Noises that are to be emitted by an aerial vehicle during operations may be predicted using one or more machine learning systems, algorithms or techniques. Anti-noises having equal or similar intensities and equal but out-of-phase frequencies may be identified and generated based on the predicted no
Noises that are to be emitted by an aerial vehicle during operations may be predicted using one or more machine learning systems, algorithms or techniques. Anti-noises having equal or similar intensities and equal but out-of-phase frequencies may be identified and generated based on the predicted noises, thereby reducing or eliminating the net effect of the noises. The machine learning systems, algorithms or techniques used to predict such noises may be trained using emitted sound pressure levels observed during prior operations of aerial vehicles, as well as environmental conditions, operational characteristics of the aerial vehicles or locations of the aerial vehicles during such prior operations. Anti-noises may be identified and generated based on an overall sound profile of the aerial vehicle, or on individual sounds emitted by the aerial vehicle by discrete sources.
대표청구항▼
1. An unmanned aerial vehicle (UAV) comprising: a frame;a Global Positioning System (GPS) sensor associated with the frame;at least one acoustic device mounted to the frame;a plurality of motors mounted to the frame;a plurality of propellers, wherein each of the plurality of propellers is coupled to
1. An unmanned aerial vehicle (UAV) comprising: a frame;a Global Positioning System (GPS) sensor associated with the frame;at least one acoustic device mounted to the frame;a plurality of motors mounted to the frame;a plurality of propellers, wherein each of the plurality of propellers is coupled to one of the plurality of motors;a sound emitting device mounted to at least one of the frame or one of the plurality of motors; anda computing device having a memory and one or more computer processors,wherein the one or more computer processors are configured to at least: capture data regarding a sound using the at least one acoustic device;determine a sound pressure level of the sound and a frequency of the sound based at least in part on the data;determine, by the GPS sensor, a position of the UAV;determine at least one environmental condition associated with the position;determine at least one operating characteristic of at least one of the plurality of motors or at least one of the plurality of propellers associated with the position;determine a sound pressure level of an anti-noise and a frequency of the anti-noise based at least in part on the sound pressure level of the sound, the frequency of the sound, and at least one of: the position,the at least one environmental condition, orthe at least one operating characteristic; andemit the anti-noise from the sound emitting device of the UAV. 2. The UAV of claim 1, wherein the at least one acoustic device comprises at least one of: a microphone;a piezoelectric sensor; ora vibration sensor. 3. A method to operate a first aerial vehicle comprising a first sound emitting device mounted thereto, wherein the method comprises: predicting, by at least one computer processor prior to a first time, at least one of: a first anticipated position of the first aerial vehicle at the first time;a first anticipated environmental condition at the first anticipated position or at the first time;a first anticipated operating characteristic of the first aerial vehicle at the first anticipated position or at the first time;predicting, by the at least one computer processor, a first sound to be emitted by at least one component of the first aerial vehicle at the first time, wherein the first sound is predicted based at least in part on the at least one of the first anticipated position, the first anticipated environmental condition or the first anticipated operating characteristic;determining, by the at least one computer processor, a second sound based at least in part on the first sound, wherein a second sound pressure level of the second sound is not greater than a first sound pressure level of the first sound, and wherein a second frequency of the second sound is substantially equal in magnitude and of reverse polarity with respect to a first frequency of the first sound; andcausing, by the at least one computer processor, the second sound to be emitted by the first sound emitting device at the first time. 4. The method of claim 3, wherein the second sound is caused to be emitted by the first sound emitting device at the first time. 5. The method of claim 4, wherein the first aerial vehicle further comprises a Global Positioning System (GPS) sensor, and wherein the method further comprises:determining, by the GPS sensor, that the first aerial vehicle is at the first anticipated position at the first time,wherein the second sound is caused to be emitted by the first sound emitting device in response to determining that the first aerial vehicle is at the first anticipated position at the first time. 6. The method of claim 3, wherein the at least one component of the first aerial vehicle is at least one of a frame of the first aerial vehicle, a motor mounted to the frame, or a propeller rotatably coupled to the motor. 7. The method of claim 3, wherein predicting the first sound to be emitted by the at least one component of the first aerial vehicle at the first time further comprises: providing, by the at least one computer processor, first information regarding the first anticipated position, the first anticipated environmental condition and the first anticipated operating characteristic to at least one machine learning system as an input; andreceiving, from the at least one machine learning system, second information regarding the first sound as an output, wherein the second information regarding the first sound comprises the first sound pressure level and the first frequency. 8. The method of claim 7, wherein determining the second sound further comprises: providing first information regarding the first sound to at least one machine learning system as an input, wherein the information regarding the first sound comprises at least one of a first sound pressure level of the first sound or a first frequency of the first sound; andreceiving, from the at least one machine learning system, second information regarding the second sound as an output, wherein the second information regarding the second sound comprises a second sound pressure level and a second frequency,wherein the second sound is caused to be emitted by the first sound emitting device at the second sound pressure level or at the second frequency. 9. The method of claim 7, wherein the at least one machine learning system is configured to perform at least one of: an artificial neural network;a conditional random field;a cosine similarity analysis;a factorization method;a K-means clustering analysis;a latent Dirichlet allocation;a latent semantic analysis;a log likelihood similarity analysis;a nearest neighbor analysis;a support vector machine; ora topic model analysis. 10. The method of claim 3, wherein predicting the at least one of the first anticipated position of the first aerial vehicle at the first time, the first anticipated environmental condition at the first anticipated position or at the first time, or the first anticipated operating characteristic of the first aerial vehicle at the first anticipated position or at the first time comprises: determining that a second aerial vehicle was at the first anticipated position at a second time, wherein the second time preceded the first time; anddetermining information regarding at least one of a second environmental condition or a second operating characteristic observed by the second aerial vehicle at the first anticipated position at the second time,wherein the first sound to be emitted by the at least one component of the first aerial vehicle at the first time is predicted based at least in part on the information regarding the at least one of the second environmental condition or the second operating characteristic. 11. The method of claim 10, wherein the first sound to be emitted by the at least one component of the first aerial vehicle at the first time is predicted by at least one computer processor provided on the second aerial vehicle. 12. The method of claim 3, wherein predicting the at least one of the first anticipated position of the first aerial vehicle at the first time, the first anticipated environmental condition at the first anticipated position or at the first time, or the first anticipated operating characteristic of the first aerial vehicle at the first anticipated position or at the first time comprises: generating a transit plan for the first aerial vehicle, wherein the transit plan comprises information regarding a plurality of anticipated positions of the aerial vehicle, and wherein the first anticipated position is one of the plurality of anticipated positions,wherein predicting the first sound to be emitted by the at least one component of the first aerial vehicle at the first time further comprises: predicting a plurality of sounds to be emitted by one of a plurality of components of the first aerial vehicle, wherein each of the plurality of sounds is associated with at least one of the plurality of anticipated positions of the first aerial vehicle,wherein determining the second sound further comprises: determining a plurality of anti-noises, wherein each of the plurality of anti-noises corresponds to one of the plurality of sounds, wherein each of the plurality of anti-noises has a sound pressure level not greater than a sound pressure level of the one of the plurality of sounds, wherein each of the plurality of anti-noises has a frequency that is substantially equal in magnitude and of reverse polarity with respect to a frequency of the one of the plurality of sounds, wherein the second sound is one of the plurality of anti-noises, and wherein each of the plurality of anti-noises corresponds to the one of the plurality of positions. 13. The method of claim 3, wherein the first sound emitting device comprises one of an audio speaker, a piezoelectric sound emitter or a vibration source provided on the first aerial vehicle. 14. The method of claim 3, further comprising: determining a noise threshold within a vicinity of the first anticipated position,wherein the second sound is determined based at least in part on the first sound and the noise threshold within the vicinity of the first anticipated position. 15. The method of claim 14, wherein determining the second sound based at least in part on the first sound further comprises: determining at least one of the second sound pressure level or the second frequency based at least in part on the first sound and the noise threshold,wherein a sum of the first sound pressure level and the second sound pressure level is less than the noise threshold at a predetermined time. 16. The method of claim 3, wherein the first anticipated environmental condition comprises at least one of: a first temperature at the first anticipated position or at the first time,a first barometric pressure at the first anticipated position or at the first time,a first wind speed at the first anticipated position or at the first time,a first humidity at the first anticipated position or at the first time,a first level of cloud coverage at the first anticipated position or at the first time,a first level of sunshine at the first anticipated position or at the first time, ora first surface condition at the first anticipated position or at the first time. 17. The method of claim 3, wherein the first anticipated operational characteristic comprises at least one of: a first rotating speed of a first motor provided on the first aerial vehicle at the first anticipated position or at the first time,a first altitude of the first aerial vehicle at the first anticipated position or at the first time,a first course of the first aerial vehicle at the first anticipated position or at the first time,a first airspeed of the first aerial vehicle at the first anticipated position or at the first time,a first climb rate of the first aerial vehicle at the first anticipated position or at the first time,a first descent rate of the first aerial vehicle at the first anticipated position or at the first time,a first turn rate of the first aerial vehicle at the first anticipated position or at the first time, ora first acceleration of the first aerial vehicle at the first anticipated position or at the first time. 18. A method comprising: identifying, by at least one computer processor, information regarding a first transit of a first aerial vehicle, wherein the first transit comprises travel over a first position by the first aerial vehicle at a first time, and wherein the information regarding the first transit of the first aerial vehicle comprises at least one of: a latitude of the first position;a longitude of the first position;an altitude of the first aerial vehicle at the first position and at the first time;a course of the first aerial vehicle at the first position and at the first time;an air speed of the first aerial vehicle at the first position and at the first time;a climb rate of the first aerial vehicle at the first position and at the first time;a descent rate of the first aerial vehicle at the first position and at the first time;a turn rate of the first aerial vehicle at the first position and at the first time;an acceleration of the first aerial vehicle at the first position and at the first time;a rotating speed of a first motor mounted to the first aerial vehicle at the first position and at the first time, wherein the first motor has a first propeller rotatably coupled thereto; orat least one frequency of at least a first sound captured by a first sound sensor provided on the first aerial vehicle at the first position and at the first time;at least one sound pressure level of at least the first sound; ora first environmental condition encountered by the first aerial vehicle at the first position and at the first time;determining, by the at least one computer processor, at least one frequency of a second sound and at least one sound pressure level of the second sound based at least in part on the information regarding the first transit of the first aerial vehicle;generating, by the at least one computer processor, a transit plan for a second transit of a second aerial vehicle, wherein the second transit comprises travel over the first position by the second aerial vehicle at a second time, wherein the transit plan comprises a plurality of instructions, andwherein one of the plurality of instructions is an instruction to emit, by a sound emitting device provided on the second aerial vehicle, at least the second sound at a second time or upon determining that the second aerial vehicle is within a vicinity of the first position, andstoring the transit plan in an onboard memory of the second aerial vehicle prior to the second time. 19. The method of claim 18, wherein determining the at least one frequency of at least the second sound and the at least one sound pressure level of at least the second sound comprises: providing, by the at least one computer processor, the information regarding the first transit of the first aerial vehicle to at least one machine learning system as an input; andreceiving, from the at least one machine learning system, information regarding the second sound as an output, wherein the information regarding the second sound comprises the at least one frequency of the second sound and the at least one sound pressure level of the second sound. 20. The method of claim 18, further comprising: identifying, by the at least one computer processor, a noise threshold within a vicinity of the first position, wherein at least one of the at least one sound pressure level of the second sound or the at least one frequency of the second sound is determined based at least in part on the noise threshold within the vicinity of the first position.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (9)
Warnaka, Glenn E.; Zalas, John M., Active attenuation of noise in a closed structure.
Burdisso Ricardo (Blacksburg VA) Fuller Chris R. (Blacksburg VA) O\Brien Walter F. (Blacksburg VA) Thomas Russell H. (Blacksburg VA) Dungan Mary E. (Malden SC), Active control of aircraft engine inlet noise using compact sound sources and distributed error sensors.
Johnson, Samuel Alan; Burkard, William Dennis; Mimlitch, III, Robert H.; Mimlitch, Jr., Robert Henry; Norman, David Anthony, Aerial robot with dispensable conductive filament.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.