Patent Application
20100027807
The present disclosure relates to audio players, and more particularly to an audio reproduction apparatus for adjusting the volume of an audio players.
The present disclosure may best be understood by reference to the following detailed description when considered in connection with the accompanying drawings.
Recently, portable audio systems, such as CD, MP3, MD, and media players, have become popular, especially due to the advent of technologies that made such systems smaller and more powerful at the same time. These portable audio systems typically play, for example, music via audio output devices such as earphones, headphones and the like. Such output devices provide a convenient means for enjoying music without disturbing others in proximity.
While the popularity of portable audio systems has soared recently, many users have also become accustomed to listening to loud music for a long period of time with headphones or earphones. Listening to loud music at a high volume for a prolonged period of time, however, may lead to temporary, or even permanent, hearing loss or damage.
In a noisy environment, listeners tend to set the volume level higher to block out ambient noise. For example, in excessively noisy environments such as subway stations, airplanes and crowded areas, users typically set the audio output volume to a sufficiently high level to overcome the background noise. Since the loudness level of sound perceived by a listener is related to the ambient noise level and the sound pressure level (SPL) of sound output devices, listening to music at a high volume setting with loud ambient noise may ultimately lead to hearing damage or loss.
To overcome the ambient noise problem, noise canceling headphones have been developed to reduce background noise to some degree. While such headphones reduce the ambient noise somewhat, they typically do not allow automatic adjustment of the volume level set by the user to reduce the risk of hearing damage or loss. In addition, these headphones tend to be bulky, inconvenient and expensive, and thus, inappropriate as portable audio devices.
As a further solution to the above problems, manufacturers of portable audio players have developed safety circuitry which warn the user or limit the output volume when the volume reaches a dangerously high level. Such safety circuitry limits the output volume by limiting the output electric power of the audio player within an acceptable level to allow the user to listen to music without serious damage to hearing. Such a solution, however, may not be preferred by consumers who would rather control the volume level themselves. Further, simply limiting the output electric power of the audio player may not be effective for different headphones with varying sensitivity (defined as the sound pressure level produced at a specific power input). Indeed, since hearing loss is related to the output sound pressure level provided and the exposure period, limiting the output electric power of the audio player may not directly correlate with preventing hearing damage or loss.
The present disclosure is directed to an audio player capable of adjusting an audio volume outputted through an audio output device based on a sound pressure level of the audio output device. The audio player monitors the sound pressure level of the audio output device by monitoring the output level of the audio signal provided to the audio output device in combination with the sensitivity value of the audio output device. The audio player controls the audio volume (i.e., sound pressure level produced by the audio output device) based on the monitored sound pressure level.
In one embodiment, an audio player includes a volume adjustment unit, an output adapter, and a volume limiting unit. The volume adjustment unit is configured to control an output level of an output audio signal. The output adapter is configured to provide the output audio signal to an audio output device. The volume limiting unit is configured to limit an audio volume produced at the audio output device by adjusting the volume adjustment unit.
In another embodiment, an audio player includes a volume adjustment unit and an output adapter. The volume adjustment unit is configured to control an output level of an output audio signal. The output adapter is configured to provide the output audio signal to an audio output device. The audio player is configured to limit an audio volume produced at the audio output device by monitoring a sound pressure level of the audio output device.
In yet another embodiment, an audio output device for a media player includes an input adapter, a speaker, and a volume control unit. The input adapter is configured to receive an audio signal. The speaker is configured to covert the audio signal into sound. The volume control unit is configured to monitor the audio signal and to control an output level of the audio signal provided to the speaker.
In a further embodiment, a method for controlling an output volume of a media player comprises: (i) determining an output level of an audio signal provided to an audio output device; (ii) monitoring a sound pressure level produced by the audio output device driven by the media player based upon the output level; and (iii) controlling the output level of the audio signal in response to monitoring the sound pressure level.
In still another embodiment, a computer-readable medium stores instructions that when executed by a media player cause the media player to perform a method for controlling an output volume of the media player. The method comprises: (i) monitoring a sound pressure level produced by an audio output device coupled to the media player in response to an output audio signal generated by media player; and (ii) controlling an output level for the output audio signal in response to monitoring the sound pressure level.
In the following description, numerous specific details are set forth. It will be apparent, however, that these embodiments may be practiced without some or all of these specific details. In other instances, well known process steps have not been described in detail in order not to unnecessarily obscure the present disclosure.
The media files from the storage device 130 are provided to the audio processing unit 120, which is a processor configured to process and play the media files. In playing the media files, the audio portion of the files is processed to generate audio signals. Specifically, the audio processing unit 120 generates audio signals from the media files and transmits the audio signals to the volume control device 140. The volume control device 140 controls the output level (i.e., power) of the audio signals based on volume levels configurable by user input and also functions to limit the volume of the audio output device based on information on the audio output device connected to the audio player 100. The audio signals are then provided to an audio output device, such as a speaker, an earphone, a headphone, and the like, which converts the signals to sound.
For amplifying the input audio signals, the amplifier 204 has a constant amplifying coefficient (e.g., gain) indicating a ratio between the electric power of a signal input to the amplifier 204 and the electric power of the signal amplified by the amplifier 204.
According to the amplifying coefficient, the amplifier 204 receives and amplifies the left and the right channel signals 214 and 216 from the volume adjustment unit 202 to a level audible to human ears. The amplified left and right channel signals are then provided to the audio output device connector 208 in the form of a socket, which provides an interface to an audio output device equipped with a jack plug that can be inserted into the audio output device connector 208. In addition, the amplifier 204 provides the amplified signals to the volume limiting unit 206 for determining the output electrical power provided to the audio output device via the audio output device connector 208.
The audio output device connector 208 is configured to include one or more conductors, such as lines, contact portions, and the like, for providing electrical contact with corresponding conductors in the jack plug of the audio output device. In contrast to conventional audio output device connectors, which typically have three conductors (two conductors for the left and right channel signals, and a ground conductor), the audio output device connector 208 is configured with four conductors: two conductors 222 and 224 for the left and right channel signals 214 and 216 respectively, a ground conductor 226, and an additional conductor 220. The additional conductor 220 in the audio output device connector is configured to provide electrical data signal 218 indicating one or more electrical characteristics (e.g., sensitivity and/or impedance data) of the audio output device to the volume limiting unit 206. The electrical characteristics data may include, for example, either or both sensitivity and impedance of the audio output device in contact with the conductor 220.
Based on the received electrical data signal and output electric power delivered to the audio output device, the volume limiting unit 206 determines and monitors the sound pressure level of the audio output device. In the case of sensitivity data, the sensitivity of a headphone is defined as the sound pressure level produced at a specific input electric power and may be represented as the number of dB of actual sound pressure level produced by the headphone with 1 mW of input electric power. Thus, the sensitivity of headphones can be determined by applying 1 mW to the headphones and measuring the sound pressure level generated at the earpiece using a dummy head with built-in microphones. Audio output device manufacturers typically specify sensitivity ratings for their products, usually in a manual packaged with the products. In accordance with one embodiment, the sensitivity is recorded or stored in the audio output device at the manufacturing stage and is detected by the audio player 100 when the jack plug of the audio output device is inserted to contact the conductor 220 in the audio output device connector 208 of the audio player 100.
With reference to
In the case where the electrical data is an impedance value of an audio output device, the volume limiting unit 206 may determine the output electric power by using the voltage and the impedance value of the audio output device without knowing the current value. The impedance value can be obtained by various methods, for example by including the impedance value in the electrical data from the audio output device or by manually inputting the impedance value through an input device (not shown) of the audio player 100. In one embodiment, the amplifier 204 typically includes a non-zero, but known impedance so that the output electric power can be determined by using the impedance value of the audio output device taking into account the amplifier's known impedance.
Once the output electric power delivered to the audio output device has been determined, the volume limiting unit 206 determines the sound pressure level of the audio output device from the electrical data and the output electric power. For example, the sound pressure level may be estimated based upon the output electric power and the sensitivity with minor unit change between a dB scale and a normal scale. In one embodiment, since the sound pressure level is proportional to the current through a voice coil of the audio output device and the current is related with the output electric power in root square, the sound pressure level is calculated based upon the root square value of the output electric power.
The volume limiting unit 206 continuously monitors the sound pressure level of the audio output device during operation and limits the sound pressure level based on estimates of the degree of hearing loss or damage that may result from the monitored sound pressure level of the audio output device over a period of time. To model the degree of hearing loss, the volume limiting unit 206 monitors the time period the user is exposed to the sound pressure level, since hearing loss or damage can be caused by a one-time exposure to loud sound as well as by continuous exposure to sounds at various sound levels over an extended period of time. Thus, the volume limiting unit 206 integrates (e.g., averages) the sound pressure level for various time periods and monitors whether the integrated sound pressure level during each of the time periods, i.e., the time average value of the sound pressure level, is more than or equal to a threshold sound pressure level for each time period. When the integrated sound pressure level for a time period exceeds a specified level, the volume limiting unit 206 generates and provides the control signal 210 to the volume adjustment unit 202 to control or limit the volume of the audio output device by adjusting the output electric power delivered to the audio output device. The volume limiting unit 206 may also generate a warning signal 212 to alert a user by generating an audible warning or displaying a warning message on a displaying unit (not shown) of the audio player 100 so that the user may limit the volume manually. In one embodiment, Table 1 provides some examples of integrated sound pressure levels and exposure time periods that trigger the volume limiting unit 206 to generate the control signal and/or warning signal 212.
As can be seen in Table 1 above, for every 3 dB over 85 dB of the SPL, the allowable exposure time, which does not generate a hearing loss index indicating a danger of deafness, is cut in half. The volume limiting unit 206 generates a control signal 210 based upon the hearing loss index and sends the control signal 210 to the volume adjustment unit 202 to control or limit the output level of the audio signal by adjusting the output electric power delivered to the audio output device. The volume limiting unit 206 may also generate a warning signal 212 to alert a user by generating an audible warning or displaying a warning message on a displaying unit (not shown) of the audio player 100 so that the user may limit the volume manually. For example, the volume limiting unit 206 may transmit a control signal 210 to the volume adjustment unit 202 or generate the warning signal 212, when the integrated SPL in the left column of Table 1 has maintained for more than or equal to the exposed time period in the right column of Table 1. In this manner, prolonged exposure of the user to loud sound can be prevented. The volume limiting unit 206 may be implemented in a form of hardware and software and a combination thereof.
Between the extra conductor 308 and the ground conductor 310 of the audio output device 300, a resistor 320 is provided with a predetermined resistance value R, which corresponds to the sensitivity of the audio output device 300. In accordance with one embodiment, the sensitivity of the audio output device 300 is preferably measured during the product manufacturing stage, since each of the products, i.e., the audio output device 300 may possibly have unique sensitivity value which can be different for every product. The resistance value may be recorded in the audio output device 300 by connecting the resistor 320 having a resistance value corresponding to the sensitivity between the conductors 308 and 310. The resistor 320 can be installed in a circuit of the audio output device 300 at the final assembly stage of the manufacturing process of the audio output device 300.
The volume limiting unit 206 reads the resistance value R of the audio output device 300 to receive the sensitivity of the audio output device 300. In order to read the resistance value R of the resistor 320, for example, the audio player 100 may measure a voltage of a line 318 contacting the conductor 308 and a current flowing along a circuit line connected to the line 318 coupled to the conductor 308. In this manner, the volume limiting unit 206 obtains the sensitivity of the audio output device 300 to estimate the sound pressure level of the audio output device 300.
The audio output device 300 in accordance with the present disclosure covers various types of devices named as headphones, earphones, earbuds, stereophones, canalphones, or headsets, but without limitation thereto. The audio output device 300 includes any pair of transducers that receive an audio signal from a media player placed in close proximity to the ears to convert the audio signal into audible sound waves, without limitation to specific types of audio output devices.
The audio player 100 in one embodiment may also be used with an audio output device with a conventional three-conductor jack plug. In this case, the resistance value R of such audio output device is nearly zero since there is no extra conductor and the audio player 100 may use a default sensitivity value as the sensitivity of the audio output device. For use with a conventional audio output device that does not have the extra conductor, an adapter having an extra conductor may be inserted between the audio player and the audio output device. The user can select an adapter which corresponds to the sensitivity of the audio output device. The manufacturers of the audio output device 300 may sell such an adapter as an accessory to the audio output device 300.
For use with a conventional three-conductor audio output device, the audio output socket 412 includes three output conductors or lines 414, 416 and 418 that can be connected to the jack plug of the conventional three-conductor audio output device. The output conductors or lines 414 and 416 deliver the left and the right channel signals to the conventional audio output device while the output conductor or line 418 provides a ground connection to the conventional audio output device. In this manner, the conventional three-conductor audio output device can be connected to the audio player 100 in
Then, in operation 520, the audio player 100 receives sensitivity value of the audio output device, for example, by reading a resistor placed in the audio output device, which may be connected to the audio player 100 directly. Alternatively, a three-conductor audio output device may be connected to the audio player 100 via the adapter 400 having a resistor indicating the sensitivity of the audio output device connected to the adapter 400. In operation 530, the audio player 100 determines the sound pressure level (SPL) of the audio output device by using the output electric power and the sensitivity obtained in operations 510 and 520.
In operation 540, while monitoring the sound pressure level provided to the audio output device via audio output connector, the audio player 100 integrates the sound pressure level for a predetermined time period. If the audio player 100 determines that the sound pressure level is not higher than a predetermined threshold value in operation 550, it proceeds back to operation 540 to continue integrating the sound pressure level. If, however, the audio player 100 determines that the sound pressure level is higher than the predetermined threshold value in operation 550, it provides the control signal 210 to the volume adjustment unit 202 to limit the electric output power. In this operation, the volume adjustment unit 202 reduces the electric output power provided to the amplifier. Optionally, the audio player 100 may also display or issue a warning sign to alert the user that the volume should be lowered.
Although the audio player 100 receives the sensitivity value from audio output devices, the audio player 100 may receive the sensitivity value of audio output devices manually from the user or automatically via a computer.
In an alternate embodiment, the interface unit 632 provides a connection to an external device, such as a personal computer, to receive the electrical data of the audio output device from the external device. The interface unit 632 may also include a communication module for a short range communication, such as Bluetooth, Zigbee, the infrared or RF communication as well as a cable connection such as a universal serial bus (USB). The user may input the electrical data 618 of the audio output device by using an input device of the computer (e.g., a keyboard) and download the information into the memory 628 such that the audio player 600 may use the information in determining the sound pressure level of the audio output device. For receiving the electrical data, the external computer and the audio player 600 may execute an application program, which may be provided by the manufacturer of the audio output device.
In another embodiment, the electrical data 618 may be inputted from a manufacturer's server via a remote connection. For example, the user of the audio player 600 may log on to an Internet website provided by the manufacturer and click on a menu to download the electrical specification information, such as sensitivity, impedance, and the like of an audio output device onto the audio player 600 via the interface unit 632. The downloaded electrical specification data is then stored in the memory 628, such as DRAM, flash memory, and the like. The volume limiting unit 206 reads the stored electrical data 618 to estimate the sound pressure level as described above.
The wireless communication module 634 allows the audio player 600 to communicate with a mobile communication network, such as GSM, CDMA, and the like. For example, a cellular phone having a functionality of MP3 player can be equipped with such a module. In this case, the electrical data 618 is directly downloaded into the memory 628 without necessarily being connected to the external computer via the interface unit 632. For example, the audio player 600 receives a configuration file including all the electrical data of one or more audio output devices from the server of the manufacturer through the mobile communication network by using the wireless communication module 634. The configuration file can be downloaded by the operation of the user in advance or at the time of inserting a specific type of audio output device into the audio player. The user may select to download a specific configuration file of one audio output device or all the audio output devices provided by the manufacturer. The downloaded configuration file is stored into the memory 628 and read by the volume limiting unit 206 to calculate the sound pressure level of the corresponding audio output device. The configuration file includes various types of electrical data, such as sensitivity, impedance, and the like.
Alternatively, the configuration file can be downloaded in a plug-and-play way by detecting the type of the audio output device inserted into the audio output connector 208 when the audio output device is connected to the audio player. To identify the audio output device, the audio output device provides identifying information to the audio player 600 to allow the audio player to detect the type of the audio output device. For example, the resistor 320 in the audio output device 100 in
If the configuration file corresponding to the inserted audio output device is not stored in the memory 628, the user may trigger the audio player 600 to start the process of downloading the configuration file by using the wireless communication unit 634. The audio player 600 may also initiate the downloading process without triggering or inputting activity from the user in such a way that the audio player 600 transmits a request message to the server of the manufacturer via the mobile communication network. After the audio player 600 receives the configuration file, it starts to perform the volume control process as described above.
In one embodiment, the audio output device may include an IC chip (e.g., IC memory chip) for providing the electrical data.
In another embodiment, the audio player 100 and the audio output device 702 may include a wireless communication capability by employing a digital interface protocol, such as universal serial bus (USB) link, or wireless interface connection, such as BloothTooth, ZigBee, HDMI (high definition multimedia interface), HDCP (high-bandwidth digital contents projection), and the like. In this case, the audio player 100 may communicate with the audio output device 702 via a wireless connection to obtain the electrical data of the audio output device 702. For example, in case of a USB headphone having a digital to analog converter (DAC), the audio player 100 may receive sensitivity data from the audio output device 702 while transmitting the audio data to be played by the audio output device 702.
In another embodiment, an audio output device may itself include a volume limiting unit to adjust the sound pressure level of the audio output device.
The audio output device 802 includes a volume limiting unit 806 coupled between the jack plug 804 and the speakers 808 for adjusting a sound pressure level to be heard by human ears within a predetermined range. The volume limiting unit 806 performs similar functions to the volume limiting unit 206 described with reference to
| Number | Date | Country | Kind |
|---|---|---|---|
| 10-2006-0105650 | Oct 2006 | KR | national |
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/KR2007/004899 | 10/8/2007 | WO | 00 | 9/15/2009 |
