JP2012095076A - Portable device, portable communication terminal, unpleasant sound generation detection method, and unpleasant sound generation detection program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a technique of detecting generation of unpleasant sounds caused by an event that a portable device vibrates while contacting with an external object.SOLUTION: A portable telephone 10 has: a portable telephone housing 11; a vibrator 12 generating the vibration in the portable telephone housing 11; an acceleration sensor 13 detecting the acceleration of the portable telephone housing 11 vibrated by the vibrator 12; a comparator 26 comparing the acceleration of the portable telephone housing 11 which is detected by the acceleration sensor 13 with a predetermined acceleration reference range stored in a ROM 22; and an unpleasant sound generation determination part 27 determining that the portable telephone housing 11 vibrates while contacting with an external object and unpleasant sounds are generated in the case that the acceleration of the portable telephone housing 11 which is detected by the acceleration sensor 13 deviates from the predetermined acceleration reference range, according to the comparison result of the comparator 26.

Description

  The present invention relates to a mobile device, a mobile communication terminal, an unpleasant sound occurrence detection method, and an unpleasant sound occurrence detection program.

  As this type of technology, Patent Document 1 discloses a mobile phone including a vibrator that performs incoming call notification by generating mechanical vibration. This mobile phone further includes a control unit that controls the intensity of mechanical vibration of the vibrator and a shake detection unit that detects the shake of the phone received from the external environment. When a radio wave directed to the own telephone arrives, the control unit controls the intensity of mechanical vibration of the vibrator based on the motion detection result output from the motion detection unit at the time of arrival. Here, “the shaking of the own phone” means “the shaking of the own phone caused by carrying by the user”.

  As a specific example, when the mobile phone is placed on a desk or the like, and the shaking of the own phone is not detected, the vibration intensity of the vibrator is set to be weak, and the vibrator vibrates weakly. As a result, when the mobile phone is placed on a desk, the vibrator vibrates weakly, so that vibration and vibration sound are reduced, and the annoyance is alleviated.

Japanese Patent Laid-Open No. 2004-236202

  The configuration of Patent Document 1 is advantageous in that it can prevent the generation of unpleasant sounds due to the vibration of the mobile phone.

  By the way, when the mobile phone is placed on a soft object such as a sofa, an unpleasant sound is hardly generated even if the vibrator vibrates strongly. Nevertheless, according to the configuration of Patent Document 1, the vibration intensity of the vibrator is set to be weak because the own telephone is not shaken. As a result, the user cannot notice the vibration of the vibrator. That is, there is a fundamental defect in the mechanism of Patent Document 1 that prevents the generation of unpleasant noise caused by the vibration of the mobile phone.

  The present invention has been made in view of the above circumstances, and its purpose is to prevent the generation of unpleasant noise caused by the mobile device vibrating while in contact with an external object. First, it is to provide a technique for detecting the generation of unpleasant sound caused by vibration of a mobile device while contacting an external object.

  According to the first aspect of the present invention, the mobile device is configured as follows. That is, the portable device includes a portable device main body, vibration generating means for generating vibration in the portable device main body, acceleration detecting means for detecting acceleration of the portable device main body that is vibrated by the vibration generating means, Comparison means for comparing the acceleration of the portable device main body detected by the acceleration detection means with a predetermined acceleration reference range, and the portable device main body detected by the acceleration detection means as a result of comparison by the comparison means An unpleasant sound generation determining means for determining that an unpleasant sound is generated when the mobile device body vibrates while contacting an external object when the acceleration of the mobile device is out of the predetermined acceleration reference range. .

  According to the second aspect of the present invention, the portable device is configured as follows. That is, the portable device includes a portable device main body, vibration generating means for generating vibration in the portable device main body, acceleration detecting means for detecting acceleration of the portable device main body that is vibrated by the vibration generating means, Comparing means for comparing the harmonics of the acceleration of the mobile device body detected by the acceleration detecting means with a predetermined harmonic reference range, and a result of comparison by the comparing means, detected by the acceleration detecting means When the harmonic of acceleration of the mobile device main body is out of the predetermined harmonic reference range, the mobile device main body vibrates while contacting an external object and determines that an unpleasant sound is generated. Generation determination means.

  According to the third aspect of the present invention, the unpleasant sound generation detection method includes the following steps. That is, the step of generating vibration in the mobile device body, the step of detecting the acceleration of the mobile device body being vibrated, the detected acceleration of the mobile device body, and a predetermined acceleration reference range are compared. If the detected acceleration of the mobile device body is out of the predetermined acceleration reference range as a result of this comparison, the mobile device body vibrates while contacting an external object, and an unpleasant sound is generated. A step of determining that there is.

  According to the fourth aspect of the present invention, the unpleasant sound generation detection method includes the following steps. That is, the step of generating vibration in the mobile device body, the step of detecting the acceleration of the mobile device body being vibrated, the detected harmonic of the mobile device body, and a predetermined harmonic reference range And when the detected harmonic of the mobile device body is out of the predetermined harmonic reference range, the mobile device body vibrates while contacting an external object. Determining that an unpleasant sound has occurred.

  According to a fifth aspect of the present invention, an unpleasant sound generation detection program causes a computer to generate a vibration in a mobile device body, a step of detecting an acceleration of the mobile device body being vibrated, and a detection Comparing the acceleration of the portable device body with a predetermined acceleration reference range, and if the result of this comparison indicates that the detected acceleration of the portable device body is outside the predetermined acceleration reference range, And a step of determining that an unpleasant sound is generated by the device body vibrating while contacting an external object.

According to a sixth aspect of the present invention, an unpleasant sound generation detection program causes a computer to generate a vibration in a mobile device body, a step of detecting an acceleration of the mobile device body being vibrated, and a detection The step of comparing the acceleration harmonics of the mobile device main body with a predetermined harmonic reference range, and as a result of this comparison, the detected harmonics of the acceleration of the mobile device main body is the predetermined harmonic reference range. If the mobile device main body vibrates while contacting an external object, the step of determining that an unpleasant sound is generated;
Is executed.

  According to the present invention, it is possible to detect that the portable device vibrates while contacting an external object and an unpleasant sound is generated.

FIG. 1 is a functional block diagram of a mobile phone. (First embodiment) FIG. 2 is a control flow of the mobile phone. (First embodiment) FIG. 3 is a graph showing an acceleration signal of the acceleration sensor in a normal state. (First embodiment) FIG. 4 is a graph showing an acceleration signal of the acceleration sensor when an unpleasant sound is generated. (First embodiment) FIG. 5 is a graph showing the frequency spectrum of the acceleration signal of the acceleration sensor at normal times. (First embodiment) FIG. 6 is a graph showing the frequency spectrum of the acceleration signal of the acceleration sensor when an unpleasant sound is generated. (First embodiment) FIG. 7 is a schematic configuration diagram of a mobile phone. (Second Embodiment)

(First embodiment)
Next, a first embodiment of the present invention will be described with reference to FIGS.

  A mobile phone 10 shown in FIG. 1 mainly includes a mobile phone casing 11 (mobile device main body, mobile phone main body), a vibrator 12, an acceleration sensor 13, a control unit 14, a radio unit 15, and an antenna 16. It is provided as a configuration.

  The control unit 14 includes a CPU 20 (Central Processing Unit), a RAM 21 (Random Access Memory), and a ROM 22 (Read Only Memory). The CPU 20 is a central arithmetic unit. The RAM 21 is a readable / writable storage means. The ROM 22 is a read-only storage unit. The ROM 22 stores a control program (unpleasant sound occurrence detection program). This control program is read by the CPU 20 and executed on the CPU 20, so that the hardware such as the CPU 20 is connected to the call incoming notification unit 23, the email incoming notification unit 24, the vibrator drive unit 25, the comparison unit 26, unpleasant sound. The generation determination unit 27 and the vibrator adjustment unit 28 function.

(Vibrator 12)
The vibrator 12 is a vibration generating unit that generates vibration in the mobile phone casing 11. The vibrator 12 is connected to the control unit 14. In this embodiment, the vibrator 12 is configured by a small DC motor having an eccentric weight attached to the output shaft. The vibrator 12 is driven by a vibrator driving unit 25 of the control unit 14.

(Acceleration sensor 13)
The acceleration sensor 13 is acceleration detecting means for detecting the acceleration of the mobile phone casing 11 that is vibrated by the vibrator 12. The acceleration sensor 13 is connected to the control unit 14. In the present embodiment, the acceleration sensor 13 is a capacitance type acceleration sensor, and the number of detection axes is three. However, instead of this, the acceleration sensor 13 may be another type such as a piezoresistive type, and the number of detection axes may be one if the direction of vibration is predetermined. The acceleration sensor 13 detects the acceleration of the mobile phone casing 11 that is vibrated by the vibrator 12, and converts the detected acceleration into a voltage value to generate an acceleration signal. The acceleration sensor 13 transmits the generated acceleration signal to the comparison unit 26 of the control unit 14.

(Radio unit 15, antenna 16)
The wireless unit 15 and the antenna 16 realize the communication function of the mobile phone 10. The wireless unit 15 is connected to the control unit 14. The antenna 16 is connected to the wireless unit 15. The radio unit 15 outputs a signal obtained by modulating data from the control unit 14 to the antenna 16, and transmits data obtained by demodulating the signal input from the antenna 16 to the control unit 14. The communication function standards of the mobile phone 10 include IMT-2000 (International Mobile Telecommunication 2000), GSM (Global System for Mobile Communications), PHS (Personal Handy-phone System), wireless LAN, Bluetooth (registered trademark), and the like. There is no particular limitation.

(Control unit 14: Call incoming notification unit 23)
The incoming call notification unit 23 is a incoming call notification unit that notifies the owner of the mobile phone 10 of an incoming call by driving the vibrator 12 via the vibrator driving unit 25. The incoming call notification unit 23 transmits a driving start command to the vibrator driving unit 25 to cause the vibrator driving unit 25 to start driving the vibrator 12.

(Control unit 14: Email incoming notification unit 24)
The incoming email notification unit 24 is an incoming email notification unit that notifies the owner of the mobile phone 10 of an incoming email by driving the vibrator 12 via the vibrator driving unit 25. The incoming e-mail notification unit 24 transmits a drive start command to the vibrator drive unit 25 to cause the vibrator drive unit 25 to start driving the vibrator 12.

(Control unit 14: vibrator driving unit 25)
The vibrator drive unit 25 is a vibrator drive unit that drives the vibrator 12 based on a drive start command from the incoming call notification unit 23 or the email incoming notification unit 24. When receiving a driving start command from the incoming call notification unit 23 or the email incoming notification unit 24, the vibrator drive unit 25 reads the rotational speed data of the vibrator 12 stored in the RAM 21 and supplies a voltage corresponding to the rotational speed data to the vibrator. 12 is supplied.

(Control unit 14: comparison unit 26)
The comparison unit 26 is a comparison unit that compares the acceleration of the mobile phone casing 11 detected by the acceleration sensor 13 with a predetermined acceleration reference range. The predetermined acceleration reference range is a range that serves as a reference for the magnitude (voltage value) of acceleration. The predetermined acceleration reference range is stored in the ROM 22 in advance. The comparison unit 26 reads and acquires a predetermined acceleration reference range from the ROM 22. Further, the comparison unit 26 receives an acceleration signal from the acceleration sensor 13. The comparison unit 26 acquires the acceleration of the mobile phone casing 11 detected by the acceleration sensor 13 based on the received acceleration signal. Please refer to FIG. 3 and FIG. 4 for reference. 3 and 4 show the acceleration waveform of the mobile phone casing 11 detected by the acceleration sensor 13.

(Control unit 14: Unpleasant sound generation determination unit 27)
When the acceleration of the mobile phone casing 11 detected by the acceleration sensor 13 falls outside a predetermined acceleration reference range as a result of the comparison by the comparison section 26, the unpleasant sound generation determination unit 27 determines that the mobile phone casing 11 is an external object. It is an unpleasant sound generation determination means for determining that an unpleasant sound is generated by vibrating while touching. Here, the external object means a relatively hard object such as a desk or chair. The phrase “the mobile phone casing 11 is in contact with an external object” includes, for example, the case where “the mobile phone 10 is left on a desk or chair”.

(Control unit 14: vibrator adjustment unit 28)
The vibrator adjusting unit 28 is a vibration intensity adjusting unit that reduces the intensity of vibration generated by the vibrator 12 in the mobile phone housing 11 when the unpleasant sound generation determining unit 27 determines that an unpleasant sound is generated. In the present embodiment, the “vibration intensity” has a positive correlation with the “voltage supplied to the vibrator 12”. Therefore, the vibrator adjusting unit 28, when the unpleasant sound generation determining unit 27 determines that an unpleasant sound is generated, the vibrator driving unit in order to reduce the intensity of vibration generated by the vibrator 12 in the mobile phone casing 11. A voltage drop signal is transmitted to 25. When receiving the voltage drop signal from the vibrator adjusting unit 28, the vibrator driving unit 25 reduces the voltage supplied to the vibrator 12 by, for example, 10%.

(Operation)
Next, the operation of the mobile phone 10 will be described with reference to FIG. First, when the mobile phone 10 is turned on (S300), the control unit 14 enters a state of waiting for an incoming call and an incoming e-mail (S310: NO, S320: NO). In this state, when there is an incoming call (S310: YES), the incoming call notification unit 23 causes the vibrator drive unit 25 to drive the vibrator 12 (S330). Similarly, if an e-mail is received in this state (S320: YES), the e-mail incoming notification unit 24 causes the vibrator drive unit 25 to drive the vibrator 12 (S330). At this time, the vibrator 12 vibrates relatively smoothly at a low frequency of about 100 Hz. As described above, the vibration frequency of the vibrator 12 is close to the lower limit of the human audible band, and the auditory sensitivity is low. Therefore, the vibration sound of the vibrator 12 is usually hardly audible to the owner of the mobile phone 10.

  Next, the comparison unit 26 reads and acquires a predetermined acceleration reference range from the ROM 22 (S340). Further, the comparison unit 26 receives an acceleration signal from the acceleration sensor 13 (S350). Then, the comparison unit 26 compares the acceleration of the mobile phone casing 11 detected by the acceleration sensor 13 with a predetermined acceleration reference range (S360).

  Next, when the acceleration of the mobile phone casing 11 detected by the acceleration sensor 13 is outside the predetermined acceleration reference range as a result of the comparison by the comparison unit 26, the unpleasant sound generation determination unit 27 (S370: YES) Then, it is determined that the mobile phone case 11 vibrates while being in contact with an external object, and an unpleasant sound is generated (S380).

  Then, when the unpleasant sound generation determination unit 27 determines that an unpleasant sound is generated (S380), the vibrator adjustment unit 28 reduces the intensity of vibration generated by the vibrator 12 in the mobile phone casing 11 (S390). . Specifically, when the unpleasant sound generation determination unit 27 determines that an unpleasant sound is generated (S380), the vibrator adjustment unit 28 reduces the intensity of vibration generated by the vibrator 12 in the mobile phone casing 11. Therefore, a voltage drop signal is transmitted to the vibrator drive unit 25 (S390). When receiving the voltage drop signal from the vibrator adjusting unit 28, the vibrator driving unit 25 reduces the voltage supplied to the vibrator 12 by, for example, 10%. As a result, the rotational speed of the output shaft of the vibrator 12 decreases by about 8 to 12%. And the control part 14 returns a process to S350.

  On the other hand, in S370, if the acceleration of the mobile phone casing 11 detected by the acceleration sensor 13 is not out of the predetermined acceleration reference range as a result of the comparison by the comparison unit 26 (S370: NO), the control unit 14 The process is terminated (S400).

(Theory of detection)
Next, the reason why it is possible to detect that the mobile phone 10 vibrates while contacting an external object and an unpleasant sound is generated by the above control flow will be described.

(Theory of detection: Normal: Fig. 3)
FIG. 3 shows an acceleration signal of the acceleration sensor 13 in a normal state in the present embodiment. As shown in FIG. 3, the acceleration signal output from the acceleration sensor 13 has a waveform that is relatively close to a sine wave during normal times. This is because the vibrator 12 is configured by attaching an eccentric weight to the output shaft of the small motor. During vibration, the weight moves in a circle, and the reaction force of this movement acts on the mobile phone casing 11. This is because the mobile phone case 11 vibrates.

  Strictly speaking, however, the acceleration signal output from the acceleration sensor 13 has a waveform slightly deviating from the sine wave. This is because the acceleration signal includes a nonlinear component. The cause of this “non-linear component” is an elastic body such as a rubber sheet provided at a contact portion between the mobile phone casing 11 and the vibrator 12.

(Theory of detection: When unpleasant noise occurs: Fig. 4)
FIG. 4 shows an acceleration signal of the acceleration sensor 13 when an unpleasant sound is generated in the present embodiment. As shown in FIG. 4, the acceleration signal output from the acceleration sensor 13 has a waveform in which a natural waveform such as a shock wave is superimposed on a sine wave for each period when an unpleasant sound is generated. This is because when the mobile phone casing 11 is vibrated in a state where it is placed on a hard surface such as a desk, the mobile phone casing 11 repeatedly touches and separates from the hard surface. As a result, the mobile phone casing 11 This is because an impact that shakes the whole is generated.

(Theory of detection: Summary)
It should be noted that the amplitude of the acceleration signal output from the acceleration sensor 13 is larger when the unpleasant sound is generated than when it is normal, as can be seen by comparing FIG. 3 and FIG. This is because, as described above, an intrinsic waveform such as a shock wave is superimposed on the acceleration signal output from the acceleration sensor 13 when an unpleasant sound occurs. Therefore, as shown in FIG. 3, an acceleration reference range (reference A) that completely includes the normal acceleration signal is prepared in advance, and the acceleration signal output from the acceleration sensor 13 is converted to the acceleration reference range (reference A). If it is monitored as shown in FIG. 4 that the mobile phone 10 is within the range, it is possible to detect that the mobile phone 10 vibrates while contacting an external object and an unpleasant sound is generated.

  The preferred first embodiment of the present invention has been described above. In short, the first embodiment has the following features.

  That is, the mobile phone 10 is vibrated by the mobile phone casing 11 (mobile device main body, mobile phone main body), the vibrator 12 (vibration generating means) that generates vibration in the mobile phone casing 11, and the vibrator 12. The acceleration sensor 13 (acceleration detecting means) for detecting the acceleration of the mobile phone housing 11 is compared with the acceleration of the mobile phone housing 11 detected by the acceleration sensor 13 and the acceleration reference range stored in the ROM 22. As a result of comparison between the comparison unit 26 (comparison means) and the comparison unit 26, when the acceleration of the mobile phone casing 11 detected by the acceleration sensor 13 is out of the acceleration reference range, the mobile phone casing 11 is not an external object. An unpleasant sound generation determination unit 27 (unpleasant sound generation determination unit) that determines that an unpleasant sound is generated while vibrating while in contact is provided.According to the above configuration, it is possible to detect that the mobile phone 10 vibrates while being in contact with an external object and an unpleasant sound is generated.

  If it adds, according to the above structure, even if the surrounding environment of the mobile phone 10 is noisy, the mobile phone 10 vibrates while in contact with an external object, and an unpleasant sound is generated. Can be detected. This is because unpleasant sounds are not directly detected using a microphone or the like.

  Further, when the unpleasant sound generation determination unit 27 determines that an unpleasant sound is generated, the vibrator adjusting unit 28 (vibration intensity adjusting unit) that reduces the intensity of vibration generated by the vibrator 12 in the mobile phone casing 11 is further provided. I have. According to the above configuration, an unpleasant sound generated when the mobile phone casing 11 vibrates while contacting an external object is weakened.

  In addition, the mobile phone 10 includes a wireless unit 15 and an antenna 16 as communication means.

  In addition, the method for detecting the generation of unpleasant noise includes the steps of generating vibrations in the mobile phone housing 11 (S330), and detecting the acceleration of the mobile phone housing 11 being vibrated (S350). The step of comparing the acceleration of the mobile phone casing 11 and the acceleration reference range (S360, S370), and when the detected acceleration of the mobile phone casing 11 deviates from the predetermined acceleration reference range as a result of this comparison And (S380) determining that the mobile phone casing 11 vibrates while contacting an external object and an unpleasant sound is generated.

  Although the preferred first embodiment of the present invention has been described above, the first embodiment can be modified as follows, for example.

  Note that the mobile device is not limited to the mobile phone 10 and includes, for example, a pager as a mobile communication terminal, a PDA (Personal Digital Assistant), and the like.

  In the first embodiment, the acceleration signal output from the acceleration sensor 13 is monitored in order to detect that the mobile phone 10 vibrates while contacting an external object and an unpleasant sound is generated. . However, instead of this, harmonics of the acceleration signal output from the acceleration sensor 13 may be monitored. The reason is as follows. FIG. 5 shows a frequency spectrum generated by performing FFT processing on the acceleration signal output from the acceleration sensor 13 at the normal time in the first embodiment. FIG. 6 shows a frequency spectrum generated by performing FFT processing on the acceleration signal output from the acceleration sensor 13 when unpleasant sound is generated in the first embodiment. As can be seen by comparing FIG. 5 and FIG. 6, the natural waveform such as the shock wave described above tends to appear as a harmonic of a sine wave that is a fundamental wave of vibration by the vibrator 12. Therefore, if the harmonics of the acceleration signal output from the acceleration sensor 13 are compared with a harmonic reference range (predetermined harmonic reference range) as indicated by hatching in FIGS. The reason is that it is possible to detect that an unpleasant sound is generated while vibrating. Specifically, if the harmonics of the acceleration signal output from the acceleration sensor 13 are out of a predetermined harmonic reference range as shown by hatching in FIG. 6, the mobile phone 10 vibrates while contacting an external object. An unpleasant sound is generated. In addition, the harmonic reference range here is a range that serves as a reference for the magnitude (voltage value) of the harmonic.

  Further, as an idea derived from the above thinking process, in order to more clearly grasp the inherent waveform such as the shock wave described above, the acceleration signal output from the acceleration sensor 13 is a high-pass filter that emphasizes the high frequency band. The above-described comparison may be performed after processing in advance.

  Further, in the first embodiment, when the vibrator adjustment unit 28 determines that an unpleasant sound is generated by the unpleasant sound generation determination unit 27 (S380), the vibrator 12 generates vibrations that the mobile phone casing 11 generates. In order to reduce the strength, a voltage drop signal is transmitted to the vibrator drive unit 25 (S390). When receiving the voltage drop signal from the vibrator adjusting unit 28, the vibrator driving unit 25 reduces the voltage supplied to the vibrator 12 by, for example, 10%. However, in addition to this, the vibrator adjustment unit 28 may be configured to transmit the voltage drop signal at predetermined time intervals. Here, the “predetermined time interval” is, for example, 0.1 seconds.

  Alternatively, the vibrator drive unit 25 may reduce the voltage supplied to the vibrator 12 by, for example, 50% when receiving the voltage drop signal from the vibrator adjustment unit 28.

  Alternatively, the vibrator driving unit 25 may reduce the voltage supplied to the vibrator 12 by, for example, 20% when receiving the voltage drop signal from the vibrator adjusting unit 28.

  As described above, when the unpleasant sound generation determination unit 27 determines that an unpleasant sound is generated, it is arbitrary how the voltage supplied to the vibrator 12 is reduced. For example, the manner in which the voltage supplied to the vibrator 12 is lowered may be found experimentally so that the owner of the mobile phone 10 does not feel uncomfortable, or a certain learning function is provided in the CPU 20 of the control unit 14 in the past. You may be made to choose adaptively from the data.

  Further, in this embodiment, the acceleration reference range is treated as a concept having an upper limit and a lower limit as shown in FIGS. 3 and 4, but instead, the acceleration reference range is handled as a concept having only an upper limit. Alternatively, it may be handled as a concept having only a lower limit. In short, when detecting the occurrence of an unpleasant sound, the magnitude of the absolute value of acceleration is a problem, and there is no problem if that point is clear. That is, as shown in FIGS. 3 and 4, when both positive acceleration and negative acceleration are expressed using a positive voltage, an uncomfortable sound can be obtained even if the acceleration reference range is treated as a concept having only a lower limit. This means that it may be possible to detect the occurrence of.

(Second Embodiment)
Next, a second embodiment of the present invention will be described with reference to FIG. Here, the present embodiment will be described with a focus on differences from the first embodiment, and overlapping descriptions will be omitted as appropriate. In addition, in principle, the same reference numerals are assigned to components corresponding to the respective components of the first embodiment.

  As shown in FIG. 7, in this embodiment, the mobile phone 10 includes a mobile phone housing 11 and a vibrator 12, an acceleration sensor 13, a control unit 14, a radio unit 15, an antenna 16, a voltage limiting circuit 30 (vibration intensity adjusting means). The voltage detection circuit 31 (comparison means, unpleasant sound generation determination means) is configured.

  The control unit 14 includes a CPU 20, a RAM 21, and a ROM 22. When the control program stored in the ROM 22 is executed on the CPU 20, the control program causes hardware such as the CPU 20 to function as a call incoming notification unit 23, an email incoming notification unit 24, and a vibrator drive unit 25.

  In the present embodiment, the vibrator 12 is connected to the control unit 14 via the voltage limiting circuit 30. The acceleration sensor 13 is connected to the voltage limiting circuit 30 through the voltage detection circuit 31.

  The vibrator driving unit 25 of the control unit 14 supplies a desired voltage to the voltage limiting circuit 30.

  The voltage limiting circuit 30 supplies a voltage to the vibrator 12 based on the voltage supplied from the vibrator driving unit 25 of the control unit 14 and the voltage drop signal received from the voltage detection circuit 31. When the voltage limiting circuit 30 cannot receive the voltage drop signal from the voltage detection circuit 31, the voltage limiting circuit 30 supplies the voltage supplied from the vibrator driving unit 25 of the control unit 14 to the vibrator 12 as it is. On the other hand, while receiving the voltage drop signal from the voltage detection circuit 31, the voltage limiting circuit 30 slightly reduces the voltage supplied from the vibrator driving unit 25 of the control unit 14, and then reduces the voltage to the vibrator 12. To supply.

  The acceleration sensor 13 detects the acceleration of the mobile phone casing 11 that is vibrated by the vibrator 12, and converts the detected acceleration into a voltage value to generate an acceleration signal. The acceleration sensor 13 transmits the generated acceleration signal to the voltage detection circuit 31.

  The voltage detection circuit 31 is configured by a general comparator. The voltage detection circuit 31 transmits a voltage drop signal to the voltage limiting circuit 30 when the acceleration signal output from the acceleration sensor 13 is out of a predetermined acceleration reference range. On the other hand, the voltage detection circuit 31 does not transmit a voltage drop signal to the voltage limiting circuit 30 if the acceleration signal output from the acceleration sensor 13 is not outside the predetermined acceleration reference range.

  In short, in the first embodiment, the comparison unit, the unpleasant sound generation determination unit, and the vibration intensity adjustment unit are realized by software. That is, the comparison unit is realized by the comparison unit 26, the unpleasant sound generation determination unit is realized by the unpleasant sound generation determination unit 27, and the vibration intensity adjustment unit is realized by the vibrator adjustment unit 28. On the other hand, in this embodiment, the comparison unit, the unpleasant sound generation determination unit, and the vibration intensity adjustment unit are realized in hardware. That is, the comparison means and the unpleasant sound generation determination means are realized by the voltage detection circuit 31, and the vibration intensity adjustment means is realized by the voltage limiting circuit 30. As described above, the comparison unit, the unpleasant sound generation determination unit, the vibration intensity adjustment unit, and the like may be realized in software or in hardware.

  Finally, the control program described above can be stored and supplied to a computer using various types of non-transitory computer readable media. Non-transitory computer readable media include various types of tangible storage media. Examples of non-transitory computer-readable media include magnetic recording media (for example, flexible disks, magnetic tapes, hard disk drives), magneto-optical recording media (for example, magneto-optical disks), CD-ROMs (Read Only Memory), CD-Rs, CD-R / W and semiconductor memory (for example, mask ROM, PROM (Programmable ROM), EPROM (Erasable PROM), flash ROM, RAM (random access memory)) are included. The program may also be supplied to the computer by various types of transitory computer readable media. Examples of transitory computer readable media include electrical signals, optical signals, and electromagnetic waves. The temporary computer-readable medium can supply the program to the computer via a wired communication path such as an electric wire and an optical fiber, or a wireless communication path.

DESCRIPTION OF SYMBOLS 10 Mobile phone 11 Mobile phone case 12 Vibrator 13 Acceleration sensor 14 Control part 25 Vibrator drive part 26 Comparison part 27 Unpleasant sound generation determination part 28 Vibrator adjustment part

Claims (8)

A mobile device body;
Vibration generating means for generating vibration in the portable device body;
Acceleration detecting means for detecting the acceleration of the mobile device body that is vibrated by the vibration generating means;
A comparison means for comparing the acceleration of the mobile device body detected by the acceleration detection means with a predetermined acceleration reference range;
As a result of the comparison by the comparison means, if the acceleration of the mobile device body detected by the acceleration detection means is out of the predetermined acceleration reference range, the mobile device body vibrates while in contact with an external object. An unpleasant sound generation determination means for determining that a nuisance sound is generated;
With
Mobile device. A mobile device body;
Vibration generating means for generating vibration in the portable device body;
Acceleration detecting means for detecting the acceleration of the mobile device body that is vibrated by the vibration generating means;
Comparison means for comparing the harmonics of the acceleration of the mobile device body detected by the acceleration detection means with a predetermined harmonic reference range;
As a result of comparison by the comparison means, when the harmonic of the acceleration of the mobile device main body detected by the acceleration detection means is out of the predetermined harmonic reference range, the mobile device main body is in contact with an external object. An unpleasant sound generation determination means for determining that an unpleasant sound is generated by vibration;
With
Mobile device. The portable device according to claim 1 or 2,
When the unpleasant sound occurrence determining means determines that an unpleasant sound is generated, the vibration generating means further includes a vibration intensity adjusting means for reducing the intensity of vibration generated in the portable device body,
Mobile device. The portable communication terminal as a portable device according to any one of claims 1 to 3, comprising a communication means. Generating vibration in the mobile device body;
Detecting the acceleration of the mobile device body being vibrated;
Comparing the detected acceleration of the mobile device body with a predetermined acceleration reference range;
As a result of the comparison, if the detected acceleration of the mobile device body is out of the predetermined acceleration reference range, it is determined that the mobile device body vibrates while contacting an external object and an unpleasant sound is generated. And steps to
including,
Unpleasant sound generation detection method. Generating vibration in the mobile device body;
Detecting the acceleration of the mobile device body being vibrated;
Comparing the detected acceleration harmonics of the mobile device body with a predetermined harmonic reference range;
As a result of this comparison, when the detected harmonic of the mobile device body is out of the predetermined harmonic reference range, the mobile device body vibrates while contacting an external object, and an unpleasant sound is generated. A step of determining that
including,
Unpleasant sound generation detection method. On the computer,
Generating vibration in the mobile device body;
Detecting the acceleration of the mobile device body being vibrated;
Comparing the detected acceleration of the mobile device body with a predetermined acceleration reference range;
As a result of the comparison, if the detected acceleration of the mobile device body is out of the predetermined acceleration reference range, it is determined that the mobile device body vibrates while contacting an external object and an unpleasant sound is generated. And steps to
To execute,
Unpleasant sound detection program. On the computer,
Generating vibration in the mobile device body;
Detecting the acceleration of the mobile device body being vibrated;
Comparing the detected acceleration harmonics of the mobile device body with a predetermined harmonic reference range;
As a result of this comparison, when the detected harmonic of the mobile device body is out of the predetermined harmonic reference range, the mobile device body vibrates while contacting an external object, and an unpleasant sound is generated. A step of determining that
To execute,
Unpleasant sound detection program.

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