This application generally relates to an array microphone system and method of assembling the same. In particular, this application relates to an array microphone capable of fitting into a ceiling tile of a drop ceiling and providing 360-degree audio pickup with an overall directivity index that is optimized across the voice frequency range.
Conferencing environments, such as boardrooms, video conferencing settings, and the like, can involve the use of microphones for capturing sound from audio sources. The audio sources may include human speakers, for example. The captured sound may be disseminated to an audience through speakers in the environment, a telecast, and/or a webcast.
In some environments, the microphones may be placed on a table or lectern near the audio source in order to capture the sound. However, such microphones may be obtrusive or undesirable, due to their size and/or the aesthetics of the environment in which the microphones are being used. In addition, microphones placed on a table can detect undesirable noise, such as pen tapping or paper shuffling. Microphones placed on a table may also be covered or obstructed, such as by paper, cloth, or napkins, so that the sound is not properly or optimally captured.
In other environments, the microphones may include shotgun microphones that are primarily sensitive to sounds in one direction. The shotgun microphones can be located farther away from an audio source and be directed to detect the sound from a particular audio source by pointing the microphone at the area occupied by the audio source. However, it can be difficult and tedious to determine the direction to point a shotgun microphone to optimally detect the sound coming from its audio source. Trial and error may be needed to adjust the position of the shotgun microphone for optimal detection of sound from an audio source. As such, the sound from the audio source may not be ideally detected unless and until the position of the microphone is properly adjusted. And even then, audio detection may be less than optimal if the audio source moves in and out of a pickup range of the microphone (e.g., if the human speaker shifts in his/her seat while speaking).
In some environments, microphones may be mounted to a ceiling or wall of the conference room to free up table space and provide human speakers with the freedom to move around the room, thereby resolving at least some of the above concerns with tabletop and shotgun microphones. Most existing ceiling-mount microphones are configured to be secured directly to the ceiling or hanging from drop-down cables that are mounted to the ceiling. As a result, these products require complex installation and tend to become a permanent fixture. Further, while ceiling microphones may not pick up tabletop noises given their distance from the table, such microphones have their own audio pickup challenges due to a closer proximity to loudspeakers and HVAC systems, a further distance from audio sources, and an increased sensitivity to air motion or white noise.
Accordingly, there is an opportunity for systems that address these concerns. More particularly, there is an opportunity for systems including an array microphone that is unobtrusive, easy to install into an existing environment, and can enable the adjustment of the microphone array to optimally detect sounds from an audio source, e.g., a human speaker, and reject unwanted noise and reflections.
The invention is intended to solve the above-noted problems by providing systems and methods that are designed to, among other things: (1) provide an array microphone assembly that is sized and shaped to be mountable in a drop ceiling in place of a ceiling tile; and (2) provide an array microphone system comprising a concentric configuration of microphones that achieves improved directional sensitivity over the voice frequency range and an optimal main to side lobe ratio over a prescribed steering angle range.
In an embodiment, an array microphone system comprises a substrate and a plurality of microphones arranged, on the substrate, in a number of concentric, nested rings of varying sizes. In said embodiment, each ring comprises a subset of the plurality of microphones positioned at predetermined intervals along a circumference of the ring.
In another embodiment, a microphone assembly comprises an array microphone comprising a plurality of microphones and a housing configured to support the array microphone. In said embodiment, the housing is sized and shaped to be mountable in a drop ceiling in place of at least one of a plurality of ceiling tiles included in the drop ceiling. Further, a front face of the housing includes a sound-permeable screen having a size and shape that is substantially similar to the at least one of the plurality of ceiling tiles.
In another embodiment, a method of assembling an array microphone comprises arranging a first plurality of microphones to form a first configuration on a substrate and arranging a second plurality of microphones to form a second configuration on the substrate, where the second configuration concentrically surrounds the first configuration. The method further comprises electrically coupling each of the first and second pluralities of microphones to an audio processor for processing audio signals captured by the microphones.
These and other embodiments, and various permutations and aspects, will become apparent and be more fully understood from the following detailed description and accompanying drawings, which set forth illustrative embodiments that are indicative of the various ways in which the principles of the invention may be employed.
The description that follows describes, illustrates and exemplifies one or more particular embodiments of the invention in accordance with its principles. This description is not provided to limit the invention to the embodiments described herein, but rather to explain and teach the principles of the invention in such a way to enable one of ordinary skill in the art to understand these principles and, with that understanding, be able to apply them to practice not only the embodiments described herein, but also other embodiments that may come to mind in accordance with these principles. The scope of the invention is intended to cover all such embodiments that may fall within the scope of the appended claims, either literally or under the doctrine of equivalents.
It should be noted that in the description and drawings, like or substantially similar elements may be labeled with the same reference numerals. However, sometimes these elements may be labeled with differing numbers, such as, for example, in cases where such labeling facilitates a more clear description. Additionally, the drawings set forth herein are not necessarily drawn to scale, and in some instances proportions may have been exaggerated to more clearly depict certain features. Such labeling and drawing practices do not necessarily implicate an underlying substantive purpose. As stated above, the specification is intended to be taken as a whole and interpreted in accordance with the principles of the invention as taught herein and understood to one of ordinary skill in the art.
With respect to the exemplary systems, components and architecture described and illustrated herein, it should also be understood that the embodiments may be embodied by, or employed in, numerous configurations and components, including one or more systems, hardware, software, or firmware configurations or components, or any combination thereof, as understood by one of ordinary skill in the art. Accordingly, while the drawings illustrate exemplary systems including components for one or more of the embodiments contemplated herein, it should be understood that with respect to each embodiment, one or more components may not be present or necessary in the system.
Systems and methods are provided herein for an array microphone assembly that (1) is configured to be mountable in a drop ceiling of, for example, a conferencing or boardroom environment, in place of an existing ceiling panel, and (2) includes a plurality of microphone transducers selectively positioned in a self-similar or fractal-like configuration, or constellation, to create a high performance array with, for example, an optimal directivity index and a maximal main-to-side-lobe ratio. In embodiments, this physical configuration can be achieved by arranging the microphones in concentric rings, which allows the array microphone to have equivalent beamwidth performance at any given look angle in a three-dimensional (e.g., X-Y-Z) space. As a result, the array microphone described herein can provide a more consistent output than array microphones with linear, rectangular, or square constellations. Further, each concentric ring within the constellation of microphones can have a slight, rotational offset from every other ring in order to minimize side lobe growth, giving the array microphone lower side lobes than existing arrays with co-linearly positioned elements. This offset configuration can also tolerate further beam steering, which allows the array to cover a wider pick up area. Moreover, the microphone constellation can be harmonically nested to optimize beamwidth over a given set of distinct frequency bands.
In embodiments, the array microphone may be able to achieve maximal side lobe rejection across the voice frequency range and over a broad range of array focus (e.g., look) angles due, at least in part, to the use of micro-electrical mechanical system (MEMS) microphones, which allows for a greater microphone density and improved rejection of vibrational noise, as compared to existing arrays. The microphone density of the array constellation can permit varying beamwidth control, whereas existing arrays are limited to a fixed beamwidth. In other embodiments, the microphone system can be implemented using alternate transduction schemes (e.g., condenser, balanced armature, etc.), provided the microphone density is maintained.
The array microphone 104 (also referred to herein as “microphone array”) comprises a plurality of microphone transducers 106 (also referred to herein as “microphones”) configured to detect and capture sounds in an environment, such as, for example, speech spoken by speakers sitting in chairs around a conference table. The sounds travel from the audio sources (e.g., human speakers) to the microphones 106. In some embodiments, the microphones 106 may be unidirectional microphones that are primarily sensitive in one direction. In other embodiments, the microphones 106 may have other directionalities or polar patterns, such as cardioid, subcardioid, or omnidirectional, as desired.
The microphones 106 may be any suitable type of transducer that can detect the sound from an audio source and convert the sound to an electrical audio signal. In a preferred embodiment, the microphones 106 are micro-electrical mechanical system (MEMS) microphones. In other embodiments, the microphones 106 may be condenser microphones, balanced armature microphones, electret microphones, dynamic microphones, and/or other types of microphones.
The microphones 106 can be coupled to, or included on, a substrate 107. In the case of MEMS microphones, the substrate 107 may be one or more printed circuit boards (also referred to herein as “microphone PCB”). For example, in
As shown in
Referring additionally to
As shown in
In embodiments, the housing 102 can be sized and shaped for installation in the drop ceiling 600 in place of at least one of the ceiling tiles 604. For example, the housing 102 can have length and width dimensions that are substantially equivalent to the cell size of the grid forming the drop ceiling 600. In one embodiment, the housing 102 is substantially square-shaped with dimensions of approximately two feet by two feet (e.g., each of the side rails 112 is about 2 feet long), so that the housing 102 can replace any one of the ceiling tiles 604 in a standard U.S. drop ceiling. In other embodiments, the housing 102 may be sized and shaped to replace two or more of the ceiling tiles 604. For example, the housing 102 may be shaped as an approximately four feet by four feet square to replace any group of four adjoining ceiling tiles 604 that form a square. In other embodiments, the housing 102 can be sized to fit into a standard European drop ceiling (e.g., 600 mm by 600 mm), or a standard Asian drop ceiling (e.g., 625 mm by 625 mm). By mounting the microphone array assembly 100 in place of a ceiling tile 604 of the drop ceiling 600, the assembly 100 can gain acoustic benefits, similar to that of mounting a speaker in a speaker cabinet (such, for example, infinite baffling).
In some cases, an adapter frame (not shown) may be provided to retro-fit or adapt the housing 102 to be compatible with drop ceilings that have a cell size that is larger than the housing 102. For example, the adapter frame may be an aluminum frame that can be coupled around a perimeter of the housing 102 and has a width that extends the dimensions of the housing 102 to fit a predetermined cell size. In such cases, a housing 102 that is sized for standard U.S. ceilings can be adapted to fit, for example, a standard Asian ceiling. In other cases, the housing 102 may be designed to fit a minimum cell size (such as, for example, a 600 mm by 600 mm square), and the adapter frame may be provided in multiple sizes or widths that can extend the dimensions of the housing 102 to fit various different cell sizes (such as, for example, a two feet by two feet square, a 625 mm by 625 mm square, etc.), as needed.
In embodiments, all or portions of the housing 102 may be made of a lightweight, sturdy aluminum or any other material that is light enough to allow the microphone array assembly 100 to be supported by the grid of the drop ceiling 600 and strong enough to enable the housing 102 to support the microphone array 104 mounted therein. For example, in certain embodiments, at least the back panel 110 comprises a flat, aerospace-grade, aluminum board comprising a honeycomb core (e.g., as manufactured by Plascore®). Further, according to certain embodiments, the components of the housing 102 (e.g., the side rails 112, the back portion 110, the screen 108, the microphone array 104, etc.) can be configured to easily fit together for assembly and easily taken apart for disassembly. This feature allows the housing 102 to be customizable according to the end user's specific needs, including, for example, replacing the screen 108 with a different material (e.g., fabric) or color (e.g., to match the color of the ceiling tiles 604); adding or removing an adapter frame to change an overall size of the housing 102, as described above; replacing the side rails 112 to match a color or material of the metal channels 602 in the drop ceiling 600; replacing or adjusting the array microphone 104 (e.g., in order to provide an array with more or fewer microphones 106); etc.
Referring additionally to
Referring now to
In embodiments, the microphone array assembly 100 includes an external port 124 mechanically coupled to the control box 114 and configured to electrically couple a cable (not shown) to the audio PCB 116. The cable may be a data, audio, and/or power cable, depending on the type of information being conveyed through the port 124. For example, upon coupling the cable thereto, the external port 124 can be configured to receive control signals from an external control device (e.g., an audio mixer, an audio recorder/amplifier, a conferencing processor, a bridge, etc.) and provide the control signals to the audio PCB 116. Further, the port 124 can be configured to transmit or output, to the external control device, audio signals received at the audio PCB 116 from the microphone array 104. In some cases, the external port 124 can be configured to provide power from an external power supply (e.g., a battery, wall outlet, etc.) to the audio PCB 116 and/or the microphone array 104. In a preferred embodiment, the external port 124 is an Ethernet port configured to receive an Ethernet cable (e.g., CAT5, CAT6, etc.) and to provide power, audio, and control connectivity to the microphone array assembly 100. In other embodiments, the external port 124 can include a number of ports and/or can include any other type of data, audio, and/or power port including, for example, a Universal Serial Bus (USB) port, a mini-USB port, a PS/2 port, an HDMI port, a serial port, a VGA port, etc.
Referring now to
Referring now to
The number, size, and shape of the one or more peripheral PCBs 107b can vary depending on, for example, a number of sides 132, size and/or shape of the central PCB 107a, as well as an overall shape of the substrate 107. For example, in the illustrated embodiment, the central PCB 107a is a polygon with seven uniform sides 132, and the substrate 107 includes seven peripheral PCBs 107b respectively coupled to each side 132 at an inner end 134 of each peripheral PCB 107b. As illustrated, the inner ends 134 are flat surfaces uniformly sized to match any one of the seven sides 132. Each peripheral PCB 107b can further include an outer end 136 that is opposite the inner end 134. In the illustrated embodiment, the substrate 107 is shaped as a circle, and therefore, the outer end 136 of each peripheral PCB 107b is curved.
In other embodiments, the central PCB 107a can have other overall shapes, including, for example, other types of polygons (e.g., square, rectangle, triangle, pentagon, etc.), a circle, or an oval. In such cases, the inner ends 134 of the peripheral PCBs 107b may be sized and shaped according to the size and shape of the sides 132 of the central PCB 107a. For example, in one embodiment, the central PCB 107 may have a circular shape such that each of the sides 132 is curved, and therefore, the inner ends 134 of the peripheral PCBs 107b may also be curved. Likewise, in other embodiments, the substrate 107 can have other overall shapes, including, for example, an oval or a polygon, and the outer ends 136 of the peripheral PCB 107b can be shaped accordingly. In still other embodiments, the substrate 107 can include a donut-shaped peripheral PCB 107b surrounding a circular central PCB 107a, or a single, continuous board 107 comprising all of the microphone transducers 106.
As shown in
More specifically, in embodiments, the microphones 106 can be arranged in concentric, circular rings of varying sizes, so as to avoid undesired pickup patterns (e.g., due to grating lobes) and accommodate a wide range of audio frequencies. As used herein, the term “ring” may include any type of circular configuration (e.g., perfect circle, near-perfect circle, less than perfect circle, etc.), as well as any type of oval configuration or other oblong loop. As shown in
In embodiments, each ring contains a different subset of the remaining microphones 106b, and each subset of microphones 106b can be positioned at predetermined intervals along a circumference of the corresponding ring. The predetermined interval or spacing between neighboring microphones 106b within a given ring can depend on a size or diameter of the ring, a number of microphones 106b included in the subset assigned to that ring, and/or a desired sensitivity or overall sound pressure for the microphones 106b in the ring. Increasing the number of microphones 106 and a microphone density of the rings (e.g., due to nesting of the rings) can help remove grating lobes and thereby, produce an improved beamwidth with a near constant frequency response across all frequencies within the preset range.
As will be appreciated,
In order to accommodate the microphones 906, the microphone configuration 900 may be mounted on a plurality of printed circuit boards (not shown), similar to the central PCB 107a and the plurality of peripheral PCBs 107b. For example, referring now to
In embodiments, the number of rings 910-922 included in the microphone array, a diameter of each ring, and/or the radial distance between neighboring rings can vary depending on the desired frequency range over which the array microphone is configured to operate and what percentage of that range will be covered by each ring. In embodiments, the diameter of each ring in the microphone array defines the lowest frequency at which the subset of microphones within that ring can operate without picking up unwanted signals (e.g., due to grating lobes). As such, the diameter of the outermost ring 922 can determine a lower end of the operational frequency range of the microphone array, and the remaining ring diameters can be determined by subdividing the remaining frequency range. For example and without limitation, in some embodiments, the microphone array can be configured to cover an operational frequency range of at least 100 hertz (Hz) to at least 10 kilohertz (KHz), with each ring covering, or contributing to coverage of, a different octave or other frequency band within this range. As a further example, in such embodiments, the outermost ring 922 may be configured to cover the lowest frequency band (e.g., 100 Hz), and the remaining rings 910-920, either alone or in combination with one or more other rings, may contribute to coverage of the remaining octaves or bands (e.g., frequency bands starting at 200 Hz, 400 Hz, 800 Hz, 1600 Hz, 3200 Hz, and/or 6400 Hz).
As will be appreciated, side lobes may be present in a polar response of a microphone array, in addition to a main lobe of the array beam, the result of undesired, extraneous pick-up sensitivity at angles other than the desired beam angle. Because side lobes can change in magnitude and frequency sensitivity as the array beam is steered, a beam that typically has very small side lobes relative to a main lobe can have a much larger side lobe response once the beam is steered to a different direction. In some cases, the side lobe sensitivity can even rival the main lobe sensitivity at certain frequencies. However, in embodiments, including more microphones 906 within the microphone array can strengthen the main lobe of a given beam and thereby, reduce the ratio of side lobe sensitivity to main lobe sensitivity.
In embodiments, the rings 910-922 may be at least slightly rotated relative to a central axis 930 that passes through a center of the array (e.g., the central microphone 902) in order to optimize the directivity of the microphone array. In such cases, the microphone array can be configured to constrain microphone sensitivity to the main lobes, thereby maximizing main lobe response and reducing side lobe response. In some embodiments, the rings 910-922 can be rotationally offset from each other, for example, by rotating each ring a different number of degrees, so that no more than any two microphones 906 are axially aligned. For example, in microphone arrays with a smaller number of microphones, this rotational offset may be beneficial to reduce an undesired acoustic signal pickup that can occur when more than two microphones are aligned. In other embodiments, for example, in arrays with a large number of microphones, the rotational offset may be more arbitrarily implemented, if at all, and/or other methods may be utilized to optimize the overall directivity of the microphone array.
Referring back to
In embodiments, the total number of microphones 106 and/or the number of microphones 106b on the central PCB 107a and/or each of the peripheral PCBs 107b may vary depending on, for example, the configuration of the harmonic nests, a preset operating frequency range of the array 104, an overall size of the microphone array 104, as well as other considerations. For example, in
In embodiments, the number of microphones 906 included in each of the rings 910-922 can be selected to create a self-similar or repeating pattern in the microphone configuration 900. This can allow the microphone configuration 900 to be easily extended by adding one or more rings, in order to cover more audio frequencies, or easily reduced by removing one or more rings, in order to cover fewer frequencies. For example, in the illustrated embodiments of
As will be appreciated, in other embodiments, the microphones 106/906 may be arranged in other configuration shapes, such as, for example, ovals, squares, rectangles, triangles, pentagons, or other polygons, have more or fewer subsets or rings of microphones 106/906, and/or have a different number of microphones 106/906 in each of the rings 910-922 depending on, for example, a desired distance between each ring, an overall size of the substrate 107, a total number of microphones 106 in the array 104, a preset audio frequency range covered by the array 104, as well as other performance- and/or manufacturing-related considerations.
The control device 1032 may be in wired or wireless communication with the array microphone system 1030 to control the audio component 1036, the microphone array 1034, and/or the indicator 1038. For example, the control device 1036 may include controls to activate or deactivate the microphone array 1034 and/or the indicator 1038. Controls on the control device 1036 may further enable the adjustment of parameters of the microphone array 1034, such as directionality, gain, noise suppression, pickup pattern, muting, frequency response, etc. In embodiments, the control device 1036 may be a laptop computer, desktop computer, tablet computer, smartphone, proprietary device, and/or other type of electronic device. In other embodiments, the control device 1036 may include one or more switches, dimmer knobs, buttons, and the like.
In some embodiments, the microphone array system 1030 includes a wireless communication device 1040 (e.g., a radio frequency (RF) transmitter and/or receiver) for facilitating wireless communication between the system 1030 and the control device 1036 and/or other computer devices (e.g., by transmitting and/or receiving RF signals). For example, the wireless communication may be in the form of an analog or digital modulated signal and may contain audio signals captured by the microphone array 1034 and/or control signals received from the control device 1036. In some embodiments, the wireless communication device 1040 may include a built-in web server for facilitating web conferencing and other similar features through communication with a remote computer device and/or server.
In some embodiments, the array microphone system 1030 includes an external port (not shown) similar to the external port 124, and the system 1030 is in wired communication with the control device 1036 via a cable 1042 coupled to the port 124. In one such embodiment, the audio system 1000 further includes a power supply 1044 that is also coupled to the array microphone system 1030 via the cable 1042, such that the cable 1042 carries power, control, and/or audio signals between various components of the audio system 1000. In a preferred embodiment, the cable 1042 is an Ethernet cable (e.g., CAT5, CAT6, etc.). In other embodiments, the power supply 1044 is coupled to the array microphone system 1030 via a separate power cable.
As illustrated, the indicator 1038 can include a first light source 1046 and a second light source 1048. The first light source 1046 may be configured to indicate a first operating mode or status of the microphone array 1034 by turning the light on or off, and likewise, the second light source 1048 may be configured to indicate a second operating mode of the microphone array 1034. For example, the first light source 1046 may indicate whether or not the microphone array system 1030 has power (e.g., the light 1046 turns on if the system 1030 is turned on), and the second light source 1048 may indicate whether or not the microphone array 1034 has been muted (e.g., the light 1048 turns on if the system 1030 has been set to a mute setting). In other cases, at least one of the light sources 1046, 1048 may indicate whether or not audio is being received from an outside audio source (e.g., during web conferencing). In a preferred embodiment, the first light source 1046 is a first LED with a first light color, and the second light source 1048 is a second LED with a second light color that is different from the first light color (e.g., blue, green, red, white, etc.). The indicator 1038 can be in electronic communication with and controlled by the control device 1032 and/or the audio component 1036, for example, to determine which operating mode(s) can be indicated by the indicator 1038 and which color(s), LED(s), or other forms of indication are assigned to each operating mode.
In embodiments, the audio component 1036 can be configured (e.g., via computer programming instructions) to enable adjustment of parameters of the microphone array 1034, such as directionality, gain, noise suppression, pickup pattern, muting, frequency response, etc. Further, the audio component 1036 may include an audio mixer (not shown) to enable mixing of the audio signals captured by the microphone array 1034 (e.g., combining, routing, changing, and/or otherwise manipulating the audio signals). The audio mixer may continuously monitor the received audio signals from each microphone in the microphone array 1034, automatically select an appropriate (e.g., best) lobe formed by the microphone array 1034 for a given human speaker, automatically position or steer the selected lobe directly towards the human speaker, and output an audio signal that emphasizes the selected lobe while suppressing signals from the other audio sources.
In embodiments, in order to accommodate the possibility of several human speakers speaking simultaneously (e.g., in a boardroom environment), the microphone array 1034 can be configured to simultaneously form up to eight lobes at any angle around the microphone array 1034, for example, to emulate up to eight seated positions at a table. Due to its microphone configuration (e.g., the microphone configuration 900), the microphone array 1034 can form relatively narrow lobes (e.g., as shown in
Further, the audio mixer may be configured to simultaneously provide up to eight individually-routed outputs or channels (not shown), each output corresponding to a respective one of the eight lobes of the microphone array 1034 and being generated by combining the inputs received from all microphones in the microphone array 1034. The audio mixer may also provide a ninth auto-mixed output to capture all other audio signals. As will be appreciated, the microphone array 1034 can be configured to have any number of lobes.
According to embodiments, the lobes of the microphone array 1034 can be configured to have an adjustable beamwidth that allows the audio component 1036 to effectively track, and capture audio from, human speakers as they move within the environment. In some cases, the microphone array system 1030 and/or the control device 1032 may include a user control (not shown) that allows manual beamwidth adjustment. For example, the user control may be a knob, slider, or other manual control that can be adjusted between three settings: normal beamwidth, wide beamwidth, and narrow beamwidth. In other cases, the beamwidth control can be configured using software running on the audio component 1036 and/or the control device 1032.
In environments where multiple microphone array systems 1030 are included, for example, to cover a very large conference room, the audio system 1000 may include an audio mixer that receives the outputs from the audio components 1036 included in each microphone array system 1030 and outputs a mixed output based on the received audio signals.
The audio component 1036 may also include an audio amplifier/recorder (not shown) that is in wired or wireless communication with the audio mixer. The audio amplifier/recorder may be a component that receives the mixed audio signals from the audio mixer and amplifies the mixed audio signals for output to a loudspeaker, headphones, live radio or TV feeds, etc., and/or records the received signals onto a medium, such as flash memory, hard drives, solid state drives, tapes, optical media, etc. For example, the audio amplifier/recorder may disseminate the sound to an audience through loudspeakers located in the environment 600, or to a remote environment via a wired or wireless connection.
The connections between the components shown in
In embodiments, the microphone array 1034 includes a plurality of MEMS microphones (e.g., the microphones 906) arranged in a self-similar or repeating configuration comprising concentric, nested rings of microphones (e.g., the rings 910-922) surrounding a central microphone (e.g., the microphone 902). MEMS microphones can be very low cost and very small sized, which allows a large number of microphones to be placed in close proximity in a single microphone array. For example, in embodiments, the microphone array 1034 includes between 113 and 120 microphones and has a diameter of less than two feet (e.g., to fit in place of a two feet by two feet ceiling tile). Further, by using MEMS microphones in the microphone array 1034, the audio component 1036 may require less programming and other software-based configuration. More specifically, because MEMS microphones produce audio signals in a digital format, the audio component 1036 need not include analog-to-digital conversion/modulation technologies, which reduces the amount of processing required to mix the audio signals captured by the microphones. In addition, the microphone array 1034 may be inherently more capable of rejecting vibrational noise due to the fact that MEMS microphones are good pressure transducers but poor mechanical transducers, and have good radio frequency immunity compared to other microphone technologies.
As shown by the polar pattern 1100, at the 1000 Hz frequency, side lobes 1104 are formed at 10 decibels (dB) below the main lobe 1102. Further, as shown in
In some embodiments, the method 1200 includes, at step 1206, selecting a total number of microphones (e.g., the microphones 106b/906) to include in each configuration that will be placed on the substrate. Where the configuration includes a number of concentric rings, the number of microphones in each ring may be selected based on a desired frequency range of the array, a frequency band assigned to the ring, a desired microphone density for the array, as well as other considerations, as discussed herein. In one embodiment, the total number may be selected from a group consisting of numbers that are a multiple of an integer greater than one. For example, for the rings shown in
As illustrated, the method 1200 includes, at step 1208, arranging a first plurality of microphones in a first configuration on the substrate. The method 1200 also includes, at step 1210, arranging a second plurality of microphones in a second configuration on the substrate, the second configuration concentrically surrounding the first configuration. In some embodiments, the method 1200 can additionally include, at step 1212, arranging a third plurality of microphones in a third configuration on the substrate, the third configuration concentrically surrounding the second configuration.
In embodiments, each of the first, second, and/or third configurations comprises a number of concentric rings positioned at different radial distances from a central point of the substrate to form a nested configuration. In some cases, the first configuration includes a different number of concentric rings than at least one of the second configuration and the third configuration. For example, in the illustrated embodiment of
In some embodiments, the method 1200 can include, at step 1214, rotating at least one of the first, second, and third fourth configurations relative to a central axis (e.g., the central axis 930) of the array microphone so that the configurations are at least slightly rotationally offset from each other, to improve the overall directivity of the array microphone. The method 1200 can also include, at step 1216, electrically coupling each of the microphones to an audio processor for processing audio signals captured by the microphones.
In embodiments, the first, second, and/or third pluralities of microphones are configured to cover different preset frequency ranges, or in some cases, octaves within an overall operating range of the array microphone (for example and without limitation, 100 Hz to 10 KHz). According to embodiments, a diameter of each concentric ring can be defined by a lowest operating frequency assigned to the microphones forming the ring. In some cases, the concentric rings included in the first, second, and/or third configurations are harmonically nested. In a preferred embodiment, the microphone array includes a plurality of MEMS microphones.
Any process descriptions or blocks in figures should be understood as representing modules, segments, or portions of code which include one or more executable instructions for implementing specific logical functions or steps in the process, and alternate implementations are included within the scope of the embodiments of the invention in which functions may be executed out of order from that shown or discussed, including substantially concurrently or in reverse order, depending on the functionality involved, as would be understood by those having ordinary skill in the art.
This disclosure is intended to explain how to fashion and use various embodiments in accordance with the technology rather than to limit the true, intended, and fair scope and spirit thereof. The foregoing description is not intended to be exhaustive or to be limited to the precise forms disclosed. Modifications or variations are possible in light of the above teachings. The embodiment(s) were chosen and described to provide the best illustration of the principle of the described technology and its practical application, and to enable one of ordinary skill in the art to utilize the technology in various embodiments and with various modifications as are suited to the particular use contemplated. All such modifications and variations are within the scope of the embodiments as determined by the appended claims, as may be amended during the pendency of this application for patent, and all equivalents thereof, when interpreted in accordance with the breadth to which they are fairly, legally and equitably entitled.
This application is a continuation of U.S. patent application Ser. No. 16/598,918, filed on Oct. 10, 2019, which is a continuation of U.S. patent application Ser. No. 15/833,404, filed on Dec. 6, 2017, which is a continuation of U.S. patent application Ser. No. 15/631,310, filed on Jun. 23, 2017, which is a continuation of U.S. patent application Ser. No. 15/403,765, filed on Jan. 11, 2017, which is a continuation of U.S. patent application Ser. No. 14/701,376, filed on Apr. 30, 2015, now U.S. Pat. No. 9,565,493. The contents of each application are fully incorporated herein by reference.
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