The forks 214 are used to transport the EM energy from the main channel 212 to two or more tine sections 216 of the dielectric core 204. Example environment 200-1 depicts three forks 214. The size and shape of the forks 214 can vary, and each fork 214 can be similar or different in either shape or size to another fork 214. The forks 214 are depicted in 200-2 with an orientation orthogonal to the main channel 212 and parallel to the traverse axis 112. Each fork 214 is connected to at least two tine sections 216.
Each of the tine sections 216 of the dielectric core 204 includes a closed end 218 and at least one radiating slot 210. The tine sections 216 in 200-2 are depicted as a rectangular shape with a length (e.g., aligned parallel to the traverse axis 112) that is greater than a width (e.g., aligned parallel to the longitudinal axis 110). Though not depicted, a size and shape of the tine sections 216 can include various shapes (e.g., including a curved shape, a shape with bends), various aperture sizes, and various aperture shapes (e.g., a square, a circle, an ellipse, a taper). Each tine section 216 can be similar or distinct in a shape or size from another tine section 216. The spacing between tine sections 216 (e.g., a distance taken parallel to the longitudinal axis 110 between tine sections 216) can be similar or different if the waveguide 102 includes three or more tine sections 216.
Each closed end 218 in 200-2 is depicted at least partially inside layer 206-2 with a radiating slot 210 at least partially within layer 206-1 and connected to and positioned at least partially above a corresponding closed end 218. In general, each tine section 216 can include one or more radiating slot 210. Though the radiating slot 210 of 200-1 is depicted as a rectangular shape with rounded corners, other shapes can support the techniques described herein, including a circle, a rectangle, a square, an ellipse, a taper, and so forth. A depth (e.g., taken along the vertical dimension 106) of the radiating slot 210 can be configured to enable operations of the radar system. For example, the depth may be set at a quarter wavelength of a resonant wavelength (e.g., a dominant wavelength) of the EM energy. Each radiating slot 210 includes a slot width (e.g., aligned parallel to the longitudinal axis 110) and a slot length (e.g., aligned parallel to the traverse axis 112). Example environment 200-1 depicts the slot length greater than the slot width, but, in general, the slot length can be shorter than the slot width.
Each radiating slot 210 is depicted in 200-1 with a similar shape and size. However, each radiating slot 210 can differ in a shape or size from another radiating slot 210. Each radiating slot 210 is also centered about a slot axis 220 that is aligned parallel to the longitudinal axis 110 as depicted in 200-1. The radiating slots 210 are separated by a slot separation 222, which includes a distance between the center of each consecutive radiating slot 210. The slot separation 222 enables the EM energy to be in phase as it radiates out of the radiating slots 210. For example, the slot separation 222 can be set between a full wavelength and a half wavelength of the resonant wavelength of the EM energy. Further variations of the waveguide 102 are depicted in
In contrast, radiation patterns from devices that do not include the waveguide 102 (e.g., devices that include an alternative waveguide) are depicted in 400-1 and 400-2.
In general, a radiation pattern can include one or more maximum as governed by sinusoidal equations of the EM radiation. A maximum, herein referred to as a grating lobe, can be used to determine the location of an object. The radiation pattern associated with the waveguide 102 is influenced, in part, by the slot separation 222 and a size and shape of the dielectric core 204. The radiation pattern is influenced by a steering angle, which is formed between the radiating slot 210 and the direction of the EM radiation as transmitted by the device. This steering angle can also influence the slot separation 222. For example, for steering angles less than 90° , the slot separation 222 can be set between a full wavelength and a half wavelength of the resonant wavelength of the EM energy to generate a desired grating lobe 402, centered about the origin or the coordinate system of 400-3. In 400-1, 400-2, and 400-3, the desired grating lobes 402 are centered about the longitudinal axis 110 and the traverse axis 112. The device of the automobile 104 can be configured to detect an object using the desired grating lobe 402 of 400-3.
The example radiation patterns of 400-1 and 400-2 do not use the waveguide 102 and instead may utilize alternative waveguides (e.g., including a different shape or size). The radiation patterns associated with the alternative waveguides feature undesired grating lobes 404 centered about the traverse axis 112 but offset from the center of the longitudinal axis 110. These radiation patterns each feature three distinct grating lobes, including a desired grating lobe 402 and two undesired grating lobes 404. These undesired grating lobes 404 can include a radiation intensity comparable (e.g., of similar intensity) to the desired grating lobe 402 intensity. The size or shape of the alternative waveguide and/or cross-polarization (e.g., misalignment of the polarization) of the EM radiation transmitted by the alternative waveguide can cause these undesired grating lobes 404.
For example, a car transmits a radiation pattern with multiple grating lobes into a nearby area to detect a pedestrian using an alternative waveguide. The radiation pattern is similar to 400-1 or 400-2, and one of the undesired grating lobes 404 detects the pedestrian. The car, however, was designed to detect the pedestrian using the desired grating lobe 402. Therefore, the car incorrectly assumes that the detection was made using the desired grating lobe 402. In this example, the car incorrectly determines the location of the pedestrian because the desired grating lobe 402 and the undesired grating lobe 404 are separated by a distance when transmitted into the nearby area. The car determines that the pedestrian is standing next to the car, when in fact, the pedestrian is standing in front of the car.
In contrast, the waveguide 102 does not feature the undesirable grating lobes 404 and instead features one desired grating lobe 402 used to the detect an object with improved accuracy.
At 502, a waveguide configured to reduce grating lobes and cross-polarization is formed. For example, the waveguide 102 can be stamped, etched, cut, machined, cast, molded, or formed in some other way. At 604, the waveguide configured to reduce grating lobes and cross-polarization is integrated into a system. For example, the waveguide 102 is electrically coupled to the device of the automobile 104. At 606, electromagnetic energy is received or transmitted via the waveguide configured to reduce grating lobes and cross-polarization at or by an antenna of the system, respectively. For example, the device of the automobile 104 receives or transmits EM energy via the waveguide 102 which is electrically coupled to an antenna of the automobile 104.
Some Examples are described below.
Example 1: An apparatus, the apparatus comprising a waveguide end array antenna, the waveguide end array antenna configured to guide an electromagnetic (EM) energy through a waveguide section comprising a dielectric core, the waveguide section comprising a main channel configured to guide the EM energy through a first part of the dielectric core, the main channel comprising an open end within the first part of the dielectric core; and at least one fork arranged orthogonal to the main channel and configured to guide the EM energy from the first part to a second part of the dielectric core, the at least one fork terminated by two or more tine sections, each of the two or more tine sections comprising a closed end and a radiating slot configured to dissipate at least a portion of the EM energy to outside of the dielectric core.
Example 2: The apparatus as recited by example 1, wherein the main channel is further configured as a straight channel, the straight channel configured to guide the EM energy in a direction parallel to a longitudinal axis through the first part of the dielectric core, the straight channel comprising the open end within the first part of the dielectric core and another closed end positioned opposite the open end and within the first part of the dielectric core.
Example 3: The apparatus as recited by example 1, wherein the open end within the first part of the dielectric core is further configured as waveguide input to the main channel, the waveguide input comprising an opening of the waveguide end array antenna, the opening configured to enable the EM energy to enter the waveguide section.
Example 4: The apparatus as recited by example 3, wherein a size and a shape of the waveguide input is configured to set an initial impedance of the EM energy or enable impedance matching of the EM energy.
Example 5: The apparatus as recited by example 1, wherein the two or more tine sections further comprise a length of each tine section is greater than a width of each tine section.
Example 6: The apparatus as recited by example 5, wherein the radiating slots comprise a slot length arranged parallel to the length of each tine section, the slot length greater than a slot width, the slot width arranged orthogonal to the length of each tine section.
Example 7: The apparatus as recited by example 1, wherein the radiating slots are positioned at least partially above the closed ends.
Example 8: The apparatus as recited by example 1, wherein the radiating slots further comprise a first radiating slot and a second radiating slot, the first radiating slot separated from the second radiating slot by a slot separation, the slot separation configured to cause the EM energy to be in phase as the at least a portion of the EM energy dissipates to outside of the dielectric core.
Example 9: The apparatus as recited by example 8, wherein the slot separation is further configured to reduce one or more grating lobes attributed to the EM energy as the at least a portion of the EM energy dissipates to outside of the dielectric core, the one or more grating lobes being maxima of the radiation.
Example 10: The apparatus as recited by example 8, wherein the first radiating slot and the second radiating slot are centered about a slot axis, the slot axis aligned parallel to the main channel.
Example 11: The apparatus as recited by example 8, wherein the at least one fork further comprises a first fork and a second fork, the first fork comprising the two or more tine sections, the second fork comprising another two or more tine sections, the first fork separated from the second fork by a fork separation, the fork separation configured to enable the slot separation.
Example 12: The apparatus as recited by example 8, wherein the slot separation being further configured between a full wavelength of the EM energy and a half wavelength of the EM energy, the EM energy oscillating at the full wavelength.
Example 13: The apparatus as recited by example 1, wherein the waveguide end array antenna is further configured to reduce cross-polarization of a radiation of the EM energy as the at least a portion of the EM energy dissipates to outside of the dielectric core, wherein the EM energy further comprises a polarization of the EM energy; the polarization configured to enable oscillations of the EM energy in a direction; the cross-polarization of the radiation comprising at least two directions of the EM energy from at least two radiating slots; and the at least two directions being different.
Example 14: The apparatus as recited by example 1, wherein a size of the main channel increases as an amount of the at least one fork increases.
Example 15: The apparatus as recited by example 1, wherein the dielectric core comprises air.
Example 16: The apparatus as recited by example 1, wherein the waveguide end array antenna further comprises the dielectric core positioned at least partially within a waveguide shell, the waveguide shell configured to at least partially enclose the dielectric core, the waveguide shell comprising one or more of the following: a metal; a substrate; or a metal-plated material.
Example 17: The apparatus as recited by example 1, wherein the waveguide end array antenna further comprises an injection-molded waveguide end array antenna, the injection-molded waveguide end array antenna formed using an injection-molding process, the injection-molding process comprises pouring a material into a mold to form the injection-molded waveguide end array antenna.
Example 18: A system, the system comprising a device configured to transmit or receive electromagnetic (EM) energy; and a waveguide end array antenna coupled to the device, the waveguide end array antenna configured to guide the EM energy through a waveguide section comprising a dielectric core, the waveguide section comprising a main channel configured to guide the EM energy through a first part of the dielectric core, the main channel comprising an open end within the first part of the dielectric core; and at least one fork arranged orthogonal to the main channel and configured to guide the EM energy from the first part to a second part of the dielectric core, the at least one fork terminated by two or more tine sections, each of the two or more tine sections comprising a closed end and a radiating slot configured to dissipate at least a portion of the EM energy to outside of the dielectric core.
Example 19: The system as recited by example 18, wherein the device comprises a radar device.
Example 20: The system as recited by example 18, wherein the system further comprises a vehicle, the vehicle comprising the device and the waveguide end array antenna.
Although apparatuses including a waveguide end array antenna to reduce grating lobes and cross-polarization have been described in language specific to features, it is to be understood that the subject of the appended claims is not necessarily limited to the specific features described herein. Rather, the specific features are disclosed as example implementations of a waveguide end array antenna to reduce grating lobes and cross-polarization.
This application claims the benefit under 35 U.S.C. 119(e) of U.S. Provisional Application No. 63/169,104, filed Mar. 31, 2021, and U.S. Provisional Application No. 63/127,842, filed Dec. 18, 2020, the disclosures of which are hereby incorporated by reference in their entirety herein.
Number | Date | Country | |
---|---|---|---|
63169104 | Mar 2021 | US | |
63127842 | Dec 2020 | US |