This invention relates to a method for reproduction of audio signals, primarily in relation to optimizing the reproduction of audio signals from an apparatus with a variable number of speakers.
Multi-speaker audio systems currently in the market may be wired, wireless, or a hybrid with a combination of the aforementioned. Wired audio systems rely on cables to transmit signals between source and amplifier, and between that and the speakers. However, the use of the cables creates issues pertaining to clutter due to the cables and undesirable aesthetics which has driven up demand for wireless speaker systems by consumers who wish to avoid the aforementioned issues.
There are currently several forms of wireless speaker systems which have been introduced onto the market. However, each of these various forms of wireless speaker systems have limitations which are detrimental to the usability of such wireless speaker systems.
The first form of wireless speaker systems is a direct playback type whereby a single speaker is connected wirelessly to an audio source. In a direct playback type of wireless speaker system, it is necessary for the audio source to either have or be coupled with a compatible wireless transceiver to enable communication with the speaker. A typical example of compatible wireless transceivers involves use of radio frequency waves like Bluetooth.
The second form of wireless speaker systems is a multi-room playback type whereby a transmitter unit relays identical audio signals emanating from an audio source to one or more speakers in more than one room to receive the audio signals wirelessly such that audio content heard in the various rooms are identical. A typical example of the wireless transmitter unit for the second form of wireless speaker systems involves use of 2.4 GHz radio frequency waves which have a reasonable range of deployment.
The third form of wireless speaker systems is a multi-channel playback type whereby a wireless transmitter transmits different streams of audio to multiple speakers in a single room. This is typically known as surround sound speaker systems and is best utilized when consuming movie content with multi-channel audio tracks. A typical example of the wireless transmitter unit for the third form of wireless speaker systems involves use of 2.4 GHz radio frequency waves which have a reasonable range of deployment.
In the aforementioned forms of wireless speaker systems, it is usual for the wireless speaker systems to use hardware such as, for example, transmitter, wireless rear speaker, wireless subwoofer, and the like which are bespoke for a particular wireless speaker system, and as such, the individual constituents of the wireless speaker systems do not have much functionality when deployed individually.
This is especially problematic for the multi-channel playback type of wireless speaker systems, as rear speakers are often either incorrectly installed location-wise or are discarded because of their adverse impact on interior décor aesthetics. In such instances, both the rear speakers and the transmitter which are bespoke to the wireless speaker system, become redundant. Even though consumers are aware of tangible benefits that multi-channel speaker setups bring towards movie and music playback, the prevalence of such instances has unfortunately led to widespread user and market aversion towards multi-channel speaker setups.
Finally, the popularity of multi-room playback type of wireless speaker systems has been battered in view of the ubiquity of low cost, large storage capacity, and network capable media playback devices and the fact that an appearance of individual speakers of the multi-room playback type of wireless speaker systems are not likely to be able to match interior décor aesthetics in various rooms.
The present invention aims to address the aforementioned issues in relation to wireless speaker systems.
In accordance with an embodiment of the disclosure, there is provided a calibration method for calibrating a variable number of speakers. The method includes determining physical features around a location of each of the variable number of speakers and calibrating at least one of the variable number of speakers.
The physical features around a location of each of the variable number of speakers can be determined by:
The calibration signals can be communicated from the device to at least one of the variable number of speakers so as to calibrate at least one of the variable number of speakers.
In order that the present invention may be fully understood and readily put into practical effect, there shall now be described by way of non-limitative example only preferred embodiments of the present invention, the description being with reference to the accompanying illustrative drawings:
The present invention relates to a method which will be described in a process flow. It should be noted that an order of the process flow of the method need not be strictly adhered to in order to fall within a scope of the present invention.
Referring to
The method 20 includes determining performance characteristics of each of the variable number of speakers (22). The performance characteristics of each of the variable number of speakers refers to at least one parameter such as, for example, frequency response, maximum sound pressure level, gain, compression settings and the like. The at least one parameter may relate to either a physical or acoustic attribute of each speaker.
The performance characteristics of each of the variable number of speakers are subsequently compared with each other (24) and a master speaker is designated from the variable number of speakers either with or without manual intervention (26). It should be noted that manual intervention may involve activating a specific mode on the designated master speaker. A speaker from the variable number of speakers may be designated as the master speaker based on arbitrary parameters such as, for example, speaker location, upstream processing capability, and the like. The master speaker may reduce its own gain and alter the frequency response so as to produce a substantially equivalent sonic output to a slave speaker. The designated master speaker controls and coordinates the variable number of speakers in the apparatus for audio reproduction in a manner as shown in
Referring to
The data transferred between the master 60 and the slave 62 speakers is divided into four types, namely, commands 64, query 66, audio transmission 68, and events 70. The data may generally be deemed to include attributes (permanent parameters of each speaker), status information (operational parameters of each speaker), and register information (toggling instructions for attributes). The four types of data may be described as follows:
The method 20 further includes identifying a location of each of the variable number of speakers (28). The location of each of the variable number of speakers is defined with reference to a position of the designated master speaker. The location of each of the variable number of speakers may be perceived in a manner where a room is a sealed rectangular box. Doors, corridors, passages and other architectural features may cause the room to deviate from the form of a rectangular box. In order to address such an issue, a series of overlapping boxes could be grouped together to better represent the room and correspondingly, also better represent the location of each of the variable number of speakers.
The method 20 also includes determining a distance between each of the variable number of speakers and if each of the variable number of speakers is within a single room (30). This could be carried out by:
When the speakers are determined to be either separated by room boundaries such as a wall/partition, or are too distant (beyond a range suitable for the performance characteristics of at least one of the variable number of speakers) to function effectively as a single system in view of the individual performance characteristics of each of the variable number of speakers, the speakers may function independently. It should be noted that each of the variable number of speakers is capable of relaying audio signals amongst each other when each of the variable number of speakers function independently.
For instance, when the speakers are located in different rooms, each speaker may be configured such that it reproduces all channels of an incoming audio signal when functioning independently. When a speaker is capable of reproducing stereo sound only, the speaker may be configured in a manner such that an incoming multichannel audio signal may be either mixed down to stereo, or virtualized such that this signal could be audibly reproduced over just two channels. But when the speakers are repositioned such that they are now located within a single room, the speakers may correspondingly be re-configured such that each speaker only reproduces a portion of the incoming audio signal. To further illustrate the aforementioned, when there is an incoming stereo audio signal and three speakers in a single room, one of the speakers may be used to playback the left channel signal, another the right channel signal while a third speaker may be used to reproduce a synthesized low frequency channel derived from the left and right audio signals.
In a one room system, the distance between speakers may be used as an input parameter for audio signal processing to ensure that an optimal listening experience is maintained regardless of how the system is physically arranged. For example, when listening to a stereo setup, an optimal listening experience is possible when the speakers are set apart at a distance, such that the two speakers and the listener are located at the vertices of an area defined by an equilateral triangle. Unfortunately, space and aesthetic constraints typically result in speakers being positioned closer than desired. However, such issues may be addressed with the use of audio signal processing whereby much of the lost stereo separation may be restituted with a suitable amount of cross-talk cancellation and midrange (1-4 kHz) equalization—the amount of which is varied according to the distance the speakers are set apart at.
There is also determination of physical features around the location of each of the variable number of speakers (32) in the method 20. The apparatus for audio reproduction could be input with information on the physical layout of the environment it is located in. The information such as, for example, room size, layout, floor plan and so forth may be input into the apparatus via either a conversion software running on an external computing device, or each speaker may incorporate detection capability via at least one manner selected from use of optics beams and use of audio signals (as described in preceding paragraphs) such that physical features of the environment such as, for example, room size, entry and exit points, location of speakers relative to each other, room boundaries and the like may be determined. Determining the physical features around the location of each of the variable number of speakers also allows the apparatus for audio reproduction to make adjustments for audio output due to speaker re-positioning, without a need for manual intervention.
Determination of physical features around the location of each of the variable number of speakers (32) will be discussed later in further detail with reference to
In an instance when the apparatus for audio reproduction includes a subwoofer (34), the method 20 may further include determining cumulative output levels of the variable number of speakers and setting the performance characteristics of the subwoofer added to the variable number of speakers (36). Subwoofers typically improve the performance of the apparatus for audio reproduction by augmenting low frequency sounds that are missing from smaller full range (FR) speakers. By relieving the FR speakers from a burden of producing low frequency sounds, additional improvement in system sound pressure level (SPL) could be obtained as well. When the subwoofer is added, a level, crossover frequency and phase setting of the subwoofer has to be adjusted to match those of the other speakers in the apparatus for audio reproduction. In the method 20, given that the performance characteristics of all speakers are made known to the master speaker as described earlier, the settings of the subwoofer and FR speakers may correspondingly be derived and optimized algorithmically without user intervention or direct measurement.
In a most basic implementation, the master speaker would determine the cumulative output level of the FR speakers, and set the cumulative output level of the subwoofer accordingly. For practical reasons to enable use of lower cost subwoofers and FR speakers in the method 20, the crossover frequency and slope of both subwoofer and FR speakers may be standardized using such as, for example, 80 Hz, Linkwitz-Riley 4th order. The method 20 would be desirable for use in the apparatus for audio reproduction where a lower crossover frequency, and a lower maximum system SPL is tolerated.
Finally, the method 20 may also include calibrating the apparatus for audio reproduction by using a microphone coupled with the designated master speaker to enable audio pulses to be received from each of the variable number of speakers excluding the designated master speaker (38). This allows the apparatus for audio reproduction to detect a position of the listener, and consequently allows for the performance of the speaker system to be optimized for the location of the listener.
The FR speakers and subwoofer should have programmable response characteristics. The master speaker compares the low frequency SPL capability of the FR speakers, to the corresponding low frequency SPL of the subwoofer(s), and derives an optimized crossover frequency and appropriate level settings. Additional parameters of for example, time difference of arrival (TDOA), frequency response and the like may be obtained at the listener's position via a calibration microphone.
When a single speaker is matched to a subwoofer, the maximum SPL of the system is most likely to be limited by the low frequency output capability of the FR speaker. By choosing a higher crossover point for this scenario, a very significant improvement in overall system SPL could be achieved.
A representative small full range speaker might contain 2×2.75″ drivers in a sealed enclosure, powered by 40 w of amplification, and cover a range of 80-20,000 Hz (−3 dB). This gives a maximum midrange SPL of 100 dB/1M, but only 80 dB SPL at 80 Hz/1M before the speaker driver units run out of linear driver excursion. If such a speaker is augmented by a subwoofer, crossed at 80 Hz, it would be clear that the system is still limited by the full range speaker's low frequency SPL to 80+6 dB (contribution from the subwoofer)=86 dB, regardless of the SPL capability of the subwoofer.
To achieve an improvement in the SPL limit, the crossover could be set higher at 180 Hz, where the full range speaker is limited by its linear driver excursion limits to 94 dB. The combination of the subwoofer and full range speaker now yields 94+6 dB=100 dB. The system can now play into low frequency at SPLs comparable to what it could achieve in the midrange. The master speaker, optimizing for SPL, follows the same logic of matching SPLs to set a crossover frequency of 180 Hz. At this higher crossover frequency, however, the TDOA to the listening position between full-range speakers and the subwoofer becomes critical acoustically, and has to be taken into account if flat response is to be achieved. At the 180 Hz crossover frequency as mentioned earlier, the corresponding wavelength is 1.9 m. If the time of flight difference is an odd multiple (for example, 0.95 m, 2.85 m . . . ) of half the wavelength, the output of the FR speaker and subwoofer becomes cancelled at the listener's position.
In most instances, this cancellation would not be complete, but it is evident that time alignment is quite important for systems that uses higher crossover frequency. In order to measure the TDOA of the various speakers, a microphone is connected to the master speaker, and a suitable signal such as an impulse is sent sequentially to each speaker for playback. Comparing the signal received gives a direct readout of the TDOA. Apart from having a reasonably wide bandwidth, there is no need for a especially flat midrange and treble response for the microphone, hence the microphone unit built into either a portable digital playback device or cellular phone which could be connectible to the master speaker.
In a subwoofer-FR speaker setup, the TDOA information may be used to correct for the response irregularity arising from undesirable time alignment in a variety of ways. Firstly, the TDOA could be restituted by means of adjusting a variable delay in either subwoofer or FR speaker. This requires delay capability in both units to be fully functional. Secondly, a frequency dependent delay could be implemented in a transmitting speaker (typically the master FR speaker), such the frequency bands covered by FR speakers and subwoofer are affected by different delays. This correspondingly places the burden of time correction on a transmitting speaker capable of this processing capability and the subwoofer may be relieved of the need for a variable delay block. Thirdly, a gradient and polarity of the crossover unit and the amount of overlap may be manipulated in consideration to the measured TDOA, such that the resultant response is flat. As such, with crossover frequency 180 Hz, TDOA=1.25 m, 4th order Linkwitz Riley crossover slopes, could be made to measure flat at listener's position by reversing the polarity of either subwoofer or FR speaker. In addition, increasing the overlap area, reducing or increasing the slope or Q of each speaker's filtering could be used to compensate for the response irregularity as well.
The microphone could be used to verify the result of the corrective measures as well, to ensure an even response is being produced. This may involve measurement of the apparatus for audio reproduction in the low frequency region below, at and above the crossover point. A swept tone signal may be employed, spatially averaged by separately measuring at the listening position and at several locations at the listener's area, or could involve the listener physically moving the microphone around the listener's area when a single measurement is being made.
It should be noted that when the method 20 is employed for an apparatus for audio reproduction, the user does not need to commit to a pre-configured multi-room system or a pre-configured multi-channel system at a point of purchase as additional speakers may be added when necessary, or used in a different manner as requirements change. For example, the user could start with a single speaker, connected to a source device as a basic sound system. When higher loudness levels and/or a better surround sound movie experience is desired, another speaker(s) could be added. Should the user desire a different audio experience, the additional speaker may be used as an independent speaker in another room. It should be noted that nothing is rendered redundant with a change of configuration.
Earlier mentioned, physical features around the location of each of the variable number of speakers can be determined. Based on this, one or more of the variable number of speakers can be calibrated as will be discussed in further detail with reference to
Referring to
Transmitting an instruction signal (32a) can be by manner of transmitting an instruction signal from, for example, a device. Preferably the device is a portable electronic device such as a mobile phone. For example, a mobile phone can be configured to communicate an instruction signal to one or more of the variable number of speakers.
Earlier mentioned, determining physical features around a location of each of the variable number of speakers (32) can include communicating a test signal based on the instruction signal (32b).
Specifically, each of the variable number of speakers can be configured to receive the instruction signal communicated by the, for example, portable device. Based on receipt of the instruction signal, each of the variable number of speakers can be configured to transmit a test signal.
In one embodiment, the bi-directional transceiver 82 can be configured to receive the instruction signal and communicate the instruction signal to the processor. The processor can be configured to process the received instruction signal and produce a test signal. The processor can be further configured to communicate the test signal to the bi-directional transceiver 82 and/or the acoustic transducer 84. The bi-directional transceiver 82 and/or the acoustic transducer 84 can be configured to communicate the test signal. The test signal can be an audible signal or a non-audible signal. For example, based on the received instruction signal, each of the variable number of speakers can be configured to communicate an audible signal such as a 1 KHz audio tone. In this regard, the test signal can be an audible signal such as a 1 KHz audio tone which can be communicated from the speaker via, for example, the acoustic transducer 84.
Further earlier mentioned, determining physical features around a location of each of the variable number of speakers (32) can include receiving and processing the test signal (32c).
Specifically, the test signal communicated from the aforementioned variable number of speakers can be received by the, for example, portable electronic device. The portable electronic device can be configured to receive and process the test signal in a manner so as to produce calibration signals.
For example, signal characteristics such as the amplitude, phase and/or frequency characteristics of the test signal originating from the aforementioned variable number of speakers can be made known to the portable electronic device. Signal characteristics of the received test signal at the portable electronic device can be compared to the test signal originating from the aforementioned variable number of speakers so as to produce calibration signals. In this regard, the portable electronic device can be configured to treat the test signal originating from the aforementioned variable number of speakers as a reference and process the received test signal by comparing the received test signal with the reference to produce calibration signals.
The portable electronic device can be further configured to communicate the calibration signals.
In general, with regard to determining physical features around a location of each of the variable number of speakers (32), it is appreciable that the instruction signal can be considered to be a triggering signal sent by the, for example, portable electronic device to trigger the aforementioned variable number of speakers to transmit a test signal. The test signal is communicated from the aforementioned variable number of speakers to the, for example, portable electronic device for processing.
It is further appreciable that the test signal would have travelled substantially around the location of the speakers before it is received by the, for example, portable electronic device. Thus the test signal received by the portable electronic device can be indicative of environment coefficients associated with the location around the speakers. Environment coefficients can relate to the aforementioned physical layout of the environment, room size, entry/exit points, location of speakers relative to each other and/or room boundaries etc.
Yet further appreciably, since the received test signal can be indicative of environment coefficients associated with the location around the speakers, the received test signal can be used to determine physical features around the location of each speaker. Thus physical features around a location of each speaker can be determined based on the test signal.
After the physical features around a location of each speaker have been determined, the process for the calibration method 400 continues by calibrating at least one of the variable number of speakers (410) as will be discussed in further detail hereinafter.
As mentioned earlier, a test signal can be communicated from the aforementioned variable number of speakers and received by the, for example, portable electronic device for processing. The portable electronic device can be configured to process the received test signal to produce calibration signals. The portable electronic device can be further configured to communicate the calibration signals to the aforementioned variable number of speakers.
The aforementioned variable number of speakers can then be calibrated based on the received calibration signals. Calibration of the speakers can be in the context of adjusting the volume of audio output of the speakers and/or adjusting frequency characteristics of audio signals output by the speakers. For example, calibration of the speakers can be in the context of audio equalization (EQ).
In one exemplary scenario, the test signal received by the, for example, portable electronic device can indicate that the room size is relatively large. For example, by comparing the received test signal and the reference, it can be shown that there is notable/significant loss in signal amplitude. This can be indicative that the room size is relatively large. Thus calibrating signals can be communicated from the portable electronic device to the aforementioned variable number of speakers to calibrate the variable number of speakers such that the volume of audio output can be adjusted upwards (i.e., increase in volume).
In another exemplary scenario where the test signal received by the, for example, portable electronic device is indicative that based on the physical layout of the environment, it is desirable for certain audio frequencies to be boosted and/or certain audio frequencies to be attenuated, the aforementioned variable number of speakers can be calibrated accordingly. For example, based on the physical layout of the environment, it may be desirable for high frequency signals to be attenuated and low frequency signals to be boosted. The test signal received by the portable electronic device can be indicative of such desirability and the portable electronic device can process the test signal to produce calibration signals which are in turn communicated to the aforementioned variable number of speakers to calibrate the aforementioned variable number of speakers accordingly.
Therefore, based on the calibration signals communicated from the, for example, portable electronic device, the aforementioned variable number of speakers can be calibrated.
It is appreciable that the location of the, for example, portable electronic device can be representative of the listening position of a listener relative to the aforementioned variable number of speakers. Thus it is also appreciable that the calibration method 400 facilitates calibration of the aforementioned variable number of speakers such that audio output therefrom can be optimized, taking into consideration the environment of the speakers and the position/location of the listener, in a manner so as to enhance listening experience of the listener.
Whilst there has been described in the foregoing description preferred embodiments of the present invention, it will be understood by those skilled in the technology concerned that many variations or modifications in details of design or construction may be made without departing from the present invention.
Number | Date | Country | |
---|---|---|---|
Parent | 12963582 | Dec 2010 | US |
Child | 13664367 | US |