Patent Application
20090154720
This application is based upon and claims the benefit of priority from Japanese Patent Application No. 2007-326237, filed Dec. 18, 2007, the entire contents of which are incorporated herein by reference.
1. Field
One embodiment of the invention relates to a sound output control device which outputs audio signals to a first headphone and a second headphone, a sound playback apparatus and a sound output control method.
2. Description of the Related Art
In recent years, various kinds of portable playback apparatuses, such as media players and music players, have been developed. In usual cases, a pair of headphones are used to receive and listen to audio signals of, e.g. music, which are played back by the portable playback apparatus. The pair of headphones include a headphone for a left channel and a headphone for a right channel. A user wears the two headphones on the left ear and right ear, thus being able to listen to sound corresponding to a stereo audio signal.
Jpn. Pat. Appln. KOKAI Publication No. 2006-304052 discloses an audio signal control method which boosts a low-frequency component of an audio signal when it is detected that an ear pad portion of a headphone is displaced from the user's ear.
In addition, Jpn. Pat. Appln. KOKAI Publication No. 2007-81633 discloses a bone-conduction speaker apparatus. In order to prevent sound leak from a bone-conduction speaker, this bone-conduction speaker apparatus has a function of determining whether the bone-conduction speaker is in contact with the human body, and stopping power supply to the bone-conduction speaker when the bone-conduction speaker is out of contact with the human body.
In the meantime, in general, a stereo audio signal is composed on the presupposition that the stereo audio signal is listened to by both ears of the user, and the stereo audio signal includes a left-channel audio signal for the left ear and a right-channel audio signal for the right ear. In usual cases, the left-channel audio signal includes an audio signal component which is not included in the right-channel audio signal, and the right-channel audio signal includes an audio signal component which is not included in the left-channel audio signal. If only one of the left-channel audio signal and right-channel audio signal is listened to by one of the user's ears, the user would hear unnatural sound.
Therefore, it is necessary to realize a novel function which can output sound, which is free of unnaturalness to a user, no matter whether the user listens to an audio signal by both ears or by one of the ears.
A general architecture that implements the various feature of the invention will now be described with reference to the drawings. The drawings and the associated descriptions are provided to illustrate embodiments of the invention and not to limit the scope of the invention.
Various embodiments according to the invention will be described hereinafter with reference to the accompanying drawings. In general, according to one embodiment of the invention, there is provided a sound output control device comprising: an output control module configured to detect, based on a first wearing detection signal which is sent from a first headphone and a second wearing detection signal which is sent from a second headphone, whether a wearing state of the first headphone and the second headphone is a first state in which both the first headphone and the second headphone are worn on the human body, or a second state in which one of the first headphone and the second headphone is worn on the human body and the other of the first headphone and the second headphone is not worn on the human body, to send, in a case of the first state, a left-channel audio signal and a right-channel audio signal, which are included in a stereo audio signal which is output from a playback unit, to the first headphone and the second headphone, respectively, and to generate, in a case of the second state, a monaural audio signal by mixing the left-channel audio signal and the right-channel audio signal to send the generated monaural audio signal to the one of the first headphone and the second headphone.
To begin with, referring to
The playback module 102 outputs a stereo audio signal. The stereo audio signal includes a left-channel audio signal CLin and a right-channel audio signal CRin. The stereo audio signal is, for instance, (1) an audio signal which is output from a microphone, (2) an audio signal which is played back from a recording medium such as a magnetic tape, an optical disc or a memory, or (3) an audio signal which is output from a television or a radio. For example, the playback module 102 can be realized as a player apparatus which plays back audio data that is stored in a recording medium. Audio data which is stored in the recording medium is, for instance, a stereo audio source which is recorded in stereo. In this case, the playback module 102 plays back the audio data, thereby outputting a stereo audio signal (left-channel audio signal CLin and right-channel audio signal CRin) corresponding to the audio data. The stereo audio signal (left-channel audio signal CLin and right-channel audio signal CRin) is supplied to the sound output control module 101.
The headphone EL is, for example, a first headphone (also called “earphone”) which outputs sound corresponding to the left-channel audio signal, and is worn on the left ear in use. The headphone ER is, for example, a second headphone (also called “earphone”) which outputs sound corresponding to the right-channel audio signal, and is worn on the right ear in use. The headphones EL and ER are used in order to output sound corresponding to the stereo audio signal.
The sound output control module 101 functions as a sound output control device which outputs audio signals to the first headphone EL and the second headphone ER. The sound output control module 101 has two operation modes, namely, a stereo output mode and a monaural output mode.
The switching of the operation mode between the stereo output mode and a monaural output mode is executed on the basis of a first wearing detection signal KL which is sent from the first headphone EL, and a second wearing detection signal KR which is sent from the second headphone ER. The first wearing detection signal KL is a signal which is indicative of whether or not the first headphone EL is worn on the human body. The second wearing detection signal KR is a signal which is indicative of whether or not the second headphone ER is worn on the human body.
On the basis of the first wearing detection signal KL and second wearing detection signal KR, the sound output control module 101 determines whether the wearing state of the headphones EL and ER is a first state (both-ear wearing state) in which both the headphones EL and ER are worn on the human body, or a second state (one-ear wearing state) in which one of the headphones EL and ER is worn on the human body and the other of the headphones EL and ER is not worn on the human body.
If the both-ear wearing state is determined, the sound output control module 101 selects the stereo output mode and operates in the stereo output mode. On the other hand, if the one-ear wearing state is determined, the sound output control module 101 selects the monaural output mode and operates in the monaural output mode.
The stereo output mode is a mode for outputting sound corresponding to the stereo audio signal. In the stereo output mode, the sound output control module 101 sends the left-channel audio signal and right-channel audio signal, which are included in the stereo audio signal that is output from the playback module 102, to the headphones EL and ER. Specifically, the sound output control module 101 sends the left-channel audio signal CLin, which is input from the playback module 102, to the first headphone EL as a left-channel audio output signal CLout. For example, the left-channel audio output signal CLout is a signal which is equal to the left-channel audio signal CLin, which is input from the playback module 102. Further, the sound output control module 101 sends the right-channel audio signal CRin, which is input from the playback module 102, to the second headphone ER as a right-channel audio output signal CRout. For example, the right-channel audio output signal CRout is a signal which is equal to the right-channel audio signal CRin, which is input from the playback module 102.
The monaural output mode is a mode for outputting sound corresponding to the monaural audio signal. In the monaural output mode, the sound output control module 101 generates a monaural audio signal by mixing the left-channel audio signal CLin, which is input from the playback module 102, and the right-channel audio signal CRin, which is input from the playback module 102. The sound output control module 101 sends the generated monaural audio signal to at least one of the first headphone EL and second headphone ER. Although the monaural audio signal may be sent to both the first headphone EL and second headphone ER, the monaural audio signal may be sent to only one headphone, which is selected from the first headphone EL and second headphone ER. For example, one of the first headphone EL and second headphone ER, which is worn on the human body, is selected, and the monaural audio signal may be sent to only the selected headphone.
In general, in many cases, a left-channel audio signal (SL) and a right-channel audio signal (SR), which are included in a sound source recorded in stereo, are not correlated (SL ≠ SR). If only one of the two signals which are not correlated is listened to by only one of the ears, the user tends to more easily feel unnaturalness, than in the case where the left-channel audio signal (SL) and right-channel audio signal (SR) are listened to by the left and right ears. In the present embodiment, when a transition from the both-ear wearing state to the one-ear wearing state is detected, the operation mode of the sound output control module 101 is automatically changed from the stereo output mode to the monaural output mode. Accordingly, if one of the first headphone EL and second headphone ER goes out of contact with the user's ear, the audio signal that is output from the sound output control module 101 is automatically changed from the stereo audio signal to the monaural audio signal. Therefore, no matter whether the user listens to the audio signal by both ears or one ear, it becomes possible to output sound that is free of unnaturalness to the user.
In addition, there are cases in which the volume of sound, which is listenable for the user, varies between the case in which sound is listened to by both ears and the case in which sound is listened to by one ear alone. Thus, in the monaural output mode, the sound output control module 101 not only generates and sends the monaural audio signal, but also has a volume auto-adjusting function for automatically varying the volume of the generated monaural audio signal by a predetermined amount. Thereby, the sound, which is listenable for the user, can be output.
The first headphone EL is provided with a first contact sensor HL for detecting that the first headphone EL is in contact with the human body. The first contact sensor HL detects whether the first headphone EL is in contact with the human body, and outputs the above-described first wearing detection signal KL on the basis of the detection result. The first contact sensor HL is provided at a predetermined position on the body of the first headphone EL. Specifically, as shown in
The first contact sensor HL may be composed of a device which can detect contact with an object such as the human body, for instance, an electrostatic sensor or a pressure-sensitive sensor. In the case where the first contact sensor HL is composed of, e.g. an electrostatic sensor, if the first contact sensor HL comes in contact with the ear, the electrostatic capacitance of the first contact sensor HL varies, and accordingly the voltage value of the first wearing detection signal KL varies. Thus, the sound output control module 101 can determine whether the first headphone EL is worn on the ear, by monitoring the voltage value of the first wearing detection signal KL.
The second headphone ER is provided with a second contact sensor HR for detecting that the second headphone ER is in contact with the human body. The second contact sensor HR detects whether the second headphone ER is in contact with the human body, and outputs the above-described second wearing detection signal KR on the basis of the detection result. The second contact sensor HR is provided at a predetermined position on the body of the second headphone ER. Specifically, the second contact sensor HR is provided at a predetermined position on the body of the second headphone ER, which comes in contact with the ear when the second headphone ER is worn on the ear.
The second contact sensor HR, like the first contact sensor HL, may be composed of a device which can detect contact with an object such as the human body, for instance, an electrostatic sensor or a pressure-sensitive sensor. In the case where the second contact sensor HR is composed of, e.g. an electrostatic sensor, if the second contact sensor HR comes in contact with the ear, the electrostatic capacitance of the second contact sensor HR varies, and accordingly the voltage value of the second wearing detection signal KR varies. Thus, the sound output control module 101 can determine whether the second headphone ER is worn on the ear, by monitoring the voltage value of the second wearing detection signal KR.
In
In
Two connectors 105 and 106, in addition to the above-described sound output control module 101, are provided in the additional device 12. The left-channel audio output signal CLout, right-channel audio output signal CRout, first wearing detection signal KL and second wearing detection signal KR are allocated to the connector 105 on the paired headphones EL and ER side. The paired headphones EL and ER are connected to the connector 105 of the additional device 12 via a cable 11 and a headphone plug.
The left-channel audio signal CLin and right-channel audio signal CRin are allocated to the connector 106 on the player apparatus 10 side. The connector 106 is connected to a connector 104, which is provided in the player apparatus 10, via a cable 13 and a headphone plug.
In the case where the additional device 12 is realized as the above-described remote-control unit, the additional device 12 further includes an operation unit 107. In accordance with a user's operation of the operation section 107, the sound output control module 101 outputs a control signal Cont for remote-controlling the playback operation of the player apparatus 10 and the volume of the stereo audio signal which is played back. The control signal Cont from the sound output control module 101 is sent to the playback module 102 via the connector 106 and connector 104.
A wireless communication device 201 for executing wireless communication is built in the first headphone EL. The wireless communication device 201 transmits the first wearing detection signal KL, which is output from the first contact sensor HL, by a wireless signal (RF signal). In addition, a wireless communication device 202 for executing wireless communication is built in the second headphone ER. The wireless communication device 202 transmits the second wearing detection signal KR, which is output from the second contact sensor HR, by a wireless signal (RF signal).
A wireless communication device 110 is provided on the sound output control module 101 side. The wireless communication device 110 executes wireless communication with each of the wireless communication devices 201 and 202, and receives the first wearing detection signal KL and second wearing detection signal KR from the headphones EL and ER. The first wearing detection signal KL and second wearing detection signal KR, which are received by the wireless communication device 110, are sent to the sound output control module 101.
In the structure in which the sound output control module 101 is provided in the player apparatus 10, as described with reference to
In the structure in which the sound output control module 101 is provided in the additional device 12 on the outside of the player apparatus 10, as described with reference to
Each of the wireless communication devices 201, 202 and 110 can be realized, for example, by a Bluetooth® module.
If the first contact sensor HL comes in contact with the human body, the voltage value of the first wearing detection signal KL becomes higher than a threshold value Th. If the first contact sensor HL goes out of contact with the human body, the voltage value of the first wearing detection signal KL lowers to the threshold value Th or below. Similarly, if the second contact sensor HR comes in contact with the human body, the voltage value of the second wearing detection signal KR becomes higher than the threshold value Th. If the second contact sensor HR goes out of contact with the human body, the voltage value of the second wearing detection signal KR lowers to the threshold value Th or below.
Next, referring to a flow chart of
If the sound playback apparatus 100 is powered on (step S101), the sound output control module 101 determines, on the basis of the first wearing detection signal KL that is sent from the first headphone EL and the second wearing detection signal KR that is sent from the second headphone ER, whether the wearing state of the first headphone EL and second headphone ER is the first state (both-ear wearing state) in which both the first headphone EL and second headphone ER are worn on the human body, or the second state (one-ear wearing state) in which one of the first headphone EL and second headphone ER is worn on the human body and the other of the first and second headphones EL and ER is not worn on the human body (step S102).
If the wearing state is the both-ear wearing state, the sound output control module 101 selects the stereo output mode (also referred to simply as “stereo mode”) (step S103). In this case, the sound output control module 101 sends the stereo audio signal (left-channel audio signal and right-channel audio signal) from the playback module 102 to the first headphone EL and second headphone ER.
If the wearing state is the one-ear wearing state, the sound output control module 101 selects the monaural output mode (also referred to simply as “monaural mode”) (step S105). In this case, the sound output control module 101 generates a monaural audio signal by mixing the left-channel audio signal and the right-channel audio signal, which are included in the stereo audio signal from the playback module 102, and sends the monaural audio signal to at least one of the first headphone EL and second headphone ER. Although the monaural audio signal may be sent to both the first headphone EL and second headphone ER, the monaural audio signal may be sent to only one headphone, which is selected from the first headphone EL and second headphone ER. For example, one of the first headphone EL and second headphone ER, which is worn on the human body, is selected, and the monaural audio signal may be sent to only the selected headphone. Thereby, sound leak from the headphone, which is not worn on the human body, can be prevented.
In each operation mode of the stereo output mode and monaural output mode, the sound output control module 101 continues to monitor the first wearing detection signal KL and the second wearing detection signal KR.
While the sound output control module 101 is operating in the stereo output mode, the sound output control module 101 determines, on the basis of the first wearing detection signal KL and second wearing detection signal KR, whether a transition occurs from the both-ear wearing state to the one-ear wearing state (step S104).
If the transition from the both-ear wearing state to the one-ear wearing state is detected (YES in step S104), the sound output control module 101 selects the monaural output mode and switches the operation mode from the stereo output mode to the monaural output mode (step S105).
While the sound output control module 101 is operating in the monaural output mode, the sound output control module 101 determines, on the basis of the first wearing detection signal KL and second wearing detection signal KR, whether a transition occurs from the one-ear wearing state to the both-ear wearing state (step S106).
If the transition from the one-ear wearing state to the both-ear wearing state is detected (YES in step S106), the sound output control module 101 selects the stereo output mode and switches the operation mode from the monaural output mode to the stereo output mode (step S103).
The sound output control module 101 includes a timer 71, a comparison module 72, a comparison module 73, a timer 74, a switching control module 75 and a stereo/monaural switching module 76.
The comparison module 72 compares an elapsed time after the value of the first wearing detection signal KL becomes higher than the threshold value Th with a first predetermined time which is given by the timer 71, thereby to determine that the first headphone EL is worn on the human body, on condition that the value of the first wearing detection signal KL is continuously higher than the threshold value Th for the first predetermined time or more which is given by the timer 71. If the value of the first wearing detection signal KL is continuously higher than the threshold value Th for the first predetermined time or more which is given by the timer 71, the comparison module 72 outputs a control signal PL of logic “1”. The control signal PL of logic “1” indicates that the first headphone EL is worn on the human body. The first predetermined time can be set between about one second and about three seconds, for example, at about two seconds.
In addition, the comparison module 72 compares an elapsed time after the value of the first wearing detection signal KL lowers to the threshold value Th or less with the first predetermined time, thereby to determine that the first headphone EL is not worn on the human body, on condition that the value of the first wearing detection signal KL is continuously the threshold value Th or less for the first predetermined time or more. If the value of the first wearing detection signal KL is continuously the threshold value Th or less for the first predetermined time or more, the comparison module 72 outputs a control signal PL of logic “0”. The control signal PL of logic “0” indicates that the first headphone EL is not worn on the human body.
The comparison module 73 compares an elapsed time after the value of the second wearing detection signal KR becomes higher than the threshold value Th with a second predetermined time which is given by the timer 74, thereby to determine that the second headphone ER is worn on the human body, on condition that the value of the second wearing detection signal KR is continuously higher than the threshold value Th for the second predetermined time or more which is given by the timer 74. If the value of the second wearing detection signal KR is continuously higher than the threshold value Th for the second predetermined time or more which is given by the timer 74, the comparison module 73 outputs a control signal PR of logic “1”. The control signal PR of logic “1” indicates that the second headphone ER is worn on the human body. The second predetermined time can be set, for example, at the same value as the first predetermined value.
In addition, the comparison module 73 compares an elapsed time after the value of the second wearing detection signal KR lowers to the threshold value Th or less with the second predetermined time, thereby to determine that the second headphone ER is not worn on the human body, on condition that the value of the second wearing detection signal KR is continuously the threshold value Th or less for the second predetermined time or more. If the value of the second wearing detection signal KR is continuously the threshold value Th or less for the second predetermined time or more, the comparison module 73 outputs a control signal PR of logic “0”. The control signal PR of logic “0” indicates that the second headphone ER is not worn on the human body.
With the above-described structure, it is possible to prevent the sensitivity of detection of the wearing/non-wearing state from becoming excessively high, and to prevent the occurrence of frequent switching between the stereo mode and the monaural mode.
The switching control module 75 determines, on the basis of the control signal PL and control signal PR, whether the wearing state of the first headphone EL and the second headphone ER is the both-ear wearing state or one-ear wearing state. Specifically, if both the control signal PL and control signal PR are logic “1”, the switching control module 75 outputs a switching control signal PT of logic “1” to the stereo/monaural switching module 76. The switching control signal PT of logic “1” indicates that the wearing state is the both-ear wearing state. If one of the control signal PL and control signal PR is logic “0”, the switching control module 75 outputs a switching control signal PT of logic “0” to the stereo/monaural switching module 76. The switching control signal PT of logic “0” indicates that the wearing state is the one-ear wearing state.
In accordance with the switching control signal PT, the stereo/monaural switching module 76 sends one of the stereo audio signal and monaural audio signal to the pair of headphones EL and ER. Specifically, while the switching control signal PT is logic “1”, the stereo/monaural switching module 76 sends the left-channel audio signal CLin, which is input from the playback module 102, to the first headphone EL as the left-channel audio output signal CLout, and sends the right-channel audio signal CRin, which is input from the playback module 102, to the second headphone ER as the right-channel audio output signal CRout. While the switching control signal PT is logic “0”, the stereo/monaural switching module 76 generates a monaural audio signal by mixing the left-channel audio signal CLin and the right-channel audio signal CRin, and sends the generated monaural audio signal to at least one of the first headphone EL and second headphone ER.
The stereo/monaural switching module 76 includes four switches Sw1 to Sw4, which correspond to the left-channel audio signal CLin, right-channel audio signal CRin, left-channel audio output signal CLout and right-channel audio output signal CRout, and an addition unit 81.
Each of the four switches Sw1 to Sw4 is connected to a stereo terminal (St) side when the switching control signal PT is logic “1”. In this case, the left-channel audio signal CLin is sent to the first headphone EL as the left-channel audio output signal CLout, and the right-channel audio signal CRin is sent to the second headphone ER as the right-channel audio output signal CRout.
Each of the four switches Sw1 to Sw4 is connected to a monaural terminal (Mo) side when the switching control signal PT is logic “0”. In this case, the left-channel audio signal CLin and the right-channel audio signal CRin are sent to the addition unit 81. The addition unit 81 adds the left-channel audio signal CLin and the right-channel audio signal CRin, thereby mixing the left-channel audio signal CLin and the right-channel audio signal CRin and generating the monaural audio signal.
A volume adjusting unit 82 may additionally be provided in the stereo/monaural switching module 76. The volume adjusting unit 82 automatically varies the volume of the monaural audio signal, which is obtained by the addition unit 81, by a predetermined amount. Usually, there are cases in which the volume of sound, which is listenable for humans, varies between the case in which sound is listened to by both ears and the case in which sound is listened to by one ear alone. In addition, in many cases, the proper volume in the case where a stereo audio signal is listened to by both ears is different from the proper volume in the case where a monaural audio signal is listened to by one ear. Thus, the volume adjusting unit 82 automatically adjusts the volume of the monaural audio signal, and thereby a more listenable audio signal can be output.
The memory device 84 stores a volume set value which is set by the user during the period in which the wearing state of the first headphone EL and second headphone ER is the one-ear wearing state. Specifically, a volume value, which is finally adjusted by the user during the period in which the user is listening to the audio signal in the monaural mode, is stored in the memory device 84.
Each time the wearing state of the first headphone EL and second headphone ER is transitioned from the both-ear wearing state to the one-ear wearing state, the volume set value stored in the memory device 84 is read out by the volume adjusting control module 83, and read-out volume set value is delivered to the volume adjusting unit 82. The volume adjusting unit 82 automatically varies the volume of the generated monaural audio signal so that the volume of the generated monaural audio signal may be adjusted to the volume set value.
The structure shown in
The sound output control module 101 shown in
The first ON/OFF switch 77 is connected to an output terminal for the left-channel audio output signal CLout of the stereo/monaural switching module 76, and permits/prohibits the output of the left-channel audio output signal CLout. Specifically, when the control signal PL is logic “0”, the first ON/OFF switch 77 is turned off, and thus the output of the left-channel audio output signal CLout is prohibited. When the control signal PL is logic “1”, the first ON/OFF switch 77 is turned on, and thus the output of the left-channel audio output signal CLout is permitted.
The second ON/OFF switch 78 is connected to an output terminal for the right-channel audio output signal CRout of the stereo/monaural switching module 76, and permits/prohibits the output of the right-channel audio output signal CRout. Specifically, when the control signal PR is logic “0”, the second ON/OFF switch 78 is turned off, and thus the output of the right-channel audio output signal CRout is prohibited. When the control signal PR is logic “1”, the second ON/OFF switch 78 is turned on, and thus the output of the right-channel audio output signal CRout is permitted.
In the case where the first headphone EL is worn on the human body and the second headphone ER is not worn on the human body, the control signal PL is logic “1” and the control signal PR is logic “0”. In this case, the first ON/OFF switch 77 is turned on and the second ON/OFF switch 78 is turned off. Accordingly, the monaural signal, which is generated by the stereo/monaural switching module 76, is sent to only the first headphone EL via the first ON/OFF switch 77, and is not sent to the second headphone ER. Therefore, sound leak from the second headphone ER can be prevented.
In the case where the first headphone EL is not worn on the human body and the second headphone ER is worn on the human body, the control signal PL is logic “0” and the control signal PR is logic “1”. In this case, the first ON/OFF switch 77 is turned off and the second ON/OFF switch 78 is turned on. Accordingly, the monaural signal, which is generated by the stereo/monaural switching module 76, is sent to only the second headphone ER via the second ON/OFF switch 78, and is not sent to the first headphone EL. Therefore, sound leak from the first headphone EL can be prevented.
In the case where neither the first headphone EL nor the second headphone ER is worn on the human body, the control signal PL is logic “0” and the control signal PR is logic “0”. In this case, the first ON/OFF switch 77 is turned off and the second ON/OFF switch 78 is also turned off. Accordingly, the monaural signal is sent to neither the first headphone EL nor the second headphone ER. Therefore, sound leak from the first headphone EL and the second headphone ER can be prevented.
In addition, in the case where neither the first headphone EL nor the second headphone ER is worn on the human body, that is, in the case where the control signal PL is logic “0” and the control signal PR is logic “0”, the switching control module 75 sends to the playback module 102 a stop control signal which instructs the stop of the playback operation (e.g. a signal instructing a pause, or a signal instructing a transition to a sleep state), thereby stopping the playback operation of the playback module 102. Hence, the power consumption in the case where neither the first headphone EL nor the second headphone ER is worn on the human body can greatly be reduced.
As has been described above, according to the present embodiment, the operation mode is automatically switched from the stereo mode to the monaural mode in response to a transition from the both-ear wearing mode to the one-ear wearing mode. Therefore, even if the user does not manually switch the operation mode to the monaural mode, the user can listen to sound, which is free of unnaturalness, by one ear alone.
In addition, when the stereo mode is switched to the monaural mode, the volume of the monaural audio signal is automatically varied by the volume adjusting unit 82, and automatically adjusted to a proper volume level for listening of the monaural audio signal by one ear of the user. If the operation mode is restored from the monaural mode to the stereo mode, the stereo audio signal is sent, not through the volume adjusting unit 82, to the first headphone EL and the second headphone ER, and thus the volume level can be restored to a volume level that is proper to the stereo mode.
The function of the sound output control module 101 can also be realized by a program which is executed by a microprocessor or a DSP. In addition, the first ON/OFF switch 77 and the second ON/OFF switch 78 may be built in the first headphone EL and the second headphone ER, respectively. In this case, for example, the sound output control module 101 may be configured to supply only control signals, which ON/OFF control the first ON/OFF switch 77 and the second ON/OFF switch 78, to the first headphone EL and the second headphone ER.
The various modules of the systems described herein can be implemented as software applications, hardware and/or software modules, or components on one or more computers, such as servers. While the various modules are illustrated separately, they may share some or all of the same underlying logic or code.
While certain embodiments of the inventions have been described, these embodiments have been presented by way of example only, and are not intended to limit the scope of the inventions. Indeed, the novel methods and systems described herein may be embodied in a variety of other forms; furthermore, various omissions, substitutions and changes in the form of the methods and systems described herein may be made without departing from the spirit of the inventions. The accompanying claims and their equivalents are intended to cover such forms or modifications as would fall within the scope and spirit of the inventions.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2007-326237 | Dec 2007 | JP | national |
