Rotating devices, such as cooling fans and disk drives, in a computer system typically emit acoustic noise. Cooling fans in general generate a periodic noise known as a blade passing frequency (BPF), a noise that is generated at the tip of blades. An example of a conventional layout of rotating devices within a notebook computer is illustrated in
The acoustic noise is often disturbing and has even been found to be damaging in environments such as datacenters, which contain many high performance fans. The acoustic noise has also been found to be highly distracting in quiet environments such as a home theater where a media computer is deployed.
A conventional way to remove fan noise has been through the use of passive noise control mechanisms. One conventional, passive noise control mechanism contains no fans, but instead, uses relatively large amounts of copper, heat pipes, heat sinks, etc. to adequately cool computer system components. However, due to the amount of materials required to implement the passive noise control mechanism, such a solution has often been expensive to implement.
Another conventional, passive noise control mechanism uses specially designed large and low-speed fans to shift the BPF into lower frequency bands, where the fan noise is less disturbing to the human ear. Still another conventional, passive noise control mechanism uses suitable noise absorbing materials and mounting components with suitable fasteners to reduce vibration and noise and thus avoid the so-called “tuning fork effect.” In general, the use of noise absorbing materials tends to be more effective at reducing higher frequency noise components, but less effective at eliminating lower frequency noise.
Yet another conventional way to passively control noise has been through careful selection and placement of individual components. For example, the use of low-noise cooling fans with precision low noise bearings and tuned blade shaping have become popular.
While the above-discussed conventional, passive noise control mechanisms are available, they are often costly and/or ineffective.
A further approach at reducing fan noise is through active noise control (ANC), which is a technique used to reduce noise and vibrations emanating from electronic devices, machinery, air ducts and other industrial equipment. An example of a conventional ANC system 100 is depicted in
Conventional forms of ANC have been applied to certain consumer devices, the most popular being noise canceling headphones, where the external noise is reduced within the controlled zone of each ear-cup. Other applications where ANC has been applied include air-conditioning ducts, projectors, and large printers. However, in general, implementation of ANC in such systems is difficult because of the algorithmic complexity of the ANC and additional cost incurred with increases in the size of the enclosures housing the apparatuses. The more open the solution space and thus the size of the noise field being reduced, the less effective ANC becomes and the algorithmic complexity and costs also increase.
Although there have been recent attempts to reduce noise generated in electronic devices, such attempts have proven to be less than successful because the proposed solutions are either costly, bulky to implement, and/or ineffective.
The embodiments of the invention will be described in detail in the following description with reference to the following figures.
For simplicity and illustrative purposes, the principles of the embodiments are described by referring mainly to examples thereof. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the embodiments. It will be apparent, however, to one of ordinary skill in the art, that the embodiments may be practiced without limitation to these specific details. In some instances, well known methods and structures have not been described in detail so as not to unnecessarily obscure the embodiments.
Cooling fans in general generate a periodic noise known as a blade passing frequency (BPF). BPF is a noise that is generated at the tip of the fan blades. Cooling fans also generate a broadband noise that is mostly generated by consistent, laminar airflow noise. BPF is characterized by a distinctive high pitch whine and is generally the more annoying of the two noises. Once the BPF noise escapes into an open space outside the enclosure of electronic devices, it becomes very difficult to reduce/counter it. Thus, it is beneficial to have some control over the noise before it escapes from the electronic device enclosures.
Applying active noise control (ANC) in electronic devices, such as computers (for instance, desktop computers and notebook computers), enables use of relatively inexpensive commodity components to achieve the equivalent acoustic result of using more expensive passive component configurations. For example, according to an example, noise may be reduced by actively reducing the signature of the noise, for instance, the largest spectral components of the noise, as described in greater detail herein below.
ANC in general is more effective at reducing the higher BPF frequencies associated with small high speed fans typically employed in servers and high performance machines with space restrictions, but is generally less effective at reducing the broadband noise generated by the air rush noise. One reason for that is that noise canceling algorithms are typically more effective at reducing noises at higher frequencies.
However, unlike the ANC performed in noise canceling headphones, where noises come from outside and the noise reduction occurs in a small space, for instance, between the headphones and a user's ears, the implementation of ANC in computers with much larger internal spaces is relatively more difficult in terms of effectiveness and the required algorithms.
Disclosed herein are systems and methods that implement ANC in electronic devices in efficient, cost-saving and/or space-saving ways by using at least one of specially designed inlet/outlet ports, intermediate ducts connecting ports, a resonating chamber, and speaker(s). As also discussed herein, the speakers may be used to generate both anti-noise and user sounds.
According to an example, a conventional ANC system, such as the ANC system depicted in
The error microphone 140 may detect the amount of combined fan noise and anti-noise generated by the speaker 150 and provide a signal corresponding to the combined amount, which corresponds to the differential between the noise and the anti-noise, as an error signal to the control electronics 130.
The reference microphone 120 and error microphone 140 may each be a microphone, vibration detector, or any other suitable device that detects a noise. In addition, the reference microphone 120 and error microphone 140 may each comprise one or more microphones, for instance, multiple condenser microphones configured as an array and connected in parallel for more precise noise capture. The order of the placement of the components, 110-150, in the ANC system 100 is not limited to that shown in
The speaker 150 may be a speaker, vibration generator, or any other wave generator configured to generate an acoustic wave, such as anti-noise, sound tone, etc., and to reduce/counter all or some of the undesirable fan noise.
The control electronics 130 may be any electronics that perform, implement, or execute one or more noise-canceling algorithms based on outputs from the reference microphone 120 and the error microphone 140. The noise-canceling algorithms may include the generation and output of a signal to the speaker 150 for generating an acoustic wave to reduce the noise. More particularly, for instance, the control electronics 130 analyzes the noise captured by the reference microphone 120 and the error microphone 140 and creates a signal for creation of an anti-noise to be played back through the speaker 150. Functions of the control electronics 130 may be performed in one unitary device or multiple devices. In addition, or alternatively, some or all of the functions of the control electronics 130 may be distributed to one or more of the other components, 120, 140 and 150.
According to an example, the error microphone 140 and the speaker 150 may be directly located next to the listener's ears as in noise canceling headphones. In another example, the error microphone 140 and the speaker 150 may be directly located at the electronic device, and the listener may be in a space further away from the error microphone 140 and the speaker 150. In the latter example, the control electronics 130 and acoustic properties of the electronic device may be designed to minimize the noise in the space surrounding the electronic device and not just at the location of the error microphone 140.
Although different reference numerals are recited in the following figures to designate reference microphones, error microphones, fans, speakers and control electronics, the above description with respect to
With reference first to
The duct 281 may comprise a straight pipe, slightly cone shaped pipe, or any other suitable shaped pipe that reduces the air turbulence through the duct 281. The curved lips of the ends 282 may expand uniformly and gradually as they grow out of the duct 281. Alternatively, however, the curved lips may have any other reasonably suitable configuration. Generally speaking, the curved lips of the ends 282 and the slight cone shaped configuration of the duct 281 reduce air speed and the amount of air turbulence at the enclosure opening, and thus the broad air rush noise at the enclosure opening. The port 200, if serving as an inlet port, may incorporate a fan 210 that pushes airflow into the enclosure to push air into the enclosure and counterbalance a limited number of inlet ports and outlet ports while maintaining the cooling efficiency of the enclosure.
As also shown in
Specifically, when a noise created by the fan 210 travels through the duct 380, it propagates as a planar wave 270, which may be effectively and more easily reduced via ANC as described above. The fan 210 may comprise an internal fan positioned to direct heat away from a heat generating component, for instance. A reference microphone 220 detects the noise generated by the fan 210 and outputs a signal based on the noise to control electronics 230. The control electronics 230 outputs a signal to a speaker 250, which provides an anti-noise to reduce/counter the noise based upon the signal received from the control electronics 230. An error microphone 240 is used to detect the result of the noise-reduction and provides a signal corresponding to the detected result to the control electronics 230, which may use the detected result in varying the speaker 250 output.
The inlet port 200′ and outlet port 200 may each have a fan 210 to respectively push airflow into or pull airflow from an interior of the enclosure to compensate for increased air resistance due to a relatively restricted number of openings in the enclosure. Alternatively, one or more internal fans 320 may provide sufficient airflow through the intermediate duct, and one or more fans of the inlet or outlet ports 200 may be omitted.
The intermediate duct 380 may be formed by partition barriers 310 and enclosure walls 340. The partition barriers 310 create a relatively long path for noise to travel through in the enclosure. Although a single intermediate duct 380 has been depicted, it should be understood that the electronic device 300 may include any reasonably suitable number of intermediate ducts 380 without departing from a scope of the electronic device 300.
As shown, the corners 330 of the intermediate duct 380 may be rounded to form curved corners, which generally reduce air turbulence. By use of the intermediate duct 380 with the curved corners 330, internal noise, such as noise emanating from a cooling fan for a central processing unit (CPU) must travel along the intermediate duct, which shapes the noise wave-front to be more like a planar wave propagation and more suitable for application of ANC at one or both of the inlet and outlet ports 200.
In any regard, airflow enters the notebook computer 600 through an inlet port 200′ in a rear of the notebook computer 600. As shown, a cooling fan 320 is operable to cause airflow to be drawn into the notebook computer 600. In addition, the cooling fan 320 may be located at or near a source of maximum heat dissipation, which may be near the CPU and the graphics processing unit (GPU) of the notebook computer 600. In addition, the cooling fan 320 may be positioned to dissipate heat from a heat sink 620 which aids in dissipating heat from the CPUs and GPUs. A simple closed-loop-thermostat-driven circuit or closed-loop-thermometer-driven circuit may control the on/off state of the cooling fan 320 in response to changes in the temperature of the heat sink 620. The cooling fan 320 may force an airflow from the inlet port through the intermediate duct formed by internal partitions 310 (
ANC may be implemented around at least one of the ports 200. The ANC may have minimum necessary components including, one reference microphone 220, one error microphone 240 and one anti-noise speaker 250. Alternatively, the outlet port 200 and any other port with ANC may have multiple microphones and/or speakers, and the intermediate duct may be more curved than as depicted in
The anti-noise speaker 250 is generally operated to generate an acoustic wave to reduce the noise generated by the fan 320. In addition, the anti-noise speaker 250 may also purposefully generate user sounds (for instance, music from a compact disk or a system sound generated by the computer to alert the user). Such use of the anti-noise speaker 250 to generate both the anti-noise and the user sounds obviates a need for another speaker for generating one of the two sounds, allows the implementation of both features to occupy less overall space, and saves component costs, when compared with using two separate speakers.
According to an example, the anti-noise speaker 250 may also purposefully generate lower, bass frequency user sounds. An improved bass response for the speaker system may be obtained since the speaker 250 is ported inside the computer. In this example, two smaller speakers 610 may be positioned in the left and right front corners of the notebook computer 600, for instance, to generate higher, treble frequency user sounds.
As shown, the inlet port 200′ is positioned on a bottom side of the notebook computer 700. In addition, the notebook computer 700 includes two intermediate ducts 710 and 720 configured to direct exhaust airflow out of the notebook computer 700. Respective ends of the intermediate ducts 710 and 720 may comprise outlet ports 200, which are depicted as being positioned on opposite sides of the notebook computer 700. Heat generated by the electronic components (CPU, GPU, etc.) is transferred to the airflow and caused to exit from the notebook computer 700 through the outlet ports 200.
Airflow from the cooling fan 320 flows through an intermediate duct 380, which is split into a left intermediate duct 710 and a right intermediate duct 720. A left speaker 250 is positioned to supply anti-noise acoustic waves into the left intermediate duct 710, and a right speaker 250 is positioned to supply anti-noise acoustic waves into the right intermediate duct 720. The speakers 250 may also be configured to generate user sounds in stereo by allowing left and right audio channels to be separately outputted. In this regard, the anti-noise speakers 250 may be implemented to provide stereo sound, and thus, the notebook computer 700 may not need a separate set of speakers to provide the stereo sound.
According to an example, independent ANC algorithms may be applied for the ANC performed in each of the left and right intermediate ducts 710 and 720. Alternatively, ANC algorithms applied for the ANC performed in the left intermediate duct 710 may be correlated to ANC algorithms applied for the ANC performed in the right intermediate duct 720.
As shown in
The examples shown in
Although the duct, speaker and port arrangements of
At step 810, airflow for cooling components inside an enclosure for an electronic device is actively created, through, for instance, operation of a cooling fan 320.
At step 820, a port extending from an interior to an exterior of the enclosure is used to allow the airflow to exhaust from the interior of the enclosure, where the port comprises a port duct forming a sound passageway and an end having curved lips.
At step 830, a noise, for instance, generated by operation of the cooling fan 320 is detected. In addition, at step 840, an acoustic wave to reduce the noise is generated.
In connection with the method 800, partition barriers 310 (
Any one or all of the exemplary features and embodiments of the invention may be applied and is incorporated in any and all of the embodiments of the invention unless clearly contradictory.
Further, in each of the exemplary embodiment of the invention described above, any one or more of the following additional measures may be taken to reduce noise further.
For instance, passive noise control mechanisms such as vibration/noise reducing foams may be used in critical places to improve noise-performance. Also, low speed fans producing BPF below human sensitivity may be used. Specifically, in applying the ANC, fan's rotational speed may be controlled by, for example, pulse-width-modulating a drive signal to the fan, to provide a particular harmonic signature, that is the largest spectral components, to the noise the fan generates. By doing so, the noise may be provided with a known expected signal characteristic for which there is an effective noise-canceling algorithm. Also, the fan's rotational speed can be controlled to provide a noise with components that self-cancel or a noise without certain frequencies that are prone to resonance or are particularly difficult to cancel.
While the embodiments have been described with reference to examples, those skilled in the art will be able to make various modifications to the described embodiments without departing from the scope of the claimed embodiments.
The present application claims priority from provisional application Ser. No. 61/078,016, filed Jul. 3, 2008, the contents of which are incorporated herein by reference in their entirety. This application is related to copending and commonly assigned Provisional U.S. patent application Ser. No. TBD (Attorney Docket No. 200800523-1), entitled “Electronic Device Having Active Noise Control With An External Sensor,” filed by the same inventors to this instant patent application on TBD, the disclosure of which is hereby incorporated by reference in its entirety.
Number | Date | Country | |
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61078016 | Jul 2008 | US |