JP2010128789A - Portable terminal, alarm notification method and program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To enable a user in using a portable terminal with an earphone to notice the approach of a person or an object around the user. <P>SOLUTION: If a person or an object generating a sound approaches in an environment where a user uses an earphone of a portable telephone and external sound is intercepted, a sensor built in the cellular phone detects a sound frequency. At the time, the cellular phone automatically controls the volume of listening sound to fade out the sound (gradually reduce the volume) and sends an alarm notification sound to the user. Further, the cellular phone determines which object approaches by a difference in sound frequencies and notifies an alarm on a screen of the cellular phone. Further, the cellular phone detects a change in frequencies by using the principle of Doppler effect and outputs an alarm only to the object increasing the sound frequency. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a mobile terminal, and more particularly to a mobile terminal that performs alarm (alarm, warning) notification.

  In recent years, there are an increasing number of users walking around the city while operating their mobile phones with earphones while wearing earphones and listening to voice and music.

  However, when a user (user) wears an earphone and walks while operating a mobile phone, the user (user) often does not notice even if a dangerous object such as a car approaches nearby. There is a risk of serious accidents. Also, due to the deterioration of security, suspicious people are attacked frequently at night.

  Until now, there were mobile phones with alarms (warnings, warnings) notifications when accidents or incidents occurred, but mobile phones with alarm notifications that helped prevent "previous". There is no telephone.

  Conventionally, a user who is operating a mobile phone while listening to voice or music using an earphone is blocked from the outside. It was limited to means such as ringing at the light and blinking of light at the LED (light emitting diode).

  However, these means cannot be instantly noticed to a user who is concentrating on the mobile terminal. As a result, contact accidents with moving bodies such as automobiles and suspicious person attacks frequently occur and threaten safety.

As a related technique, Japanese Unexamined Patent Application Publication No. 07-069132 (Patent Document 1) discloses a vehicle audio notification device.
In this related technology, the environmental sound electric signal amplified by the input amplifier of the sound collector is compared with the registered data by the discrimination unit of the voice recognition device, and only human voice and vehicle noise are extracted. For the extracted vehicle noise, the distance of the vehicle is calculated from the sound pressure level under simulation, and by comparing with the sound pressure level of the vehicle noise sampled at a certain time difference, a pedestrian or the like Or whether another vehicle is approaching or moving away. When a pedestrian or another vehicle is approaching, the system controller notifies the driver of the predetermined audio information obtained by the audio information converter using an output device composed of speakers, and the driver's attention is given. Arouse or give specific driving instructions.

Japanese Patent Application Laid-Open No. 07-069312

  An object of the present invention is to provide a portable terminal in which an external voice detection function is added to a voice transmission / reception system or a voice reproduction system as a solution to an alarm (alarm) notification means.

  For example, it is easy to make anomalies by giving changes such as audio fading out (gradually lowering the volume) and alarm notification on the screen to the act of actively listening to music and watching the screen. It is thought that can be noticed.

  The portable terminal of the present invention receives a wave frequency from a detector that detects a wave frequency related to an object that may be approaching, and samples the wave frequency for a certain period of time to obtain the wave frequency. When receiving the wave frequency data from the sensor control means for delivering the corresponding wave frequency data, the profile management means for managing the profile of the object in accordance with the wave frequency data, and the sensor control means, the data is sent to the profile management means for the user Check if there is any audio that is currently flowing through the earphones worn by, and if there is audio that is currently flowing, perform processing to mute the current audio, and manage the profile Terminal data processing that performs alarm notification processing to the user based on the profile when the profile is received from ; And a stage.

  The alarm notification method of the present invention is an alarm notification method implemented by a mobile terminal, the step of detecting a wave frequency related to an object that may be approaching, and sampling the wave frequency for a certain period of time. The wave frequency data corresponding to the wave frequency is paid out. When the wave frequency data is received, the user confirms whether there is a sound that is currently flowing through the earphone worn by the user, and there is a sound that is currently flowing. In this case, a process for muting the currently flowing sound, a step of paying out an object profile according to the wave frequency data when receiving the wave frequency data, and a profile receiving the profile are received. And an alarm notification process for the user based on the above.

  The program of the present invention includes a step of detecting a wave frequency related to an object that may be approaching, a step of sampling the wave frequency for a certain period of time, and issuing wave frequency data corresponding to the wave frequency; When wave frequency data is received, it is checked whether there is any sound that is currently flowing through the earphone worn by the user. If there is sound that is currently flowing, the current sound is muted. A step of performing the above processing, a step of paying out a profile of the object according to the wave frequency data when receiving the wave frequency data, and a step of performing an alarm notification process for the user based on the profile when receiving the profile. It is a program for causing a terminal to execute.

  Here, as an example of the wave frequency, at least one frequency is assumed among the frequencies of sound, light, and electromagnetic waves emitted from an object, and the reflection frequencies of sound, light, and electromagnetic waves with respect to the object. Note that the reflection frequencies of sound, light, and electromagnetic waves indicate frequencies when sound, light, and electromagnetic waves emitted by the mobile terminal are reflected back to the object. However, actually, it is not limited to these examples.

  Even in an environment where the user is shielded from external sound, it is possible to notify the user of the approach of dangerous goods at an early stage.

Hereinafter, a first embodiment of the present invention will be described with reference to the accompanying drawings.
In this embodiment, when listening to music using an earphone on a mobile terminal, the sound emitted from the object is detected to determine the possibility that the object is approaching.

  As shown in FIG. 1, the portable terminal 10 of the present invention includes an audio sensor 11, a display 12, an earphone receiver 13, a sensor control unit 14, a user interface unit 15, a profile management unit 16, and terminal data processing. Unit 17 and terminal voice control unit 18.

  The mobile terminal 10 is a mobile terminal used by a user (user), and an earphone can be connected as an external I / F (interface). Examples of the portable terminal 10 include a mobile phone, a mobile notebook PC (personal computer), a portable music player, a portable game machine, a car navigation system (car navigation system), or a similar portable electronic device. However, actually, it is not limited to these examples.

  The sound sensor 11 is a detector such as a sound detection sensor that recognizes sound and sound generated by an object (approaching object). The sound sensor 11 sends the sound frequency of the recognized object to the sensor control unit 14. Note that a microphone or a vibration sensor may be used instead of the voice sensor 11. Here, the object is an object detected by the voice sensor 11 and indicates an object that may be approaching.

  The display 12 is a device that displays characters and graphics. The display 12 is also called a monitor. The display 12 displays a message or the like based on the information on the alarm (alarm) screen received from the user interface unit 15. As an example of the display 12, a display device such as an LCD (Liquid Crystal Display), a PDP (Plasma Display), or an organic EL display (Organic electroluminescence display) can be considered. Alternatively, the display 12 may be an interface for outputting information to an external display device. That is, the display 12 may be any output device. However, actually, it is not limited to these examples.

  The earphone receiver 13 is connected to the earphone, receives the alarm sound from the user interface unit 15, and sounds the alarm sound from the earphone. As an example of the earphone receiver 13, an adapter, a speaker terminal, other connection ports (connectors), and the like are conceivable. The earphone may be a headphone. The communication line between the earphone receiver 13 and the earphone may be wired / wireless. Moreover, the earphone receiver 13 and the earphone may be integrated.

  The sensor control unit 14 samples the sound frequency of the object received from the sound sensor 11 for a certain time. When the audio frequency increases, the sensor control unit 14 determines that the object is approaching and sends the audio frequency data corresponding to the audio frequency to the terminal data processing unit 17. When the audio frequency is constant (invariable), the sensor control unit 14 determines that the object is stationary and discards the audio frequency data. When the audio frequency decreases, the sensor control unit 14 determines that the object is moving away and discards the audio frequency data. That is, the sensor control unit 14 determines that the object is not approaching when the audio frequency has not increased, and externally limits the transmission of the audio frequency data to the terminal data processing unit 17. Become. In addition, the sensor control unit 14 performs filtering according to the increase amount of the audio frequency. That is, the sensor control unit 14 determines whether to transmit the audio frequency data to the terminal data processing unit 17 according to the speed of the approaching object.

  When the user interface unit 15 receives the information on the alarm screen from the terminal data processing unit 17, based on the received information, something like “~ is approaching. Message is displayed. In addition, the user interface unit 15 receives an alarm sound from the terminal data processing unit 17 and causes the alarm sound to sound from the earphone via the earphone receiver 13.

  The profile management unit 16 manages the profile of the object according to the audio frequency data. For example, the profile management unit 16 manages, for each frequency, sound and sound generated by an object, such as engine sounds of cars and motorcycles, animal calls, shoe sounds (footsteps), etc., and links the sound frequency and the object attributes. Add (associate) and store. Further, the profile management unit 16 receives the audio frequency data from the terminal data processing unit 17 and sends an alarm display profile or an alarm audio profile corresponding to the audio frequency data to the terminal data processing unit 17.

  Upon receiving the audio frequency data from the sensor control unit 14, the terminal data processing unit 17 sends it to the profile management unit 16. When the terminal data processing unit 17 receives the audio frequency data, the terminal data processing unit 17 checks whether or not there is currently playing music (sound). If there is currently playing music, the terminal data control unit 17 mutes ( Send a command to mute. Further, the terminal data processing unit 17 receives the alarm display profile from the profile management unit 16 and sends it to the user interface unit 15. Further, when the terminal data processing unit 17 receives the alarm voice profile from the profile management unit 16, the terminal data processing unit 17 sends it to the terminal voice control unit 18. When the terminal data processing unit 17 receives the alarm sound from the terminal sound control unit 18, the terminal data processing unit 17 sends the alarm sound to the user interface unit 15.

  The terminal voice control unit 18 controls output of music and alarm voice. When the terminal voice control unit 18 receives an instruction from the terminal data processing unit 17 to stop the currently playing music, the terminal voice control unit 18 mutes the music. At this time, the terminal voice control unit 18 may fade out the music (gradually lower the volume). When the terminal voice control unit 18 receives the alarm voice profile from the terminal data processing unit 17, the terminal voice control unit 18 sends the alarm voice corresponding to the alarm voice profile to the terminal data processing unit 17. That is, the terminal voice control unit 18 finally sounds an alarm voice from the earphone according to the alarm voice profile.

A basic configuration of the sensor control unit 14 will be described with reference to FIG.
The sensor control unit 14 includes an audio frequency data processing unit 141, an audio frequency determination unit 142, and an audio frequency table 143.

  The audio frequency data processing unit 141 sends the audio frequency received from the audio sensor 11 to the audio frequency determination unit 142. Also, the audio frequency data processing unit 141 sends out the audio frequency paid out from the audio frequency table 143 to the terminal data processing unit 17. Furthermore, when the audio frequency data processing unit 141 receives an audio frequency non-transmission signal from the audio frequency determination unit 142, the audio frequency data processing unit 141 transmits nothing to the terminal data processing unit 17.

  The audio frequency determination unit 142 receives the audio frequency from the audio frequency data processing unit 141, and samples the audio frequency for a predetermined time. When the sampled audio frequency is increased, the audio frequency determination unit 142 determines that the object is approaching according to the principle of the Doppler effect, and the audio frequency corresponding to the audio frequency emitted by the object is based on the formula. The voice frequency table 143 is instructed to pay out data. Further, when the sampled audio frequency is constant (invariable), the audio frequency determination unit 142 determines that the object is stationary based on the principle of the Doppler effect, and transmits the audio frequency non-transmission signal to the audio frequency data processing unit 141. Send to In addition, when the sampled audio frequency is decreased, the audio frequency determination unit 142 determines that the object is moving away according to the principle of the Doppler effect, and transmits the audio frequency non-transmission signal to the audio frequency data processing unit 141. Send it out. That is, the audio frequency determination unit 142 determines that the object is not approaching when the audio frequency has not increased, and transmits an audio frequency non-transmission signal to the audio frequency data processing unit 141. The reason is that a stationary object or an object moving away is considered to have a low degree of danger, and the trouble of frequent alarm notifications to the user is reduced. The audio frequency determination unit 142 also has a function of adjusting a sampling time and filtering a frequency band, and can determine only an object that generates a specific sound. As a result, it is possible to construct a system that issues an alarm only when a really dangerous object approaches and then comfortably views music.

  When the audio frequency table 143 receives a command from the audio frequency determination unit 142 to transmit audio frequency data corresponding to the audio frequency, the audio frequency table 143 transmits the audio frequency data corresponding to the audio frequency to the audio frequency data processing unit 141. At this time, in the audio frequency table 143, the audio frequency and the audio frequency data are linked (associated) based on characteristics such as the waveform of the audio frequency. The audio frequency data is data indicating a characteristic audio frequency. For example, in the audio frequency table 143, if the characteristics of the received audio frequency match / similar to the characteristics of the audio frequency indicated by the predetermined audio frequency data, these audio frequencies correspond to the audio frequency data. Therefore, it is possible to specify the audio frequency data corresponding to the audio frequency.

  Actually, the audio frequency table 143 may be included in the audio frequency determination unit 142. That is, the audio frequency determination unit 142 and the audio frequency table 143 can be integrated. The audio frequency table 143 may not exist. For example, the audio frequency determination unit 142 may average the sampled audio frequencies and send the averaged audio frequencies as audio frequency data to the audio frequency data processing unit 141.

The basic configuration of the profile management unit 16 will be described with reference to FIG.
The profile management unit 16 includes a profile management data processing unit 161, a profile determination unit 162, and a profile table 163.

  The profile management data processing unit 161 sends the audio frequency data received from the terminal data processing unit 17 to the profile determination unit 162. Further, the profile management data processing unit 161 sends the profile paid out from the profile table 163 to the terminal data processing unit 17. Further, when a non-corresponding signal is received from the profile determination unit 162, nothing is transmitted to the terminal data processing unit 17.

  The profile determination unit 162 receives the audio frequency data from the profile management data processing unit 161 and searches the profile table 163 for an alarm display profile and an alarm audio profile corresponding to (corresponding to) the audio frequency data. Further, when there is an alarm display profile and an alarm sound profile corresponding to the audio frequency data in the profile table 163, the profile determination unit 162 sends the alarm display profile and the alarm sound profile to the profile table 163. Order. Further, when there is no alarm display profile and alarm audio profile corresponding to the audio frequency data in the profile table 163, the profile determination unit 162 sends a non-corresponding signal to the profile management data processing unit 161.

  When the profile table 163 receives a command from the profile determination unit 162 to send an alarm display profile and an alarm voice profile corresponding to the voice frequency data, the profile table 163 sends the alarm display profile and the alarm voice profile to the profile management data processing unit 161. Send it out.

  Actually, the profile table 163 may be included in the profile determination unit 162. That is, the profile determination unit 162 and the profile table 163 can be integrated.

The configuration of the profile table 163 will be described with reference to FIG.
In the fields in the profile table 163, there are items such as a voice frequency band, an alarm display, and an alarm voice, which are uniquely determined for each frequency band. For example, if the audio frequency band is in the range of P1 to P2, the alarm display DA and the alarm audio SA are linked (associated). If the audio frequency band is P2 to P3, the alarm display DB and the alarm audio SB are linked (associated). Here, “audio frequency band” indicates audio frequency data. “Alarm display” indicates an alarm display profile. “Alarm voice” indicates an alarm voice profile.

  With reference to FIG. 5A and FIG. 5B, the flow of operation when the user receives an alarm notification for an object from the earphone and the display 12 using the mobile terminal 10 of the present invention will be described.

  First, a case where an alarm display and sound are notified to the user through the display 12 and the earphone receiver 13 will be described.

(1) Step K101
The mobile terminal 10 is in an initial state. At this time, the user operates the screen while listening to music by connecting the earphone to the mobile terminal 10.

(2) Step K102
When an object approaches the mobile terminal 10 while producing a sound, the sound sensor 11 detects the sound frequency of the object and sends it to the sensor control unit 14.

(3) Step K103
Here, the sensor control unit 14 performs sampling and filtering of the audio frequency to determine what kind of frequency the object is emitting.

(4) Step K104
If it is determined that the audio frequency has increased, the sensor control unit 14 sends audio frequency data corresponding to the audio frequency to the terminal data processing unit 17.

(5) Step K105
Next, when receiving the audio frequency data, the terminal data processing unit 17 sends a sound ringing stop signal to the terminal audio control unit 18.

(6) Step K106
When the terminal sound control unit 18 receives a sound ringing stop signal from the terminal data processing unit 17, the terminal sound control unit 18 stops the ringing music.

(7) Step K107
On the other hand, the terminal data processing unit 17 sends the audio frequency data to the profile management unit 16.

(8) Step K108
Here, the profile management unit 16 performs matching (presence / absence determination) of alarm display and sound and sound frequency data. That is, the profile management unit 16 confirms whether an alarm display profile and an alarm sound profile corresponding to the sound frequency data exist.

(9) Step K109
When there is an alarm display profile corresponding to the audio frequency data, the profile management unit 16 sends the corresponding alarm display profile to the terminal data processing unit 17.

(10) Step K110
At the same time, when there is an alarm voice profile corresponding to the voice frequency data, the profile management unit 16 sends the corresponding alarm voice profile to the terminal data processing unit 17.

(11) Step K111
Next, the terminal data processing unit 17 sends the received alarm display profile to the user interface unit 15.

(12) Step K112
Further, the terminal data processing unit 17 sends the received alarm voice profile to the terminal voice control unit 18.

(13) Step K113
The user interface unit 15 displays an alarm image (moving image) on the screen of the display 12 according to the received alarm display profile.

(14) Step K114
In addition, the terminal voice control unit 18 sounds an alarm voice according to the received alarm voice profile. For example, the terminal voice control unit 18 sends an alarm voice corresponding to the alarm voice profile to the user interface unit 15. The user interface unit 15 sounds an alarm sound via the earphone.

(15) Step K115
From the earphone worn by the user, the music being watched fades out (the volume is gradually lowered), and an alarm sound sounds. In addition, an alarm image (still image, moving image, etc.) is displayed on the screen of the display 12 operated by the user. At this time, it is preferable that the user interface unit 15 synchronizes the display of the alarm image (moving image) and the output of the alarm sound. For example, the user interface unit 15 outputs simultaneously when both alarm image (moving image) data and alarm sound data are available.

  Next, a case where an alarm display and sound are not notified to the user through the display 12 and the earphone receiver 13 will be described. Here, the case 1 and the case 2 will be described separately.

<Case 1>
(1) Step K101
The user is in an initial state. At this time, the user operates the screen while listening to music by connecting the earphone.

(2) Step K102
When an object approaches the mobile terminal 10 while producing a sound, the sound sensor 11 detects the sound frequency of the object and sends it to the sensor control unit 14.

(3) Step K103
Here, the sensor control unit 14 performs sampling of the audio frequency to determine what kind of frequency the object is emitting.

(4) Step K116
When the sensor control unit 14 cannot acquire the audio frequency, or when it is determined that the audio frequency has not changed (invariable), and when it is determined that the audio frequency has decreased, the audio corresponding to the audio frequency The frequency data is not sent to the terminal data processing unit 17. In other words, when the sensor control unit 14 cannot acquire the audio frequency, or when it is determined that the audio frequency has not changed (invariable), and when it is determined that the audio frequency has decreased, externally, The transmission of audio frequency data to the terminal data processing unit 17 is restricted.

(5) Step K118
As a result, the user continues the act of viewing music on the mobile terminal 10 and operating the screen. That is, the mobile terminal 10 continues the current operation.

<Case 2>
(1) Step K101
The user is in an initial state. At this time, the user operates the screen while listening to music by connecting the earphone.

(2) Step K102
When an object approaches the mobile terminal 10 while producing a sound, the sound sensor 11 detects the sound frequency of the object and sends it to the sensor control unit 14.

(3) Step K103
Here, the sensor control unit 14 performs sampling of the audio frequency to determine what kind of frequency the object is emitting.

(4) Step K104
If it is determined that the audio frequency is increasing, the sensor control unit 14 sends the audio frequency data to the terminal data processing unit 17.

(5) Step K105
Next, when receiving the audio frequency data, the terminal data processing unit 17 sends a sound ringing stop signal to the terminal audio control unit 18.

(6) Step K106
When the terminal sound control unit 18 receives a sound ringing stop signal from the terminal data processing unit 17, the terminal sound control unit 18 stops the ringing music.

(7) Step K107
On the other hand, the terminal data processing unit 17 sends the audio frequency data to the profile management unit 16.

(8) Step K108
Here, the profile management unit 16 performs matching (presence / absence determination) of alarm display and sound and sound frequency data.

(9) Step K117
When there is no corresponding data, the profile management unit 16 does not send the alarm display profile and the alarm voice profile to the terminal data processing unit 17. That is, when there is no corresponding data, the profile management unit 16 externally restricts the transmission of the alarm display profile and the alarm voice profile to the terminal data processing unit 17.

(10) Step K118
As a result, the user continues the act of viewing music on the mobile terminal 10 and operating the screen. That is, the mobile terminal 10 continues the current operation.

  With reference to FIG. 6, the operation | movement of the audio | voice frequency determination in the sensor control part 14 is demonstrated.

(1) Step S101
The sensor control unit 14 is in an initial state. At this time, the sensor control unit 14 acquires the sound frequency emitted from the object from the sound sensor 11.

(2) Step S102
Next, the audio frequency data processing unit 141 sends the audio frequency data to the audio frequency determination unit 142.

(3) Step S103
The audio frequency determination unit 142 performs audio frequency sampling for a certain period of time.

(4) Step S104
Here, the audio frequency determination unit 142 performs audio frequency filtering to determine what kind of frequency the object emits.

(5) Step S105
When the audio frequency determination unit 142 determines that the audio frequency has increased, the audio frequency determination unit 142 sends audio frequency data corresponding to the audio frequency to the audio frequency data processing unit 141. That is, when the audio frequency determination unit 142 determines that the audio frequency acquired from the audio sensor 11 is valid, the audio frequency determination unit 142 instructs the audio frequency table 143 to issue audio frequency data corresponding to the audio frequency. When the audio frequency table 143 receives a command from the audio frequency determination unit 142 to transmit audio frequency data corresponding to the audio frequency, the audio frequency table 143 transmits the audio frequency data corresponding to the audio frequency to the audio frequency data processing unit 141.

(6) Step S106
The audio frequency data processing unit 141 sends audio frequency data corresponding to the audio frequency to the terminal data processing unit 17.

(7) Step S107
On the other hand, when the audio frequency determination unit 142 cannot acquire the audio frequency, or when the audio frequency is constant (invariable), and when it is determined that the audio frequency is decreasing, the audio frequency data processing unit 141 receives the audio frequency. Send non-corresponding signal. That is, when the audio frequency determination unit 142 determines that the audio frequency acquired from the audio sensor 11 is invalid, the audio frequency determination unit 142 sends a non-corresponding signal to the audio frequency data processing unit 141.

(8) Step S108
When the audio frequency data processing unit 141 receives the non-corresponding signal, the audio frequency data processing unit 141 does not transmit the audio frequency to the terminal data processing unit 17. That is, when the audio frequency data processing unit 141 receives a non-corresponding signal, the audio frequency data processing unit 141 externally limits the transmission of audio frequency data to the terminal data processing unit 17.

  With reference to FIG. 7, an operation of matching the audio frequency, the alarm display profile, and the alarm audio profile in the profile management unit 16 will be described.

(1) Step P101
The terminal data processing unit 17 is in an initial state. At this time, the terminal data processing unit 17 sends the audio frequency to the profile management data processing unit 161.

(2) Step P102
Upon receiving the audio frequency, the profile management data processing unit 161 sends the received audio frequency to the profile determination unit 162.

(3) Step P103
When the profile determination unit 162 receives the audio frequency, the profile determination unit 162 refers to the field in the profile table 163.

(4) Step P104
Here, the profile determination unit 162 determines whether the audio frequency corresponds to a frequency band in the table. That is, the profile determination unit 162 performs matching (presence / absence determination) between the audio frequency and the frequency band in the table.

(5) Step P105
When the audio frequency corresponds to the frequency band in the table, the profile determination unit 162 sends the corresponding alarm display profile and alarm audio profile to the profile management data processing unit 161. That is, when there is a voice frequency, alarm display profile, and alarm voice profile in the profile table 163 corresponding to the input voice frequency, the profile determination unit 162 performs profile management of the corresponding alarm display profile and alarm voice profile. The data is sent to the data processing unit 161.

(6) Step P106
The profile management data processing unit 161 sends the corresponding alarm display profile and alarm sound profile to the terminal data processing unit 17.
(7) Step P107
On the other hand, the profile determination unit 162 sends a profile non-corresponding signal to the profile management data processing unit 161 when the audio frequency does not correspond to the frequency band in the table. That is, when there is no audio frequency, alarm display profile, and alarm audio profile in the profile table 163 corresponding to the input audio frequency, the profile determination unit 162 does not apply the profile to the profile management data processing unit 161. Send a signal.

(8) Step P108
When the profile management data processing unit 161 receives the profile non-corresponding signal, the corresponding alarm display profile and alarm sound profile do not exist, and therefore the profile management data processing unit 161 does not send the profile to the terminal data processing unit 17. That is, externally, the profile management data processing unit 161 is configured to limit the transmission of profiles to the terminal data processing unit 17.

  By using the present invention, the user can recognize early on dangerous goods approaching himself / herself even in an environment where the earphones are being used and is blocked from external sound. Can be prevented in advance.

The second embodiment of the present invention will be described below.
In the present embodiment, a case will be described in which a user watches music while wearing an earphone with a music player capable of short-range communication with the mobile terminal 10.

  For example, it is assumed that the mobile terminal 10 is a wearable terminal. At this time, when the user attaches the mobile terminal 10 to clothes or a bag and views music with the music player, the mobile terminal 10 detects the sound frequency of the approaching object, and the alarm sound is transmitted to the music player. Send to. The user can hear the alarm sound from the earphone of the music player and can recognize the approach of a dangerous object.

  FIG. 8 shows a basic configuration of the mobile terminal 10 and the music player 20 in the present embodiment.

  The mobile terminal 10 includes an audio sensor 11, a sensor control unit 14, a profile management unit 16, a terminal data processing unit 17, and a short-range communication unit 19.

  The music player 20 also includes an earphone receiver 23, a user interface unit 25, a terminal data processing unit 27, a terminal voice control unit 28, and a short-range communication unit 29.

  Note that the mobile terminal 10 and the music player 20 may have the same configuration as the mobile terminal 10 of the first embodiment. That is, the mobile terminal 10 and the music player 20 may be the mobile terminal 10 of the first embodiment. For example, the mobile terminal 10 according to the first embodiment can be used as the mobile terminal 10 and the music player 20 according to the present embodiment as long as the mobile terminal 10 has a short-range communication function.

  The sound sensor 11 is a detector such as a sound detection sensor that recognizes sound and sound. The sound sensor 11 sends the sound frequency of the recognized object to the sensor control unit 14. Note that a microphone or a vibration sensor may be used instead of the voice sensor 11.

  The sensor control unit 14 samples the sound frequency of the object received from the sound sensor 11 for a certain period of time. When the audio frequency increases, it is determined that the object is approaching, and the audio frequency data is transmitted to the terminal data processing unit 17. When the audio frequency is constant (unchanged) or decreases, it is determined that the object is stationary or moving away, and the audio frequency data is discarded. Further, it is determined whether or not to send the frequency data to the terminal data processing unit 17 according to the speed of the approaching object by filtering according to the increase amount of the audio frequency.

  The profile management unit 16 manages the profile of the object according to the audio frequency data. For example, the profile management unit 16 manages, for each frequency, sounds generated by an object such as an engine sound of a car, an animal sound, a shoe sound (footsteps), and associates (associates) attributes of the object. Upon receiving the audio frequency data from the terminal data processing unit 17, the profile management unit 16 sends an alarm display profile and an alarm audio profile corresponding to the audio frequency data to the terminal data processing unit 17.

  Upon receiving the audio frequency data from the sensor control unit 14, the terminal data processing unit 17 sends it to the profile management unit 16. When the alarm display profile and the alarm sound profile are received from the profile management unit 16, they are sent to the short-range communication unit 19.

  The short-range communication unit 19 has a short-range communication function, and sends the alarm display profile and the alarm voice profile issued from the terminal data processing unit 17 to the outside via the short-range communication line.

  Examples of short-distance communication lines include IrDA (Infrared Data Association), Bluetooth (registered trademark), weak wireless, serial communication lines, and the like. However, actually, it is not limited to these examples.

  The near field communication unit 29 receives the alarm display profile and the alarm sound profile transmitted from the mobile terminal 10 via the near field communication line. The received profile is sent to the terminal data processing unit 27.

  The terminal data processing unit 27 sends the former (alarm display profile) out of the alarm display profile and the alarm sound profile received from the short-range communication unit to the user interface unit 25. If there is music that is currently playing, the terminal voice control unit 28 is commanded to stop, and the latter (alarm voice profile) is sent to the terminal voice control unit 28. Further, when receiving the alarm sound from the terminal sound control unit 28, the terminal data processing unit 27 sends the alarm sound to the user interface unit 25.

  When the terminal voice control unit 28 receives a command from the terminal data processing unit 27 to stop the music currently being played, the terminal voice control unit 28 mutes the music. When the terminal voice control unit 28 receives the alarm voice profile from the terminal data processing unit 27, the terminal voice control unit 28 sounds the corresponding voice. That is, the terminal voice control unit 28 sends an alarm voice corresponding to the received alarm voice profile to the terminal data processing unit 27.

  When the user interface unit 25 receives the information on the alarm screen from the terminal data processing unit 27, the user interface unit 25 displays a message on the display 22 stating that “thing like ~ is approaching. In addition, the user interface unit 25 receives an alarm sound from the terminal data processing unit 27 and causes the alarm sound to sound from the earphone via the earphone receiver 23.

  With reference to FIG. 9A and FIG. 9B, the flow of operation | movement at the time of a user viewing and listening to the alarm sound of an object from the earphone of the music player 20 using the portable terminal 10 of this embodiment is demonstrated.

  First, a case where the user views alarm sound from the earphone of the music player will be described.

(1) Step K201
The mobile terminal 10 is in an initial state. The user attaches the mobile terminal 10 to clothes or a bag.

(2) Step K202
The audio sensor 11 in the mobile terminal 10 senses the audio frequency emitted by the object and sends it to the sensor control unit 14.

(3) Step K203
Here, the sensor control unit 14 performs sampling and filtering of the audio frequency for a certain period of time.

(4) Step K204
When the sensor control unit 14 determines that the audio frequency is increasing, the sensor control unit 14 sends audio frequency data corresponding to the audio frequency to the terminal data processing unit 17.

(5) Step K205
Next, the terminal data processing unit 17 sends the audio frequency data to the profile management unit 16.

(6) Step K206
Here, the profile management unit 16 refers to the profile table 163 and searches for an alarm sound profile corresponding to the acquired sound frequency data.

(7) Step K207
When there is an alarm voice profile corresponding to the obtained voice frequency data in the profile table 163, the profile management unit 16 sends the corresponding alarm voice profile to the terminal data processing unit 17.

(8) Step K208
The terminal data processing unit 17 sends the corresponding alarm voice profile to the near field communication unit 19.

(9) Step K209
The near field communication unit 19 sends a corresponding alarm sound profile from the mobile terminal 10 to the outside via the near field communication line.

(10) Step M201
The near field communication unit 29 in the music player 20 receives the alarm sound profile transmitted from the near field communication unit 19 via the near field communication line.

(11) Step M202
The short-range communication unit 29 sends the received alarm voice profile to the terminal data processing unit 17.

(12) Step M203
Upon receiving the alarm voice profile, the terminal data processing unit 17 instructs the terminal voice control unit 18 to stop the sounding of music.

(13) Step M204
When the terminal voice control unit 18 receives a voice ringing stop signal from the terminal data processing unit 17, the terminal voice control unit 18 stops ringing music.

(14) Step M205
When the ringing of music is stopped, the terminal data processing unit 17 sends an alarm voice profile to the terminal voice control unit 18.

(15) Step M206
The terminal voice control unit 18 sounds an alarm voice according to the alarm voice profile.

(16) Step M207
The user views the alarm sound from the earphone of the music player 20.

  Next, a case where an alarm sound does not sound from the music player and the user continues to watch music will be described. Here, the case 1 and the case 2 will be described separately.

<Case 1>
(1) Step K201
The mobile terminal 10 is in an initial state. The user attaches the mobile terminal 10 to clothes or a bag.

(2) Step K202
The audio sensor 11 in the mobile terminal 10 senses the audio frequency emitted by the object and sends it to the sensor control unit 14.

(3) Step K203
Here, the sensor control unit 14 performs sampling and filtering of the audio frequency for a certain period of time.

(4) Step K210
When the sound control frequency is not acquired, or when the sound control frequency is determined to be constant (invariable), or when the sound control frequency is determined to be decreasing, the sensor control unit 14 The frequency data is not sent to the terminal data processing unit 17. In other words, when the sensor control unit 14 has not acquired the audio frequency, or when it is determined that the audio frequency is constant (invariable), and when it is determined that the audio frequency is decreasing, the sensor control unit 14 is externally used. The transmission of audio frequency data to the terminal data processing unit 17 is restricted.

(5) Step K212
As a result, the user continues to watch music without listening to the alarm sound. That is, the music player 20 continues the current operation.

<Case 2>
(1) Step K201
The mobile terminal 10 is in an initial state. The user attaches the mobile terminal 10 to clothes or a bag.

(2) Step K202
The audio sensor 11 in the mobile terminal 10 senses the audio frequency emitted by the object and sends it to the sensor control unit 14.

(3) Step K203
Here, the sensor control unit 14 performs sampling and filtering of the audio frequency for a certain period of time.

(4) Step K204
When the sensor control unit 14 determines that the audio frequency is increasing, the sensor control unit 14 sends audio frequency data corresponding to the audio frequency to the terminal data processing unit 17.

(5) Step K205
Next, the terminal data processing unit 17 sends the audio frequency data to the profile management unit 16.

(6) Step K206
Here, the profile management unit 16 refers to the profile table 163 and searches for an alarm sound profile corresponding to the acquired sound frequency data.

(7) Step K211
The profile management unit 16 does not send the profile to the terminal data processing unit 17 when there is no profile (alarm display profile and alarm audio profile) corresponding to the acquired audio frequency data in the profile table 163. That is, externally, the profile management unit 16 limits the transmission of profiles to the terminal data processing unit 17.

(8) Step K212
As a result, the user continues to watch music without listening to the alarm sound. That is, the music player 20 continues the current operation.

The third embodiment of the present invention will be described below.
In this embodiment, the frequency of light (or electromagnetic waves) emitted from an object is detected instead of sound. That is, in the present invention, the frequency of other waves such as light (or electromagnetic waves) may be detected without being limited to sound. Note that it is preferable that all frequencies of sound, light, and electromagnetic waves can be detected because the approach of an object can be detected more reliably.

  For example, the mobile terminal 10 detects the frequency of light (or electromagnetic waves) emitted from an object, displays an alarm display on the user's mobile terminal 10, and sounds a sound.

  At this time, the mobile terminal 10 is equipped with a light (or electromagnetic wave) sensor. In this case, in each of the above-described embodiments (first and second embodiments), “sound sensor 11” is read as “light (or electromagnetic wave) sensor”, and “sound frequency” is “frequency of light (or electromagnetic wave)”. To read as That is, the audio sensor 11 is a detector that detects some wave.

The fourth embodiment of the present invention will be described below.
In the present embodiment, the reflection frequency of the sound or light (or electromagnetic wave) emitted from the mobile terminal 10 is detected. The reflection frequency of sound, light, and electromagnetic waves indicates the frequency when sound, light, and electromagnetic waves emitted from the mobile terminal 10 are reflected back to the object. Note that it is preferable that all the reflection frequencies of sound, light, and electromagnetic waves can be detected because the approach of an object can be detected more reliably.

  For example, the mobile terminal 10 generates sound and light (or electromagnetic waves), detects the frequency at which the sound and light (or electromagnetic waves) are reflected from an object, and sends an alarm display to the user's mobile terminal 10. To display the sound. At this time, the mobile terminal 10 is equipped with a device or a circuit that generates sound or light (or electromagnetic waves). For example, the mobile terminal 10 includes a speaker, a lighting device, an electromagnetic wave irradiation device, and the like. In this case, in each of the above-described embodiments (first and second embodiments), the “voice sensor 11” may include a speaker, a lighting device, an electromagnetic wave irradiation device, and the like.

  When the mobile terminal 10 detects a sound reflection frequency, “sound frequency” is read as “sound reflection frequency” in each of the above-described embodiments (first and second embodiments).

  When the mobile terminal 10 detects the reflection frequency of light (or electromagnetic waves), the mobile terminal 10 is equipped with a light (or electromagnetic wave) sensor. In this case, in each of the above-described embodiments (first and second embodiments), “sound sensor 11” is read as “light (or electromagnetic wave) sensor”, and “sound frequency” is “reflection frequency of light (or electromagnetic wave)”. "

The fifth embodiment of the present invention will be described below.
In the present embodiment, the mobile terminal 10 detects an earphone connection, incoming call, music playback, etc., and automatically activates an alarm notification function according to the present invention.

  For example, it is assumed that the mobile terminal 10 does not perform the operations of the above-described embodiments when the user does not use an earphone. The mobile terminal 10 automatically detects the connection of the earphone to the mobile terminal 10 itself, the incoming call, and the music playback, or the connection of the earphone to the music player 20 and the music playback automatically. The operation of each embodiment is performed.

  Note that the earphone receiver 13 and the user interface unit 15 (or the earphone receiver 23 and the user interface unit 25) detect the connection of the earphones and notify the terminal data processing unit 17 of the connection. In addition, music playback is detected by the terminal voice control unit 18 (or the terminal voice control unit 28) and notified to the terminal data processing unit 17. The terminal data processing unit 17 automatically performs the operations of the above-described embodiments in response to notification that the connection of the earphone or the music reproduction has been detected.

  Alternatively, the mobile terminal 10 automatically detects the connection of the earphone to the mobile terminal 10 itself, an incoming call, and music playback, or automatically detects the connection of the earphone to the music player 20 and music playback, as described above. You may make it start the application software for performing operation | movement of each embodiment.

  Note that the above-described embodiments can be implemented in combination.

  Finally, the characteristic function (processing means) of the portable terminal of the present invention will be described in detail.

  The sound frequency data processing means sends the sound frequency received from the sound sensor to the sound frequency determination means. The voice frequency data processing means sends the voice frequency paid out from the voice frequency table to the terminal data processing means. Furthermore, when the audio frequency data processing means receives the audio frequency non-transmission signal from the audio frequency determination means, nothing is transmitted to the terminal data processing means.

  The audio frequency determination means samples the audio frequency for a certain time from the audio frequency data processing means. When the frequency is increased, the audio frequency determination means determines that the object is approaching according to the principle of the Doppler effect, and delivers audio frequency data corresponding to the audio frequency emitted by the object based on the formula. The voice frequency table is commanded as follows. Further, the sound frequency determining means determines that the object is stationary or moving away according to the principle of the Doppler effect when the sampled sound frequency is constant (invariable) or decreases. An audio frequency non-transmission signal is transmitted to the audio frequency data processing means. This has the effect of reducing the annoyance of frequent alarm notifications to the user because the moving object is less dangerous. The sound frequency determination means also has a function of adjusting the sampling time and filtering the frequency band, and can determine only an object that generates a specific sound. As a result, it is possible to construct a system that issues an alarm only when a really dangerous object approaches and then comfortably views music.

  When the voice frequency table receives a command from the voice frequency determination means to send voice frequency data corresponding to the voice frequency, the voice frequency table sends voice frequency data corresponding to the voice frequency to the voice frequency data processing means.

  The profile management data processing means sends the audio frequency data received from the terminal data processing means to the profile determination means. The profile management data processing means sends the profile paid out from the profile table to the terminal data processing means. Further, the profile management data processing means sends nothing to the terminal data processing means when receiving the non-corresponding signal from the profile determination means.

  The profile determination unit receives the audio frequency data from the profile management data processing unit, and searches the profile table for a profile (alarm display profile and alarm audio profile) corresponding to the received audio frequency data. When there is a corresponding profile, the profile determination means instructs the profile table to send out the corresponding profile. If there is no corresponding profile, the profile determination means sends a non-corresponding signal to the profile management data processing means.

  When the profile table receives a command from the profile determination means to send the corresponding profile, the profile table sends the corresponding profile to the profile management data processing means.

  As described above, the present invention relates to an approaching object detection system and an alarm (warning) system when using an earphone.

  In the present invention, when a user is using an earphone on a mobile terminal and an external sound is blocked, when a person or an object that emits a sound approaches, a detection sensor built in the mobile terminal Detects the audio frequency.

  At this time, the mobile terminal automatically controls the volume (volume) of the sound being heard through the earphone, fades out (slowly decreases the volume), and sends an alarm sound to the user. Also, it is determined what kind of object is approaching due to the difference in audio frequency, and an alarm is notified on the screen of the portable terminal.

  In the present invention, the mobile terminal is provided with a part for detecting a change in frequency using the principle of the Doppler effect, and an alarm is issued only to an object whose sound frequency increases. Usually, when an object that transmits sound approaches, the sound frequency increases, and when the object moves away, the sound frequency decreases.

  By using the present invention, it is possible to eliminate a situation in which an alarm continues to be output every time the sound of an object is detected, and it is possible to more effectively notify an object of an alarm.

  Furthermore, it has a database that categorizes objects that emit sound for each frequency range to be detected, and provides information on the objects to the user. For example, a notification such as “an object that seems to be a car is approaching” is given by a voice and a display on the display 12.

  The present invention can be applied to a cellular phone having a data processing function and a communication function, or a portable information communication device in general.

  As mentioned above, although embodiment of this invention was explained in full detail, actually, it is not restricted to said embodiment, Even if there is a change of the range which does not deviate from the summary of this invention, it is included in this invention.

FIG. 1 is a block diagram showing a basic configuration of a mobile terminal according to the present invention. FIG. 2 is a block diagram illustrating a basic configuration of the sensor control unit. FIG. 3 is a block diagram showing the basic configuration of the profile management unit. FIG. 4 is a diagram illustrating a configuration example of a profile table. FIG. 5A is a flowchart illustrating an operation when the user receives an alarm notification for an object from the earphone and the display using the mobile terminal. FIG. 5B is a flowchart illustrating an operation when the user receives an alarm notification for an object from the earphone and the display using the mobile terminal. FIG. 6 is a flowchart showing the sound frequency determination operation in the sensor control unit. FIG. 7 is a flowchart showing the matching operation between the audio frequency, the alarm display profile, and the alarm audio profile in the profile management unit. FIG. 8 is a block diagram showing the basic configuration of the mobile terminal and music player of the present invention. FIG. 9A is a flowchart illustrating an operation when a user views an alarm sound of an object from an earphone of a music player using a mobile terminal. FIG. 9B is a flowchart showing an operation when the user views the alarm sound of the object from the earphone of the music player using the mobile terminal.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Portable terminal 11 ... Voice sensor 12 ... Display 13 ... Earphone receiver 14 ... Sensor control part 15 ... User interface part 16 ... Profile management part 17 ... Terminal data processing part 18 ... Terminal voice control part 19 ... Short distance communication part 20 ... Music player 23 ... Earphone receiver 25 ... User interface unit 27 ... Terminal data processing unit 28 ... Terminal voice control unit 29 ... Near field communication unit

Claims (19)

A detector that detects a wave frequency associated with an object that may be approaching;
Sensor control means for receiving the wave frequency from the detector, sampling the wave frequency for a predetermined time, and delivering wave frequency data corresponding to the wave frequency;
Profile management means for managing the profile of the object according to the wave frequency data;
When the wave frequency data is received from the sensor control means, it is sent to the profile management means to check whether there is a voice currently flowing through the earphone worn by the user, and the currently flowing voice is If there is, terminal data that performs a process for muting the sound that is currently being played and performs an alarm notification process for the user based on the profile when the profile is received from the profile management means A portable terminal comprising processing means. The mobile terminal according to claim 1,
The sensor control means includes
Wave frequency data processing means for receiving the wave frequency from the detector;
Receiving the wave frequency from the wave frequency data processing means, and wave frequency determination means for sampling the wave frequency for a certain period of time;
When receiving a command to send wave frequency data corresponding to the wave frequency from the wave frequency determining means, a wave frequency table for sending the wave frequency data corresponding to the wave frequency to the wave frequency data processing means A portable terminal. The mobile terminal according to claim 2,
When the sampled wave frequency is increased, the wave frequency determination unit determines that the object is approaching according to the principle of Doppler effect, and the wave frequency corresponding to the sampled wave frequency based on a formula When the wave frequency table is instructed to send data to the wave frequency data processing means, and the sampled wave frequency is not increased, it is determined that the object is not approaching according to the principle of Doppler effect. , Sending a wave frequency non-sending signal to the wave frequency data processing means,
When the wave frequency data processing means sends out the wave frequency delivered from the wave frequency table to the terminal data processing means and receives a wave frequency non-send signal from the wave frequency determination means, the terminal data processing means A portable terminal that restricts the transmission of wave frequency data to the. The mobile terminal according to any one of claims 1 to 3,
The profile management means includes
A profile table in which the wave frequency data and the profile are linked;
Receiving the wave frequency data from the terminal data processing means, sending out the profile paid out from the profile table to the terminal data processing means based on the wave frequency data, and there is a profile corresponding to the wave frequency data Without receiving a non-corresponding signal, profile management data processing means for restricting the transmission of the profile to the terminal data processing means,
The wave frequency data is received from the profile management data processing means, the profile table is searched for a profile corresponding to the wave frequency data, and if there is the corresponding profile, the corresponding profile is A portable terminal comprising: profile determination means for sending to a profile management data processing means and, if there is no corresponding profile, sending the non-corresponding signal to the profile management data processing means. The mobile terminal according to any one of claims 1 to 4,
The current voice is controlled, and when receiving a command to stop the current voice from the terminal data processing means, the current voice is faded out, and the profile is sent from the terminal data processing means. Terminal voice control means for sending alarm voice corresponding to the profile to the terminal data processing means,
When the profile is received from the terminal data processing means, an alarm display corresponding to the profile is displayed on a display, and when the alarm sound is received from the terminal data processing means, a user interface that sounds the alarm sound from the earphone A portable terminal further comprising a control means. A mobile terminal according to any one of claims 1 to 5,
When the profile is received from another portable terminal via a short-range communication line, the profile is sent to the terminal data processing means, and the user is currently flowing through the earphone of the other portable terminal A portable terminal further comprising short-range communication means for receiving the profile from the terminal data processing means and transmitting the profile to the other portable terminal via the short-range communication line when viewing audio. The mobile terminal according to any one of claims 1 to 6,
The portable detector detects at least one frequency among the frequencies of sound, light, and electromagnetic waves emitted from the object and the reflection frequency of sound, light, and electromagnetic waves with respect to the object as the wave frequency. An alarm notification method implemented by a mobile terminal,
Detecting a wave frequency associated with an object that may be approaching;
Sampling the wave frequency for a fixed time and delivering wave frequency data corresponding to the wave frequency;
When the wave frequency data is received, it is confirmed whether or not there is an audio currently flowing through an earphone worn by a user. If there is an audio that is currently flowing, the audio that is currently flowing is muted. Steps to perform the process to
Receiving the wave frequency data, paying out a profile of the object according to the wave frequency data;
Receiving the profile, and performing an alarm notification process for the user based on the profile. The alarm notification method according to claim 8, wherein
If the sampled wave frequency is increasing, it is determined that the object is approaching according to the principle of the Doppler effect, and wave frequency data corresponding to the sampled wave frequency is paid from the wave frequency table based on the formula. Step to issue,
If the sampled wave frequency is not increased, the step of determining that the object is not approaching according to the principle of the Doppler effect, generating a wave frequency non-transmission signal, and limiting the transmission of the wave frequency data is further included. Including alarm notification method. The alarm notification method according to claim 8 or 9, wherein
Referring to a profile table in which the wave frequency data and the profile are linked;
Receiving the wave frequency data and searching the profile table for a profile corresponding to the wave frequency data;
When there is the corresponding profile, paying out the profile corresponding to the wave frequency data from the profile table;
And a step of generating a non-corresponding signal and restricting the transmission of the profile when there is no corresponding profile. The alarm notification method according to any one of claims 8 to 10,
Controlling the currently flowing sound and fading out the currently flowing sound upon receiving a command to stop the currently flowing sound;
Receiving the profile, displaying an alarm indication corresponding to the profile on a display;
Receiving the profile, and further causing the alarm sound corresponding to the profile to ring from the earphone. The alarm notification method according to any one of claims 8 to 11,
When receiving the profile from another portable terminal via a short-range communication line, performing an alarm notification process for the user based on the received profile;
A step of sending the profile to the other mobile terminal via the short-range communication line when the user is viewing the currently flowing audio via the earphone of the other mobile terminal; Including alarm notification method. The alarm notification method according to any one of claims 8 to 12,
The wave notification frequency is at least one of a frequency of sound, light, and electromagnetic waves emitted from the object and a reflection frequency of sound, light, and electromagnetic waves with respect to the object. Detecting a wave frequency associated with an object that may be approaching;
Sampling the wave frequency for a fixed time and delivering wave frequency data corresponding to the wave frequency;
When the wave frequency data is received, it is confirmed whether or not there is an audio currently flowing through an earphone worn by a user. If there is an audio that is currently flowing, the audio that is currently flowing is muted. Steps to perform the process to
Receiving the wave frequency data, paying out a profile of the object according to the wave frequency data;
A program for causing a portable terminal to execute an alarm notification process for the user based on the profile when receiving the profile. The program according to claim 14, wherein
If the sampled wave frequency is increasing, it is determined that the object is approaching according to the principle of the Doppler effect, and wave frequency data corresponding to the sampled wave frequency is paid from the wave frequency table based on the formula. Step to issue,
If the sampled wave frequency is not increased, the step of determining that the object is not approaching according to the principle of the Doppler effect, generating a wave frequency non-transmission signal, and limiting the transmission of the wave frequency data is further included. A program to be executed by a mobile device. The program according to claim 14 or 15,
Referring to a profile table in which the wave frequency data and the profile are linked;
Receiving the wave frequency data and searching the profile table for a profile corresponding to the wave frequency data;
When there is the corresponding profile, paying out the profile corresponding to the wave frequency data from the profile table;
A program for causing a portable terminal to further execute a step of generating a non-corresponding signal and restricting transmission of a profile when there is no corresponding profile. A program according to any one of claims 14 to 16,
Controlling the currently flowing sound and fading out the currently flowing sound upon receiving a command to stop the currently flowing sound;
Receiving the profile, displaying an alarm indication corresponding to the profile on a display;
A program for causing a portable terminal to further execute a step of sounding an alarm sound corresponding to the profile from the earphone when the profile is received. A program according to any one of claims 14 to 17,
When receiving the profile from another portable terminal via a short-range communication line, performing an alarm notification process for the user based on the received profile;
A step of sending the profile to the other mobile terminal via the short-range communication line when the user is viewing the currently flowing audio via the earphone of the other mobile terminal; A program to be executed by a mobile device. A program according to any one of claims 14 to 18,
The wave frequency is at least one of a frequency of sound, light, and electromagnetic waves emitted from the object and a reflection frequency of sound, light, and electromagnetic waves with respect to the object.

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