Typically, sound systems for live concert touring are owned by a professional sound provider and travel in one of many tractor/trailer trucks with all the band's production equipment. This can include lighting, video, staging and the band's instruments. A variety of speaker types is typically carried on the tour to accommodate the variety of seating arrangements various venues may provide.
Typically, a large line array is used to cover the main audience area and the farthest areas of an arena or stadium. Smaller line arrays are used to cover the outer sides and center of the audience area. Additional speakers are then also used on stage to cover the closest audience members. There are typically 2 to 7 or more separate loudspeaker arrays brought in and flown (installed) on the day of the show. As most systems are symmetric on the left and right, 1 to 4 or more arrays must be designed to fit their respective coverage areas. The arrays may comprise high, mid and low frequency speakers, as well as subwoofer (ultra low frequency) speakers.
With existing line array loudspeakers each box in the array can be set to a number of different angles relative to the adjacent box; smaller angles increase sound pressure level (SPL), larger angles increase vertical coverage. To get a general idea of the number of speakers required and location for array, acoustic modeling software is used to roughly “draw” the venue prior to the show. This initial look provides a starting point for future modeling, but not the actual angles or orientations of the speakers that need to be implemented on show day.
To fine-tune the speaker angles for the actual performance, a system engineer will arrive early in the morning at the venue to measure the dimensions of the room (typically with a laser range finder), and verify the actual suspension locations and trim height limitations. The venue configuration will then be modified in the modeling software and appropriate array angles and trim heights are chosen. This work must be completed before the loudspeakers can be flown (installed) in the venue.
The loudspeakers are then flown in the venue. Flying each array is a labor-intensive process. Large format loudspeakers typically weigh in excess of 200 lbs. Inter-cabinet angles must be set between each cabinet, typically at more than one point per cabinet. If angles are set incorrectly or the trim height is incorrect, the system could have non-ideal coverage, or worse, not cover the entire audience. Once all the arrays are flown, connected and powered, the system technician will take acoustical measurements of the system to see how the performance matches their acoustic model. If performance is very poor and time permits, an array might be brought down and reconfigured. However, if time does not permit, typically only system equalization and array alignment delay can be adjusted to improve performance. In extreme cases at least some loudspeakers are unplugged to modify coverage.
This summary is provided to introduce a selection of concepts in a simplified form that are further described below in the Detailed Description. This summary is not intended to identify key features of the claimed subject matter, nor is it intended to be used as an aid in determining the scope of the claimed subject matter.
The loudspeaker system of the present disclosure includes adaptive loudspeakers, each having a housing generally in the shape of a rectangular cuboid. A pair of ultra low frequency (also “ULF”) transducers are mounted back-to-back within the housing, with each of the transducers being individually powered and controlled. In addition, a digital signal processor (also “DSP”) channel is provided for each transducer to control the output, including the vertical and/or horizontal directionality of each transducer. An electronic network interconnects the digital signal processing channels with each other. A control system is provided to monitor and control the operation and performance of the transducers individually. The control system includes a computer processor connected to the networked digital signal processing channels and is capable of calculating the loudspeaker output acoustic lobe formation parameters. The control system controls the operation of the transducers based on the calculated loudspeaker output lobe formation parameters.
The control system controls the digital signal processor channels to direct the acoustic output from the loudspeaker components in desired vertical and/or horizontal directions. In this regard, the control system controls at least one of the gain, delay, and response of each transducer in the loudspeaker, thereby to selectively direct the acoustic output from the loudspeaker in a desired vertical direction to achieve a desired coverage of a venue in which the loudspeaker is located, as well as to selectively direct the acoustic output of the loudspeaker in a desired horizontal direction.
Each of the loudspeakers includes a self-testing program incorporated into the circuitry of the loudspeaker, whereby to operably verify that the components of the loudspeaker are operating properly. The loudspeaker system further includes in a single housing a pair of ultra low-frequency transducers in the range of about 20-200 Hz.
The individual loudspeaker cabinets may be arranged in a vertical array, with the vertical array in substantially a straight vertical line. Also, vertical arrays of loudspeakers may be positioned side-by-side to each other to achieve a desired horizontal coverage or scope. The loudspeakers are also substantially identical in construction, including the same transducer configuration and the same number and type of transducers.
Proximity sensors are disposed on the loudspeaker to enable the control system to determine the identity and position of each loudspeaker in an array. Such proximity sensors may transmit signals in the infrared frequency range, or alternatively ultrasonic or radar-type proximity sensors may be utilized.
A tilt sensor is positioned within each of the loudspeaker cabinets, thereby to determine the tilt of each loudspeaker cabinet. The output of the tilt sensors are actively directed to the control system.
As a further aspect of the present disclosure, the self-testing program is incorporated into loudspeakers of the above configuration or into loudspeakers of other configurations. The self-test program is operable to verify that the transducers and other components of each loudspeaker are operating properly.
In accordance with a further aspect of the present disclosure, the control system for the loudspeakers of the above configuration, or loudspeakers of other configurations, can function to verify the specific location of each loudspeaker with respect to the location in the venue in question. The control system generates acoustical impulses from transducers positioned at different locations to trilaterally locate the microphone and thereby determine the distance and direction of the microphone relative to the transducers which generated the acoustical impulses. This helps to verify the configuration of the venue in question.
As a further aspect of the present disclosure, proximity sensors may be utilized in conjunction with the loudspeakers described above, or with loudspeakers of other configurations. Such proximity sensors are capable of determining the position of each loudspeaker based on the output signals from the proximity sensors. Such proximity sensors may consist of infrared proximity sensors, ultrasonic proximity sensors, or radar proximity sensors.
The present disclosure also includes a method for providing sound to a venue, including creating a model of the configuration of the venue, and assembling a plurality of loudspeakers in stacked relationship, and positioning the stacked loudspeakers so that the loudspeakers are disposed in a substantially vertical array. Each of said loudspeakers includes transducers, wherein each transducer is operated by a digital signal processor channel. Based on the modeled venue configuration, the stacked loudspeaker arrays are positioned at one or more locations at the venue. Each of the transducers is operated individually by a control system that networks all the digital processor channels together and also networks the loudspeakers together. Each of the transducers is tested and the parameters for each loudspeaker is individually specified. In this regard, the gain, delay, and/or response of each transducer is individually specified, thereby to direct sound emanating from the loudspeaker in desired vertical and/or horizontal directions.
The method includes assembling two or more vertical arrays of loudspeakers in side-by-side configuration, thereby to achieve the desired horizontal coverage.
The method also includes utilizing a rigging system to suspend the loudspeakers in substantially a straight line vertical array. The method of the present disclosure also utilizes loudspeakers which are substantially identical to each other in construction.
In the method of the present disclosure, the control system recognizes if a particular transducer is not operational, and then adjusts the output of other operational transducers to compensate for the non-operational transducer(s).
The foregoing aspects and many of the attendant advantages of this invention will become more readily appreciated as the same become better understood by reference to the following detailed description, when taken in conjunction with the accompanying drawings, wherein:
The attachments to this application, as well as the detailed description set forth below in connection with the appended drawings, where like numerals reference like elements, are intended as a description of various embodiments of the disclosed subject matter and are not intended to represent the only embodiments. Each embodiment described in this disclosure is provided merely as an example or illustration and should not be construed as preferred or advantageous over other embodiments. The illustrative examples provided herein are not intended to be exhaustive or to limit the disclosure to the precise forms disclosed. Similarly, any steps described herein may be interchangeable with other steps, or combinations of steps, in order to achieve the same or substantially similar result.
In the following description, numerous specific details are set forth in order to provide a thorough understanding of exemplary embodiments of the present disclosure. It will be apparent to one skilled in the art, however, that many embodiments of the present disclosure may be practiced without some or all of the specific details. In some instances, well-known process steps have not been described in detail in order not to unnecessarily obscure various aspects of the present disclosure. Further, it will be appreciated that embodiments of the present disclosure may employ any combination of features described herein.
The present application may include references to directions, such as “forward,” “rearward,” “front,” “back,” “upward,” “downward,” “vertical,” “horizontal,” “upright,” “right-hand,” “left-hand,” “in,” “out,” “extended,” “advanced,” and “retracted.” These references and other similar references in the present application are only to assist in helping describe and understand the present disclosure and invention and are not necessarily intended to limit the present disclosure or invention to these directions.
In the following description, various embodiments of the present disclosure are described. In the following description and in the accompanying drawings, the corresponding systems assemblies, apparatus and units may be identified by the same part number, but with an alpha or other suffix. The descriptions of the parts/components of such systems assemblies, apparatus and units are the same or similar, and therefore are not repeated so as to avoid redundancy in the present application.
An audio loudspeaker 100 (also “speaker”) of the present disclosure is shown in
Next, describing the individual speakers 100, reference initially will be made primarily to
As described above, the forward portion of housing 120 is occupied by the high, mid-range, and low-frequency compression drivers/transducers 142, 143, and 130. The power components and control components of the speaker 100 are located in the transverse rear section 124 of the speaker.
Describing aspects of the speaker 100 in greater detail,
As perhaps best shown in
The horn mouths 154L and 154R are in directional alignment with a central plane 156 which is in turn aligned with central axis 152, whereby the horn mouths are disposed in adjacent relationship to each other. In one embodiment of the present disclosure, the horn mouths 154L and 154R are stacked on top of each other, with the front of the mouths in vertical alignment. However, the front of the mouths do not have to be in the same vertical plane, but can be staggered fore and aft relative to each other. The horn mouths 154L and 154R are shown to be in the same rectilinear shape, and more specifically, rectangular in shape, having a width across the mouths that is greater in dimension than the height of the mouths. The dimensions of the width and height of the mouths are not directly related, and can be of other relative dimensions. Also, one or both of the width and height of the mouths can be selected based on a desired size of the throat “pinch” before the mouth flare 158; see
Each horn 146L and 146R includes an elongate throat 160L and 160R extending between corresponding inlets 148L and 148R and mouths 154L and 154R. As shown in the figures, each of the throats 160L and 160R extends (curves) diagonally inwardly in the forward direction toward central plane 156, and also to be in alignment with the central axis 152 at mouths 154L and 154R. In addition, the throat 160R extends (rises upwardly) in a smooth, curved manner a distance equaling the elevation change from the elevation of inlet 148R to the higher elevation of outlet 154R. Correspondingly, throat 160L descends downwardly a distance corresponding to elevation change of inlet 148L to the elevation of mouth 154L. Throat 160L curves in a smooth arc to fold into a position beneath throat 160R. See
Drivers 142 are constructed with permanent magnets and coils in a known manner of high-frequency drivers. In the present situation, to achieve a lower vertical profile, the permanent magnets utilized in drivers 142 can be square in shape.
As shown in
It will be appreciated that by the foregoing construction, the high-frequency horns are positioned within one-half of a wavelength of each other, thereby enabling control of the interaction between the sources. As a non-limiting example, the horn mouths may be 1.0 inch in height and on a 1.0 inch spacing. Moreover, the shape of the housing 120 causes the forwardly directed portion of the housing to function as a large horn for the high-frequency compression drivers and the mid-range transducers. Also the output from the high-frequency transducers 142 passes across the front of the horn wall 170 shown in
Although each of the horns 146L and 146R can be individually constructed and then assembled together, the above-described structure for the horn sets 144a-144g enables the horns to be constructed as consolidated subassemblies, for example, one subassembly at each side of the central plane 156. It is possible to produce the horn structure using permanent molds which are capable of achieving the rather complex shape of the horn structure very economically.
As shown in
As noted above, a plurality of mid-range cone-type transducers 143 are mounted in a vertical array to each side of the horn structure 140. Although three mid-range cone transducers are illustrated in each vertical array, the number of such cone transducers can be increased or decreased from that illustrated. As shown in
Each of the mid-range transducers 143 is independently powered and controlled by a separate DSP channel. Thus, each of the mid-range transducers is independently powered and processed, as are each of the high-frequency compression drivers 143 and low-frequency cone transducers 130.
As shown in
With respect to additional features of the speakers 100, as shown in
Referring additionally to
Each of the loudspeakers 100 further includes a test key 201 that queries the loudspeaker for the last known status of the loudspeaker internal electronics. See
Also, each speaker 100 includes a built-in microphone 203 to perform in-situ diagnostics of the speaker, see
To describe the foregoing more specifically, the front right panel of each housing 120 houses a calibrated microphone 203 that is used to confirm the operation of each driver and transducer within a loudspeaker 100, see
As a further feature, each of the speakers 100 includes a built-in tilt sensor located within the interior of the speaker. This sensor can help establish the hang angle of the speaker array, which should be substantially vertical. The tile sensors provide active feedback to the control system 260 of the speaker, described below.
The speakers 100 can be vertically flown (hung) as shown in
The upper ends of the flybar latches are attachable to a flybar structure 216 composed of a pair of parallel transverse rearward and forward crossbars 220 and 222 having their corresponding ends connected by side bars 224 and 226 that extend along the outer face of the sides 126 and 128 of the speaker housing. It will be appreciated that the crossbars 220 and 222 can be connected to the side bars 224 and 226 by using brackets 227 or other means. Alternatively, the entire flybar can be constructed from a singularly welded, cast, or molded unit.
The construction of the flybar assembly 216 enables vertical speaker arrays to be conveniently jointed together in side-by-side relationship together by placing the corresponding side bars 224 and 226 of adjacent vertical arrays in face-to-face relationship to each other and then securing the corresponding side bars together. In this regard, two adjacent arrays may be initially positioned together through the use of a pin 228 extending outwardly from the forward and rearward portion of side bar 226. The pin 228 has an enlarged and pointed head 229, to initially engage through a rearward enlarged portion of a slot 230 formed in the side bar 224. Once the head 229 of pin 228 has extended through the enlarged width portion of the slot 230, the pin can be slid forwardly in the slot 230 to engage a narrower portion 231 of the slot that corresponds substantially to the width or diameter of the pin 228. When the pin 228 is in such position, the side bars 224 and 226 are in substantially a face-to-face position with each other.
Speakers 100 are conveniently attachable one on top of the other. In this regard, each of the speakers 100 includes rigging latches 232 slidably engageable within slots or rigging channels 212 at the sides of the speaker housings, see
Moreover, since the speakers 100 are flown in vertical relationship to each other, there is no need to position adjacent speakers at an angle relative to the horizontal or relative to each other or to adjust any angularity between speakers. This greatly simplifies the flying of speaker arrays in terms of required rigging as well as rigging time. As such, the foregoing system for attaching vertically adjacent speakers may be utilized.
Referring to
A vertical alignment line 244 extends vertically along the inside surfaces of each lobe section 122 adjacent grille 246, which covers the central portion of the front of the speaker. The alignment line 244 can serve as a visual indication of whether or not the speakers 100 of a vertical array are all in alignment with each other. As shown in
As noted above, each of the high-frequency compression drivers 142 as well as each of the mid-range cone transducers 143 and each of the low-frequency cone transducers 130 is individually powered as well as individually controlled. This is schematically illustrated in
The adaptive performance software, by generating desired or optimal DSP control parameters for the compression drivers and cone transducers, is able to steer or direct the output from the compression drivers and cone transducers in the vertical and horizontal directions. Typically, the signal from the high-frequency compression drivers and mid and low-frequency cone transducers can be directed between any angle or angle range in the vertical direction from essentially straight down to straight up and anywhere therebetween. Moreover, the angular output in the horizontal direction of the compression drivers and cone transducers can be directed in about a 60° range.
Further, as shown in
Input of digital audio signals to the control system 260 can be via AES/EBU (AES3) port 273 routed through an analog-to-digital converter 274. The input to the controller 260, as well as output therefrom, also may be routed through Dante enabled ports 276. The Dante ports also function as the network interface to the control system 260.
One example of a methodology of installing arrays composed of speakers 100, such as speaker arrays 102, 104, 106, 108, or 110 is illustrated in
The definition of the performance venue is “drawn” in software using dimensional information available pertaining to the venue, including its length, width, seating areas, stage elevation and position and size, balcony locations and positions, etc. Once the loudspeaker arrays have been flown in the venue, the venue configuration can be confirmed by using one or more microphones positioned at one or more points in the venue, see step 350. The audio system of the present disclosure generates several impulses from the high-frequency compression drivers and/or mid/low-frequency cone transducers at different plural locations. The system of the present disclosure trilaterates the location of the microphone. This information assists in modifying a preference or making corrections to the venue model. It will be appreciated that by using this trilateration function, it is no longer necessary to make manual measurements of the venue and carry out the associated numeric data entry of such measurements.
In step 310, noted above, one or more loudspeaker arrays are configured to match the venue in question, including matching the size and the shape of the venue, as well as the locations of the audience members and based on the ideal wave front for the venue. In this regard, algorithms have been developed to model the output of the loudspeakers 100 and each compression driver/cone transducer thereof not only to provide sound to all desired areas of a venue, but also to achieve pleasing results. In one approach the venue is divided into a grid of spots and the loudspeakers are “aimed” to direct sound to each such spot. The loudspeaker arrays are constructed from identical speakers 100 and the rigging system, described above, is used to quickly and conveniently construct and position the arrays at the venue.
At steps 320 and 330, the operating parameters for each of the high-frequency compression drivers as well as the mid- and low-frequency cone transducers of each loudspeaker are determined to optimize the speakers to the venue. In this regard, as discussed above, each such compression driver and cone transducer is independently powered and processed. In part of the present process, the control system of the present disclosure is aware of the location of each of the speakers 100. As discussed above, four infrared or other type of proximity transceivers 200 are mounted on each speaker housing 120. The transceivers are located two at the top and two at the bottom of the speaker housing on opposite sides of the speaker housing, which enables the speakers to be modeled as two-dimensional arrays. With this information, the physical layout of the loudspeakers is determined. The data transmission that occurs between each loudspeaker identifies each adjacent loudspeaker. In this manner, the position of each loudspeaker is determined. Also, as noted above, each loudspeaker includes a tilt sensor 204 to confirm that the loudspeaker in question is vertical positioned, or whether the loudspeaker is at an angle off vertical. This information is also useful in adjusting or targeting the output from each speaker.
Using the control system 260, described above, the vertical directional output of each high-frequency compression driver and each mid-range and low-frequency cone transducer can be steered in the vertical direction to achieve the best audience coverage. In this regard, as noted above, the vertical angle directional output with the drivers and transducers is adaptive throughout the entire 180° range of from vertically down to vertically up. It will be appreciated that the spacing between each of the high-frequency compression drivers, as well as each of the speakers, is minimized so as to maximize the vertical lobe alteration within the speakers' operational bandwidth, and thereby minimize vertical artifacts.
Also, as noted above, the output of the transducers and drivers is controlled to provide the device horizontal coverage. The spacing between each horizontally adjacent transducer is also minimal, to maximize horizontal lobe alteration within that transducer's operational bandwidth, and to minimize horizontal artifacts. The nominal horizontal beam width of speakers 100 is approximately 70 degrees. This beam width can be increased up to 360 degrees by using multiple columns of speakers 100.
It will be appreciated that each of the speakers 100 within an array is networked together, and thus the controls for each of the compression drivers and cone transducers of each speaker, via a computer processor which operates a DSP as well as applicable algorithms to control the output and directionality of each of the transducers in each of the speakers. Such computer processor calculates all of the lobe formation parameters for the speakers and communicates them to the loudspeakers.
The networked control system also monitors the operation and performance of all of the loudspeaker compression drivers and cone transducers in the arrays on an ongoing basis, see step 370. Since the performance parameters for the loudspeaker components are sent electronically to the loudspeaker components from the control system, such parameters can be modified very quickly at any time. Some of the monitored parameters include transducer impedance, amplifier temperature, voltage, and currents of each driver/transducer, and this information is recorded on a “live” status log that can be downloaded. In this regard, not only is the functionality of each compression driver and cone transducer confirmed, but also the control system assesses the complete performance of each compression driver/cone transducer by comparing such performance with reference parameters stored in memory. Also, follow up or supplementary venue measurements can be conducted at any time, as discussed above, thereby to more accurately define the venue. For example, if additional seats in the venue are sold, or the performers are not satisfied with the sound quality, the coverage from the speakers can be easily modified.
The above methodology can be used to design the speaker configurations for the venues shown in
In
If a failure of one or more transducers, or even an entire speaker, occurs after the speaker arrays are flown, or even during a performance, the failure is recognized by the networked control system and corrective action can be taken, step 380. Even before the overall system monitoring occurs, each loudspeaker can be tested, since each loudspeaker contains a self-test function built into the circuitry of the loudspeaker system to enable verification that all the components of the loudspeaker are operating correctly. The results of this test can be queried by simply pressing a self-test button on the loudspeaker.
If a portion of the system is damaged, the control system will determine a solution and adjust the system coverage in response. Essentially, the control system is able to rebuild the acoustical model of the loudspeaker components without the “failed” sources. In this regard, compression drivers and cone transducers parameters can be adjusted to affect the vertical direction between adjacent speakers and direct sound at every “spot” in the venue. Therefore, “spots” to be hit are redefined to adjust to the non-functioning drivers/transducers. If a particular loudspeaker or component thereof cannot “hit” every desired spot in the venue, then adjacent loudspeakers, drivers, and/or transducers are used to “fill in” the sound to achieve the desired coverage. Due to the reduction in sound level over distance, typically, more loudspeaker components are focused at further areas, and fewer loudspeaker components are directed at closer areas. It is not necessary to physically alter speaker-to-speaker angles, but instead digital signal processing is used to alter the component-to-component angles in accordance with the new virtual acoustical model created with the failed source(s) removed. The same process is used to achieve the desired horizontal coverage in the instance that a failure occurs in one or more of the drivers/transducers, or even in an entire speaker.
The speaker 100 and the arrays constructed therewith as well as the control system for the arrays described above provide significant advantages over preexisting loudspeaker arrays. For example, in the arrays of the present disclosure, the position of each loudspeaker itself is self-recognizing, and all of the drivers/transducers in each loudspeaker are networked together and individually powered and controlled for output level as well as for horizontal and vertical directionality. Further, the present loudspeaker system is “self-healing” and adapts if one or more component failures occur, even during use. Further, the rigging of the loudspeaker arrays is simplified and thus the arrays can be flown quickly and easily and also disassembled quickly and easily.
An ultra-low frequency or subwoofer loudspeaker 300 (also “speaker”) of the present disclosure is shown in
Describing the individual speakers 302, as shown in
As shown in
As illustrated in
A rear central column structure 348 spans between the top and bottom panels 344 and 346 centrally along the back surface of the grille central panel 347a. The center column structure 348 houses latch mechanisms for flying and stacking speakers 300 as described below.
The corner structures also include a cover structure 350 composed of an arcuate top plate 344 and an arcuate bottom plate 346 that are spanned by side columns 351 and 352. Top and bottom forwardly projecting arcs 353 extend around the outer perimeters of the plates 344 and 346 to define the curved out perimeter at the top and bottom of the corner assemblies 342. Arcuate tie bars 354 span between side columns 351 and 352 and correspond to the curved shape of the outer perimeter of the top and bottom panels 344 and 346. The tie bars provide grasping locations or handles for the speakers 300. Hardware members 355 extend through protective vertical runners 357 extending along the height of the columns 351/352 and the grille flanges 347d and 347e to engage the speaker housing 310. It will be appreciated that all or some of these components of the cover structure can be cast or otherwise manufactured as a singular unit.
An open cell foamed rubber panel 356 overlaps the inward surface of grille structure 347. The purpose of the panel 356 is to prevent moisture, dust, etc., from entering the speaker housing while allowing the sound from the transducers 330 to project from the speaker 300.
Referring specifically to
The speakers 300 can be vertically flown (hung) as shown in
A reinforcing bracket 381 extends between the lower edge portion of the crossbar 378 and the lower edge portion of the canted end sections 376 of side bar 372 to enhance the structural integrity of the flybar structure 370. The bracket 381 includes a turned up edge portion 381a to overlap the lower edge portion of the crossbar 378, and is attached to the crossbar by appropriate hardware members 381b. Bracket 381 may include a similar turned up edge portion to overlap canted side section ends 376 and can be fastened thereto by hardware members similar to hardware members 381b.
Cross holes 384 are formed in the end portions of the crossbar 378 to enable the speaker columns 302 to be hung from two attachment points, one located on each side of the center of the speaker column. Alternatively, a speaker column can be hung from a single center opening or attachment point 386 located at the center of the crossbar 378.
Referring specifically to
The construction of the flybar structure 370 enables the vertical speaker arrays 302 to be conveniently joined together in side-by-side relationship to each other by placing corresponding side bar structures 370 of the adjacent vertical arrays in face-to-face relationship to each other and then securing the corresponding flybar structures together. In this regard, flybar structure 370 includes pins 410 projecting outwardly from one side bar 372. Each of the pins has an enlarged and pointed head portion 412 to initially engage through an enlarged portion 414 of a horizontal slot 416 formed in the side bar section 374 of an adjacent flybar structure 370. Once the head 412 of the pin 414 has extended through the enlarged portion 414 of the slot 416, the pin 410 can be slid forwardly in the slot 416 to engage a narrower portion of the slot 416 that corresponds substantially to the width or diameter of the pin 410. When the pin 410 is in such position, the side bars 372 of the flybar structures 370 are in substantially a face-to-face position with each other and can be locked together in such position by any number of locking mechanisms.
The speakers 300 are conveniently attachable one on top of the other. In this regard, each of the speakers 300 includes rigging latches 420 slidably disposed within the lower portions of the rigging channels 400 formed in the corner structure columns 348. The vertical movement of the latches 420 are controlled by manually graspable latch grips 422 which are connected to the latches 420 by a horizontal shaft 424 that slides within a vertical slot 426 formed in the column structure 348. Speakers 300 are attached in stacked relationship with each other by releasing the rigging latches 420 of an upper speaker to engage within the channels 400 of a lower speaker by gravity. Thereafter, the rigging latches 420 are locked in place within the channels 400 of the lower speaker.
When one speaker is positioned above the other, the vertically slideable rigging latches 420 are released by operating latch grip 422 so that the horizontal shaft 424 is in alignment within slot 426, thereby allowing the shaft 424 to slide downwardly in the slot 426 and also allowing the rigging latch 420 to slide downwardly within rigging channel 400. At the time the rigging latches 420 are lowered from the upper speaker 300, the latching pins 398 of the lower speaker are disposed and retracted into outward position by manipulating the locking pin grip 406 thereof. Once the rigging latches 420 have slid downwardly into the channel 400 of the lower speaker, the upper locking pins 398 are engaged through the engagement holes 434 extending through the lower ends of the rigging latches 420, thereby to lock the rigging latches 420 with the lower speaker 300. The rigging latches 420 only extend downwardly below the lower surface of the upper speaker a distance sufficient for the latching pins 398 to engage through the rigging latch holes 434. In this manner, the speakers 300 can be quickly and conveniently coupled together in a secure manner without requiring any tools.
It will be appreciated that by the foregoing construction, the speakers 300 can be arranged in vertical arrays of any desired height. Also, the components for rigging speakers one on top of the other are “built in” within the envelope of the speaker perimeter, which facilitates attaching two or more vertical speaker arrays side-by-side to each other.
Moreover, since the speakers 300 are flown in vertical relationship to each other, there is no need to position adjacent speakers at an angle relative to the horizontal or relative to each other or to adjust any angularity between the speakers. This greatly simplifies the flying of the speaker arrays in terms of required rigging equipment or structure as well as rigging time.
As shown in
Referring specifically to
Each of the loudspeakers 300 also includes a test key 452 that queries the loudspeaker for the last known status of the loudspeaker's internal electronics. See
Also, each speaker 300 includes a built-in microphone 460 to perform in-situ diagnostics of the speaker; see
To describe the foregoing more specifically, the control panel 454 of each speaker houses a calibrated microphone 460 that is used to confirm the operation of the transducers within the loudspeaker. At the time of manufacture, the frequency response of each transducer 330 is measured by the front panel microphone and then stored in the speaker's non-volatile memory. When physical diagnostics are performed (for example, in the shop after a performance), the frequency response of each transducer is measured and compared to the factory-stored response. If the two measurements vary significantly, the control system 510 provides an alert and recommends a corrective action, for example, transducer repair or replacement. If it is necessary to replace a transducer, the measured response for the new component is compared to that of the original component at the time of manufacture. If the new component is within the specifications of the original component, the new responses are stored in the non-volatile memory of a speaker in place of the factory-measured response, and on a going-forward basis is used for comparison in future diagnostics. In this manner, it is possible to objectively verify the performance of each transducer 330 of the speaker.
As a further feature, each of the speakers 300 may include a built-in tilt sensor located within the interior of the speaker. This sensor can help establish the hang angle of the speaker array, which should be substantially vertical. The tilt sensors provide active feedback to the control system 510 of the speaker, described below.
As noted above, each ultra-low frequency transducer 330 of a speaker 300 is individually powered, as well as individually controlled. This is schematically illustrated in
Further, as shown in
Input of digital/audio signals to the control system 510 can be via AES/EBU (AES3) port 530 routed through an analog-to-digital converter 532. The input to the controller 510, as well as the output therefrom, also may be routed through Dante-enabled ports 534. The Dante ports also function as a network interface to the control system 510.
The definition of the performance venue is “drawn” in software using dimensional information available pertaining to the venue, including its length, width, seating areas, stage elevation and position and size, balcony locations and position, etc. Once the loudspeaker arrays have been flown in a venue, the venue configuration can be confirmed by using one or more microphones positioned at one or more points in the venue; see step 560. In this regard, the audio system of the present disclosure generates several impulses at different locations. The system of the present disclosure can trilaterate the location of the microphone. This information assists in modifying a preference or making corrections to the venue model. It will be appreciated that by using this trilateration function, it is not necessary to make manual measurements of the venue and carry out the associated numeric data entry of such measurements.
In step 552, noted above, one or more loudspeaker arrays are configured to match the venue in question, including matching the size and shape of the venue as well as the location of the audience members and based on the ideal wave front for the venue. In this regard, algorithms have been developed to model the output of the loudspeakers 300 and each of the transducers 330, not only to provide sound to all desired areas of a venue, but also to achieve pleasing results. In one approach, the venue can be divided into a grid of spots, and the loudspeakers are aimed to direct sound to each spot. The loudspeaker arrays are constructed from identical speakers 330 and a rating system, as described above, is used to quickly and conveniently construct and position the arrays at the venue.
At steps 354 and 356, the operating parameters of each of the ultra-low frequency transducers of each loudspeaker are determined to optimize the speakers to the venue. As discussed above, each such transducer is independently powered and processed. In this regard, the control system 510 of the present disclosure is aware of the location of each of the speakers 300. As discussed above, four infrared or other type of proximity transceivers 450 are mounted on each loudspeaker housing. The transceivers are located one on each side of the speaker housing, which enables the speakers to be modeled as two-dimensional arrays. With this information, the physical layout of the loudspeakers is determined. The data transmission that occurs between each loudspeaker identifies each adjacent loudspeaker. In this manner, the position of each loudspeaker 300 is determined.
Also as noted above, each loudspeaker can include a tilt sensor to confirm that the loudspeaker in question is in vertical position, or whether the loudspeaker is at an angle off vertical. This information is helpful in adjusting or targeting the output from each speaker.
Using the control system 510, described above, the horizontal output of each transducer can be controlled.
The control system 510 also can be used to control the vertical directional output from the speakers 300. The vertical output polar plots for the frequencies 25 Hz, 31.5 Hz, 40 Hz, 50 Hz, 63 Hz, 80 Hz, 100 Hz, and 125 Hz are shown in
It will be appreciated that all of the speakers 300 within an array 302 are networked together, and thus enable integrated control of the transducers via a computer processor which operates a DSP as well as applicable algorithms to control the output and directionality of each of the transducers in each of the speakers. Such computer processor calculates all of the lobe formation parameters for the speakers and communicates them to the loudspeakers.
The network control system also monitors the operation and performance of all the loudspeaker transducers in the array on an ongoing basis; see step 566. Since the performance parameters for the loudspeaker components are sent electronically to the loudspeaker components from the control system, such parameters can be modified very quickly at any time. Some of the monitor parameters include transducer impedance, amplifier temperature, voltage and current level of each transducer. This information is recorded on a “live” status log that can be downloaded. In this regard, not only is the functionality of each transducer confirmed, but also the control system accesses the complete performance of each transducer by comparing such performance with reference parameters stored in memory. Also, follow-up or supplemental venue measurements can be conducted at any time, as discussed above, thereby to more fully and accurately define the venue. For example, if additional seats in the venue are sold, or the performers are not satisfied with the sound quality, the coverage of the speakers can be easily modified.
Moreover, if failure of one or more transducers 330, or an entire speaker 300, occurs after the speaker arrays are flown, or even during a performance, the failure is recognized by the network control system and corrective action can be taken at step 568. Even before the overall system monitoring occurs, each loudspeaker can be tested, since each loudspeaker contains a self-test function built in to the circuitry of the loudspeaker system to enable verification that all the components of the loudspeaker are operating correctly. The results of this test can be queried by simply pressing the self-test button 452 on the loudspeaker.
If a portion of the system is damaged, the control system will determine a solution and adjust the system coverage in response. Essentially, the control system is able to rebuild the acoustical model of the loudspeaker components without the “failed” source(s). In this regard, the transducer parameters can be adjusted to affect the vertical direction between adjacent speakers and direct sound to every “spot” in the venue. Therefore, “spots” to be hit are redefined to adjust the non-functioning transducer. If a particular loudspeaker, or the transducers thereof, cannot “hit” a desired spot in a venue, then adjacent loudspeakers and/or transducers are used to “fill in” the sound to achieve the desired coverage. Due to the reduction in sound level over distance, typically, more loudspeaker components are focused at farther areas, and fewer loudspeaker components are directed at closer areas. It is not necessary to physically alter speaker-to-speaker angles, but instead digital signal processing is used to alter the component-to-component angles in accordance with the new virtual acoustical model created with the failed source(s) removed. The same process is used to achieve the desired horizontal coverage in the instance that a failure occurs in one or more of the transducers, or even in the entire speaker.
As with speaker 100 discussed above, speaker 300 and the arrays constructed therefrom, provide significant advantages over preexisting loudspeaker arrays. For example, in the arrays of the present disclosure, the position of each loudspeaker is self-recognized, and all of the drivers/transducers in each loudspeaker are networked together and individually powered and controlled for output level as well as horizontal and vertical directionality. In addition, the present loudspeaker system is “self-healing” and adapts if one or more component failures occur, even during use. Further, the rigging of the loudspeaker is simplified and thus the arrays can be flown quickly and easily and also disassembled quickly and easily.
While exemplary embodiments of the present disclosure have been illustrated and described, it will be appreciated that various changes can be made therein without departing from the spirit and scope of the invention. For example, although loudspeaker 100 is illustrated and described herein as composed of 14 high-frequency transducers, six mid-range transducers and two low-frequency transducers, the number of high-frequency, mid-range and low-frequency transducers can be altered or modified. Regardless of the numbers of the various transducers used, what is of significance is the close and relative arrangement of the transducers and drivers, the manner of their loading using horns, horn walls, horn flairs, phase plugs, and other structures, and that they are each individually controlled.
With respect to loudspeaker 300, it will be appreciated that such loudspeaker is illustrated and described as composed of two back-to-back ULF transducers 330; however, a different number of transducers can be utilized. Regardless of the number of ULF transducers used, of significance, among other features, is the offset loading of such transducers, for example, with the sound outlets from the speaker 300 at its corners 336. Also of significance are the ability to rotate the transducers to change the sound coverage of the transducers, and the individual operation and control of the transducers.
It will be appreciated that loudspeakers 100/300 and the various arrays that may be constructed therefrom provide significant advances and advantages. For example, each of the loudspeakers of the array can be of identical construction, thereby minimizing the need for spare components or parts. The loudspeakers are arrayed in a vertical arrangement, and are “dead hung,” thereby simplifying the flying of the arrays. In this regard, there are no vertical splay angles to adjust. Further, by the selection of the number of transducers and horns, their size and their spacing and relative location, the speakers 100 create a radial coverage pattern that is very narrowly focused.
Further, as described above, the tuning of the drivers and transducers of the loudspeakers is carried out electronically, and thus the parameters for the transducers and drivers can be conveniently and rapidly specified, as well as adjusted. This also enables the drivers and transducers in speakers 100/300 to adjust if any of the drivers and transducers fail during use. Further, the speakers 100/300 enable the arrays to be precisely configured to a particular venue and also enable the system to be scaleable to a particular venue.
Moreover, by the construction and control of loudspeakers 100/300, loudspeakers 100/300 and the arrays composed thereof enable the loudspeaker and arrays to produce a continuous and consistent beam width versus frequency characteristic over the entire working frequency range of a loudspeaker. Further, the loudspeakers 100/300, and the arrays composed thereof, exhibit continuous and consistent directional pattern characteristics versus frequency output from the loudspeaker, while occupying a relatively small amount of physical space, especially for the level of output generated by the loudspeaker.
This application is a continuation-in-part of U.S. application Ser. No. 14/683,009, filed Apr. 9, 2015, which is a continuation-in-part of U.S. application Ser. No. 14/489,340, filed Sep. 17, 2014, which is a continuation-in-part of U.S. application Ser. No. 13/832,817, filed Mar. 15, 2013, and this application also is a continuation-in-part of U.S. Design application No. 29/512,448, filed Dec. 18, 2014, all of the disclosures of which are hereby incorporated by reference herein in their entirety.
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