阅读说明：本技术 模块化的基于头枕的音频系统 (Modular headrest-based audio system ) 是由 T·Z·巴克斯达尔 M·S·达布林 C·奥斯瓦尔德 于 2014-04-28 设计创作，主要内容包括：本公开的实施例涉及模块化的基于头枕的音频系统。车辆音频系统,包括：信号处理器,被配置成接收及处理来自源的音频信号并且向放大器提供经处理的音频信号；第一头枕,包括头枕扬声器并被耦合到驾驶者的座位；第一固定扬声器,被定位在与头枕的前方的车辆的车厢的左角落接近处；第二固定扬声器,被定位在与头枕的前方的车辆的车厢的右角落接近处；以及头枕辅助端口,位于乘客的座位中。该端口被配置成将音频系统连接到第二头枕扬声器。该处理器使用第一组参数以用于在第一头枕扬声器被连接并且第二头枕扬声器不被连接时处理接收到的音频信号,以及第二组参数以用于在第一头枕扬声器和第二头枕扬声器两者均被连接时处理接收到的音频信号。(Embodiments of the present disclosure relate to modular headrest-based audio systems. A vehicle audio system, comprising: a signal processor configured to receive and process an audio signal from a source and provide the processed audio signal to an amplifier; a first headrest including a headrest speaker and coupled to a driver's seat; a first fixed speaker positioned proximate a left corner of a vehicle cabin forward of the headrest; a second stationary speaker positioned proximate a right corner of a vehicle cabin forward of the headrest; and a headrest auxiliary port located in a seat of the passenger. The port is configured to connect the audio system to a second headrest speaker. The processor uses a first set of parameters for processing the received audio signal when the first headrest speaker is connected and the second headrest speaker is not connected, and a second set of parameters for processing the received audio signal when both the first headrest speaker and the second headrest speaker are connected.)

1. A vehicle audio system comprising:

a signal processor configured to receive and process an audio signal from a source and provide the processed audio signal to an amplifier,

a first headrest including a first headrest speaker connected to the vehicle audio system and coupled to a driver's seat,

a first fixed speaker positioned proximate a front of the first headrest and a left corner of a cabin of the vehicle,

a second fixed speaker positioned proximate a front of the first headrest and a right corner of a cabin of the vehicle, an

A headrest assistance port located in a seat of a passenger and configured to: a connector housing a second headrest speaker in a second headrest and connecting the vehicle audio system to the second headrest speaker when the connector is received by the headrest auxiliary port, wherein the second headrest speaker is an optional speaker for extending the vehicle audio system during manufacture or assembly of a vehicle or after the vehicle is manufactured;

wherein the vehicle audio system is configured to detect whether the second headrest speaker is connected to the vehicle audio system, and

wherein the signal processor uses a first set of processing parameters for processing the received audio signal when the first headrest speaker is connected to the vehicle audio system and the second headrest speaker is not detected as being connected to the vehicle audio system, and

the signal processor uses a second set of processing parameters for processing the received audio signal when the first headrest speaker is connected to the vehicle audio system and the second headrest speaker is detected as being connected to the vehicle audio system.

2. The system of claim 1, wherein the processed audio signals provided to the amplifier for each of the first and second fixed speakers using the first set of processing parameters are different than the processed audio signals provided for the first and second fixed speakers using the second set of processing parameters.

3. The system of claim 1, wherein the processed audio signal provided to the amplifier for the first headrest speaker using the first set of processing parameters is different than the processed audio signal provided for the first headrest speaker using the second set of processing parameters.

4. The system of claim 1, wherein the processed audio signal provided to the amplifier for the first headrest speaker using the second set of processing parameters is different than the processed audio signal provided for the second headrest speaker using the second set of processing parameters.

5. The system of claim 1, wherein the signal processor remixes the audio signal from the source into an intermediate signal corresponding to a set of component directions, and

each of the first and second sets of processing parameters distributes a different portion of the intermediate signal corresponding to each of the component directions to the headrest speaker and the first and second fixed speakers.

6. The system of claim 1, wherein the system does not include a fixed speaker located behind the first headrest in a cabin of the vehicle.

7. The system of claim 1, wherein the processed audio signal provided to the amplifier minimizes leakage from the driver's seat to the passenger's seat.

8. The system of claim 1, wherein the first headrest speaker comprises at least two electro-acoustic transducers, at least one electro-acoustic transducer located at either end of the headrest.

9. The system of claim 8, wherein the processed audio signals provided to the amplifiers for the first headrest speaker control crosstalk of signals between each of the electroacoustic transducers and an ear of the listener positioned proximate a different one of the electroacoustic transducers.

10. The system of claim 8, wherein the first headrest speaker comprises a pair of arrays of electroacoustic transducers located at either end of the headrest.

11. The system of claim 1, wherein the first headrest speaker comprises an array of electroacoustic transducers located inside the headrest.

12. The system of claim 1 further comprising a bass unit auxiliary port configured to connect the audio system to a bass unit, wherein the signal processor uses a third set of processing parameters for processing the received audio signal when a bass unit is connected to the audio system.

13. The system of claim 12, wherein the processed audio signals provided to the amplifier for each of the first and second fixed speakers using the third set of processing parameters are different than the processed audio signals provided for the first and second fixed speakers using the first or second sets of processing parameters.

14. The system of claim 12, wherein the processed audio signal provided to the amplifier for the first headrest speaker using the third set of processing parameters is different than the processed audio signal provided for the first headrest speaker using either the first set of processing parameters or the second set of processing parameters.

15. The system of claim 1, further comprising:

a cable configured to connect the second headrest speaker to the source when the connector is received by the headrest auxiliary port; and is

Wherein the vehicle audio system is configured to detect whether the second headrest speaker is connected to the vehicle audio system by periodically polling the impedance on the cable.

Background

The present disclosure relates to modular headrest-based audio systems.

In some vehicle audio systems, processing is applied to the audio signals provided to each speaker based on the electrical and acoustic responses of the overall system, i.e., the response of the speaker itself and the response of the vehicle cabin to the sound produced by the speaker. Such systems are highly individualized to specific vehicle models and levels of decoration, taking into account the location of each speaker and the absorptive and reflective properties of the seat, glass, and other components of the automobile, among other things. Such systems are typically designed as part of the product development process for the motor vehicle, with the corresponding equalization and other audio system parameters loaded into the audio system at the time of manufacture or assembly.

Disclosure of Invention

A modular headrest-based audio system for a passenger vehicle includes a set of speakers secured in a vehicle cabin and a speaker located in only one of the vehicle's headrests. The first set of audio system parameters is used to adjust the audio signals provided to the various speakers, enabling an audio experience focused around a seat with speakers in its headrest. When an optional second headrest is installed and brings the speakers to the headrest of the second seat, the audio system parameters are changed, not only for the new headrest, but also for the fixed speakers and in some cases the first headrest, so that the added speakers are fully utilized. An optional bass box may also be added, again, changing the audio system parameters not only for the added components, but also for the fixed speakers, to provide overall system performance improvement.

In general, in one aspect, a vehicle audio system includes a signal processor configured to receive and process an audio signal from a source and provide the processed audio signal to an amplifier, a first headrest including a headrest speaker and coupled to a driver's seat, a first fixed speaker positioned proximate a left corner of a cabin of the vehicle forward of the headrest, a second fixed speaker positioned proximate a right corner of the cabin of the vehicle forward of the headrest, and a headrest accessory port located in a passenger's seat. The headrest auxiliary port is configured to connect the audio system to a second headrest speaker in a second headrest. The signal processor uses a first set of processing parameters for processing the received audio signal when the first headrest speaker is connected to the audio system and the second headrest speaker is not connected to the audio system, and the signal processor uses a second set of processing parameters for processing the received audio signal when both the first headrest speaker and the second headrest speaker are connected to the audio system.

Various embodiments may include one or more of the following in any combination. The processed audio signal provided to the amplifier for each of the first and second fixed speakers using the first set of processing parameters may be different from the processed audio signal provided for the first and second fixed speakers using the second set of processing parameters. The processed audio signal provided to the amplifier for the first headrest speaker using the first set of processing parameters may be different from the processed audio signal provided for the first headrest speaker using the second set of processing parameters. The processed audio signal provided to the amplifier for the first headrest speaker using the second set of processing parameters may be different from the processed audio signal provided for the second headrest speaker using the second set of processing parameters. The signal processor may remix the audio signal from the source into intermediate signals corresponding to the set of component directions, and each of the first and second sets of processing parameters may distribute different portions of the intermediate signals corresponding to each component direction to the headrest speakers and the first and second fixed speakers.

The system may not include a fixed speaker located rearward of the first headrest in a cabin of the vehicle. The processed audio signal provided to the amplifier may minimize leakage from the driver's seat to the passenger's seat. The first headrest speaker may include at least two electroacoustic transducers, at least one electroacoustic transducer located at one end of the headrest. The processed audio signals provided to the amplifier for the first headrest speaker may control crosstalk of signals between each of the electroacoustic transducers and an ear of a listener positioned to a different one of the electroacoustic transducers. The first headrest speaker may comprise a pair of arrays of electroacoustic transducers located at each end of the headrest. The first headrest speaker may include an array of electroacoustic transducers located within the headrest. The bass unit auxiliary port may be configured to connect the audio system to the bass unit, wherein the signal processor may use a third set of processing parameters for processing the received audio signal when the bass unit may be connected to the audio system. The processed audio signal provided to the amplifier for each of the first and second fixed speakers using the third set of processing parameters may be different from the processed audio signal provided for the first and second fixed speakers using the first or second set of processing parameters. The processed audio signal provided to the amplifier for the first headrest speaker using the third set of processing parameters may be different from the processed audio signal provided for the first headrest speaker using the first set of processing parameters or the second set of processing parameters.

Various advantages include providing a cost-effective solution for achieving a high quality audio experience in a small car, which expands to provide the same high quality sound to the passengers as experienced by the driver, if desired, and increasing the bass response of the system, if desired.

All examples and features mentioned above may be combined in any technically feasible manner. Other features and advantages will be apparent from the description, and from the claims.

Drawings

Fig. 1 shows a schematic diagram of a modular headrest-based audio system in a vehicle.

Fig. 2A to 2D show schematic diagrams of signal paths from a speaker to an ear of a listener.

Detailed Description

Conventional car audio systems are based on an approximate set of four or more speakers, two on the dashboard or in the front door, and two more typically located on the rear package shelf (in sedans and coupes) or in the rear door or wall (in vans and hatchbacks). However, as shown in fig. 1, in some cars (such as a small car) the speakers may be provided in the headrest rather than in a conventional location behind the driver. This saves space behind the car and does not waste energy that, if present, would not be available to provide sound to the rear seats for passengers. The audio system 100 shown in fig. 1 includes a combined source/processing/amplification unit 102. In some examples, different functions may be distributed among multiple components. In particular, the source is typically separate from the amplifier and the processing is provided by either the source or the amplifier, although the processing may also be provided by separate components. The processing may also be provided by software loaded onto a general purpose computer that provides the functionality of the source and/or amplifier. We refer to signal processing and amplification provided by the "system" rather than to any particular system architecture or technique.

The audio system shown in fig. 1 has two sets of speakers 104, 106 permanently attached to the vehicle structure. We refer to this as a "fixed" speaker. In the example of fig. 1, each set of fixed speakers includes two speakers, tweeters 108, 110 and low to mid-range speakers 112, 114. The two speakers in each set may be driven by a single amplified signal from an amplifier, with a passive crossover network (which may be embedded in one or both speakers) distributing the signal to the appropriate speaker at different frequency ranges. Alternatively, the amplifier may provide the band-limited signal directly to each speaker. In other examples full range speakers are used, and in yet another example more than two speakers per group are used. Each individual speaker shown may also be implemented as a speaker array, which may allow more complex shaping of sound, or simply more economical use of space and materials to deliver a given sound pressure level.

The driver's headrest 120 in fig. 1 includes two speakers 122, 124, which are shown schematically and may in fact each be an array of speakers. The loudspeakers, whether individual loudspeakers or arrays, may be co-operated as arrays themselves to control the distribution of sound to the ears of the listener. Two speakers may be placed at each end of the headrest, roughly corresponding to the desired spacing of the driver's ears, leaving space between them for the back cushion of the headrest, although the headrest is the primary function. In some examples, the speakers are placed closer together behind the headrest so that sound transmitted to the front of the headrest passes through the housing surrounding the back pad. The speakers may be oriented in various ways with respect to each other and with respect to the headrest components, depending on the mechanical requirements of the headrest and the acoustic objectives of the system. Co-pending application 13/799,703, incorporated herein by reference, describes a number of designs for enclosing speakers in a headrest without compromising the safety features of the headrest. The speakers of the headrest are shown in fig. 1 as being connected to the source 102 through the seat by cables 130, although they could also communicate wirelessly with the source 102 with the cables providing only power. In some examples, the speakers 122 and 124 may be placed in other locations than directly in the headrest, such as in the seat back, particularly in a seat where the headrest is an integral part of the seat back, or in a canopy or roll bar.

The car audio system may be designed, in part, to optimize the driver's experience and not provide speakers in the passenger headrests. A passenger headrest 126 with additional speakers 128 and 130 and a rear mounted bass box 132 may be offered as an option to buyers who do want to provide sound to the passenger or sacrifice significant storage space. When such optional speakers are installed, the tuning of the overall audio system is adjusted to take full advantage of the added speakers.

The cable 134 may be present in the passenger seat to simplify the task of adding the optional second headrest 126 to the seat after the vehicle is manufactured, or it may be added by the dealer at the time of purchase of the second headrest as desired. If the headrest 126 is wireless, the cable 134 may only provide power to the headrest and may already be present in the seat for other powered functions, such as positioning the motor and heater. Optional bass enclosure 132 is positioned in the trunk area of the vehicle and is connected to source 102 by cable 136, again cable 136 may be original equipment or may be dealer-installed. In some examples, the bass box 132 has a built-in amplifier 138 so that the source 102 only needs to provide an equalized but not amplified audio signal to the bass box.

A large set of adjustable parameters affects the performance of an audio system, and we refer to a set of such parameters (configured to provide a desired experience in a given audio system) as "tuning". Tuning may include values of such parameters used as gains applied to each audio signal, phase adjustments to different audio signals that control the phase alignment of sound produced by different speakers, filters applied to shape sound, and so forth. In particular, for systems comprising headrest speakers, complex filters may be used to control the binaural perception of sound at the head and avoid controlling crosstalk between signals reaching each listener's ears and between their seats.

In some examples, the audio source provides only two channels, namely left stereo audio and right stereo audio. Two other common options are four channels, i.e. left and right for front and back, and five channels for surround sound sources. Four channels are typically found when using a standard vehicle head unit, in which case the two front and two rear channels will typically have the same content, but may be at different levels due to the "fader" setting in the head unit. In order to mix sound properly for the system described herein, two or more channels of audio are upmixed into an intermediate number of components corresponding to different directions from which the sound appears to come, and then remixed into output channels intended for each particular speaker in the system. One example of such upmixing and remixing is described in U.S. patent 7,630,500, incorporated herein by reference. We use "component" to indicate each of the intermediate directional assignments to which the original source material was upmixed. A portion of each component is mixed into each output channel (although this portion may be near zero for some component-output channel combinations). For example, the audio signal for the "right front" component would be mostly distributed to the right fixed speaker, so that some portion thereof is also distributed to the right headrest speaker. The audio signal for the "center front" component will be evenly distributed to the right and left fixed speakers such that some portion thereof is distributed to the right and left headrest speakers, which helps focus the listener's perception of the location where the center component originates. The particular distribution of component content to the output channels will vary based on how many and which headrest speakers are installed. An example of this mixing and subsequent signal processing is described in co-pending application 13/888,927, incorporated herein by reference.

One aspect of the audio experience that is controlled through tuning of the car is the sound field. "sound field" refers to the listener's perception of where sound originates. In particular, it is often desirable for the sound field to be wide (sound coming from both sides of the listener), deep (sound coming from near and far), and accurate (the listener can identify where a particular sound appears to come from). In an ideal system, someone listening to recorded music can close their eyes, imagine that they are in a live performance, and indicate the location of each musician. The related concept is "surround", by which we mean the perception that a sound comes from all directions (including from the rear of the listener), regardless of whether the sound can be accurately localized. The perception of the sound field and surround (and generally sound location) is based on the level and time of arrival (phase) differences between the sounds arriving at the two ears of the listener, and the sound field can control these interaural level and time differences by manipulating the audio signals produced by the loudspeakers. As described in U.S. patent No. 8,325,936, which is incorporated herein by reference, not only headrest-based speakers, but fixed speakers may also be used in concert to control spatial perception.

If the headrest based system is used alone, the sound will be perceived as coming from behind the listener, since that is actually the position of the speakers. However, when properly combined with speakers in front of the driver (such as in a traditional fixed position on the dashboard or in the door), the speakers in the headrest can be used to improve the field of sound from the front speakers. That is, rather than simply replacing the rear seat speakers to provide "rear" sound, headrests are used to focus and control the listener's perception of sound from the front of the car. This may provide a wider or deeper and more controlled sound field than a separate front speaker may provide.

Tuning provides a specific adjustment of the signal to each speaker in order to use the headrest speakers to enhance the sound field of the front fixed speakers. The tuning of both the fixed speakers 104, 106 and the headrest speakers 122, 124, 128, 130 will be different for a system using one headrest than for a system using two headrests. The single headrest system will also be different from an otherwise identical system except that the one headrest is on the other side of the car (at a minimum, the parameters for the left and right signals will be reversed). Fig. 2A to 2D are used to illustrate these adjustments — they show the heads of two listeners as they would like to be positioned relative to the speakers in fig. 1. The driver 202 has a left ear 204 and a right ear 206, and the ears of the passenger 208 are labeled 210 and 212. The dashed arrows show the various paths taken by sound from the speaker to the ear of the listener, as described below. Fig. 2A shows all paths simultaneously, while fig. 2B to 2D show a subset of paths relating to various specific aspects of system tuning. We refer to these arrows as "signals" or "paths", although in actual practice, we do not assume that the speaker can control the direction of sound radiation, although this is possible. The signals assigned to each speaker are superimposed to produce the final output signal, and all energy from each speaker may travel omnidirectionally. The arrows only conceptually show different combinations of speakers and ears for ease of reference. If an array or other directional speaker technology is used, the signals may be provided to different combinations of speakers to provide some directional control.

Fig. 2B shows the distribution of sound only when the headrest of the driver is mounted. The signals 220, 222, 224 and 226 from each fixed speaker arrive at both ears of the driver. For each individual fixed speaker, a slight delay in the arrival of the signal at the opposite ear (222 and 224) relative to the arrival of the same signal at the close ear (220 and 226) will cause the driver to localize the sound to the correct side. The phase of the signal sent to the fixed speaker is modified to ensure that the arrival of the signal from the right fixed speaker 106 at the right ear occurs at the same time as the arrival of the corresponding signal from the left fixed speaker 104 at the left ear. Thus, signals with the same content from both sides will be perceived simultaneously at both ears and as coming from the middle.

The signal from the intermediate component is also sent to the headrest speakers. Each of the headrest speakers is now assumed to be heard only by the corresponding ears 228 and 230. By providing signals at both ears with a controlled amount of time before or after the signal from the fixed speakers (i.e., by manipulating the phase), the headrest speakers can be used to control whether the driver perceives the mid-component sound as being very focused in front of the driver or very diffuse around the driver.

Signals corresponding to each of the right and left components of the upmixed audio signal are also sent to both the fixed speakers and the headrest speakers. As is clear from the figure, the left stationary speaker is significantly closer to the driver than the right stationary speaker, as in any vehicle with side-by-side seating. Without the headrest speakers, this can result in a sound field that feels very unbalanced — sound from the right is far to the right, and sound from the left is near to touch. This may be improved by providing portions of the left and right components differently at the left and right headrest speakers. The left headrest speaker 122 is used to pull the sound image further back from the left fixed speaker 104, which will be perceived as being farther to the left, outside the actual boundaries of the car, while the right headrest speaker 124 is used to pull the sound image inward from the right fixed speaker 106.

When the passenger's headrest 126 is added, as shown in fig. 2C, the same problem exists for the passenger seat, but is reversed left to right. The left fixed speaker 104 is listened to at the left ears 220 and 232 of the two listeners, and the right fixed speaker 106 is listened to at the right ears 226 and 234 of the two listeners. The opposite ear paths from the fixed speakers are not shown because they can be ignored as described above. The processing applied to the right component signal to the right speaker on the driver's headrest (for path 230) is now applied to the left component signal to the left speaker on the passenger's headrest (236), and vice versa (i.e., the left component processing for path 228 is applied to the right component processing for path 238). Thus, the processing is reversed, with the component signals going to the same side in both headrests.

In contrast to the headrest signal, the phase adjustment made to the signal to the right fixed speaker 106 to balance the sound field at the driver is unlikely to be perceived by the passenger in the same way. Since now it is assumed that there are two listeners, the phase of the signals to the fixed loudspeakers will be adjusted to provide the best balance obtainable at the two seats. This may compensate for single seat performance, for example, by making the central sound image less accurate, but when two locations are considered, it improves the perception of the overall sound system.

Another aspect where tuning will vary between different configurations is crosstalk cancellation, as shown in fig. 2D. Crosstalk cancellation is used to prevent a sound intended for one ear from reaching the other ear, which is accomplished by providing a sound signal at a second ear that is matched but out of phase with the intended one, resulting in destructive interference (i.e., cancellation) with the unwanted signal. Within one headrest, crosstalk cancellation is provided between the left and right speakers. Two speakers in the headrest are used as an array, this is done by providing a signal from the right speaker 124 that is of the same content as the signal from the left speaker 122, but will be out of phase with the signal at the driver's right ear. Thus, the signal 230 is used not only to deliver the right component content to the right ear, but also to cancel the left component content 240 at the right ear 206 from the left headrest speaker 122. Likewise, the signal 228 is used to cancel the right side component content 242 from the right headrest speaker 124 at the left ear 204.

When the second headrest 126 is present, the right speaker 124 of the driver's headrest is proximate to the left ear of the passenger. This may result in the signal 248 from the right speaker (for each content or for crosstalk cancellation from the left speaker 122) being audible at the passenger's left ear 210, which would be undesirable. Likewise, the signal 250 from the passenger's left speaker 128 may be audible at the driver's right ear 206. To avoid this, the level of direct signal and crosstalk cancellation provided by the inboard speakers (the driver's right speaker 124 and the passenger's left speaker 128) may be reduced. This compromises the quality of sound field control and crosstalk cancellation that the headrest can provide, but avoids undesirable leakage of signals through the seat.

Some additional processing is also possible if the system has the capability. As just mentioned, there is a signal leaking from each headrest to the opposite seat position. Instead of reducing the output of the inboard speakers to avoid this leakage, the speakers of each headrest may be used in combination to cancel their own sound in the direction opposite the head, i.e., speakers 122 and 124 are used to cancel path 248 and speakers 128 and 130 are used to cancel path 250. One approach to making such control more feasible is to use an array of transducers for each of the headrest speaker positions.

In some examples, the audio system is preconfigured with at least two tuners for one headrest and for two headrests. The system may also be configured with left and right single headrest tuning. When only one headrest is installed, the proper tuning of a single headrest is used. When a second headrest is added, the system makes changes to both headrest tunes. This change may be made automatically in the case where the audio system is pre-wired for both headrests and is therefore able to detect the installation of the second headrest, or may be made in accordance with instructions issued by a technician or user installing the second headrest. Detecting the presence of the headrest may be done using additional pins added to the connector (as opposed to what would be done for a device that is always present), by periodically polling the impedance on the wires to check whether a speaker has been attached, or by a wireless transceiver that is also used to provide a signal to the headrest.

The tuning of the fixed front speakers will also depend on whether an optional bass module is installed. In addition to rebalancing the distribution of low frequency content from the front speakers to the bass box, when possible, the overall level and phase of all signals provided to the front speakers will be changed to control the perceived balance of the system across the entire audible spectrum. For example, when a higher low frequency level is available due to the presence of a low box, mid and high frequency sounds may also be played louder than they would have been played if only the current speaker was used to provide low frequency sounds. This is because increasing the level of bass while keeping other frequencies the same will actually result in higher frequencies sounding quieter, and conversely, when the high level of bass is not present, mid and high frequency sounds may have been suppressed to avoid the system sounding sharp or bright. In some examples, the phase alignment of all speakers in the system is determined when the bass box is installed, and the phase alignment is used in both modes — with or without the bass box. It is the level and component mix of the sound to the output channels that is altered based on the presence or absence of the bass boxes.

Just like the second headrest, the audio system may be preconfigured with two tunes (multiplied by several headrest tuning sets) for use with and without a bass box, and the appropriate tune is loaded in the same way. In the case of an optional bass box, even more so in the case of an optional headrest, it is possible that the customer may choose to remove and then reinstall the bass box at any time, such as to give more available space when carrying full load luggage. For this reason, it is advantageous that the system automatically detects the presence or absence of a bass box and automatically loads the appropriate tuning.

The embodiments of the systems and methods described above may include computer components and computer-implemented steps, which will be apparent to those skilled in the art. For example, it should be understood by those skilled in the art that the computer implemented steps may be stored as computer executable instructions on a computer readable medium, such as, for example, a floppy disk, a hard disk, an optical disk, a flash ROM, a non-volatile ROM, and a RAM. Further, it should be understood by those skilled in the art that computer executable instructions may be executed on various processors, such as, for example, microprocessors, digital signal processors, gate arrays, and the like. For ease of illustration, not every step or element of the above-described systems and methods is described herein as part of a computer system, but those skilled in the art will recognize that each step or element may have a corresponding computer system or software component. Accordingly, such computer systems and/or software components are enabled by describing their corresponding steps or elements (i.e., their functionality) and are within the scope of the present disclosure.

Several embodiments have been described. However, it will be understood that additional modifications may be made without departing from the scope of the inventive concept described herein, and accordingly, other embodiments are within the scope of the following claims.