JP2009080219A - Level adjustment determination device, method, and program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To accurately determine whether the amplitude of waveform of an input signal is larger or smaller. <P>SOLUTION: A level L of the input signal is calculated (102, S2), and whether or not the level L is equal to or larger than/or larger than a first threshold A<SB>max</SB>is determined (104, S4). When the level L is determined to be equal to or larger than/or larger than the first threshold A<SB>max</SB>, a threshold large time T<SB>H</SB>that is the total time of time when the level L is equal to or larger than/or larger than the first threshold A<SB>max</SB>within a past predetermined determination time T<SB>f</SB>is calculated (108, S8), and a threshold large average level M<SB>H</SB>that is an additive average for the levels equal to or larger than/or larger than the first threshold A<SB>max</SB>is calculated using the threshold large time T<SB>H</SB>(112, S10). Whether or not the threshold maximum average level is equal to or larger than/or larger than a predetermined second threshold B<SB>max</SB>is determined (116, S12), and an adjustment instruction signal for adjusting the level of the input signal according to this determination result is generated (124, S14 and S16). <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to, for example, a level adjustment determination apparatus that automatically determines an adjustment amount of a level of an input signal, a method thereof, and a program thereof.

  When an input voice signal is recognized by, for example, a voice recognition system, it may be desired to use the voice signal after adjusting the level of the voice signal, that is, the volume (waveform amplitude level) within an appropriate fixed range. As a conventional method for automatically adjusting the level of the input voice, the level of the input voice (eg, “power” or “power” within a predetermined time in the past (hereinafter referred to as “determination time”) is used. The arithmetic average value of “absolute amplitude value”) is calculated as the average level. A general method is to adjust the level when the average level is above or below a predetermined threshold. This technique is called prior art 1.

  There is also a technique of simply observing the amplitude of an audio signal or the audio signal of a low frequency part and increasing the level of the audio signal if the amplitude is small and decreasing the level of the audio signal if the amplitude is large. Details of this technique are described in Patent Document 1, and this technique is referred to as Conventional Technique 2.

There is also a method of automatically adjusting so that the volume of sound output from the speaker can be heard at a certain level by determining the volume of the sound volume from the volume of background noise. Details of this technique are described in Patent Document 2, and this technique is referred to as Conventional Technique 3.
JP 2004-328699 A JP 2006-165865 A

FIG. 1 shows a waveform of an input voice signal F (t) when the level adjustment determination device of the prior art 1 is used (hereinafter also referred to as “voice waveform”). However, the horizontal axis represents time, and the vertical axis represents the amplitude value. FIG. 1 also shows an average level G corresponding to the waveform calculated by the level adjustment determination device of the prior art 1. The upper limit A _max and the lower limit A _min of the average level for the average level G are determined in advance. If the average level G is greater than the upper limit A _max , it is determined that the volume of the sound within the determination time is excessive. . The audio volume within the determination time if less than the average level G is lower A _min is determined to be too small. The input audio signal F (t) shown in FIG. 1 has a waveform in which an extremely large amplitude waveform (such as a clipped state) and a small waveform amplitude alternately exist in a short time interval within the determination time. And the amplitude of F (t) is excessive as a whole. The average level G is an arithmetic mean at the determination time T _f (t _{1 to} t ₂ ) as described above. t ₂ is than _{t 1} represents the past of time. Further, it is preferable that t ₁ is the current time and t ₁ = 0. Therefore, the average level G is obtained by the following formula.

In the case of the waveform of the audio signal of FIG. 1, as compared when determining the average level G in the calculation of the equation (1), the average level G, as described FIG. 1, the waveform is an extremely large amplitude value L ₁ Become smaller. Then, it is determined level too small in the section alpha _1, level interval alpha ₂ is determined to be excessive. Therefore, although the waveform of the audio signal F (t) is actually excessive as a whole, the level adjustment determination device of the prior art 1 determines that it is excessive only in the section α ₂ and the waveform of the audio signal F (t). Is not judged to be excessive as a whole. As described above, the level adjustment determination apparatus according to the related art 1 can roughly determine the magnitude of the amplitude at a relaxed speed when the waveform of the input audio signal is always excessive or always excessive. However, in the case of the waveform shown in FIG. 1, the magnitude of the amplitude cannot be determined, and as a result, there is a problem that it is difficult to automatically adjust the volume accurately.

Next, as shown in FIG. 2, consider a case where the amplitude of the waveform of the input audio signal F (t) is excessive only in a certain portion (section α _{3 in} FIG. 2). FIG. 2 also shows an average level G in the case where the level adjustment determination device of the prior art 1 is used for the audio signal F (t) shown in FIG. The method for obtaining the average level G is obtained by the above equation (1). As shown in FIG. 2, even within the time interval alpha _3, the average level G, the waveform is smaller than the extremely large amplitude value L _1, it is determined to be between A _max and A _min . Therefore, the related art 1 has a problem that when the amplitude of the voice waveform is partially excessive (or excessively small), it cannot be determined as excessive (or excessively small). Further, even in the prior art 2 and the prior art 3, as in the above-described reason, it cannot be determined whether the amplitude of the speech waveform is excessive or small.

  An object of the present invention is to provide a level adjustment determination apparatus, a method thereof, and a program thereof for accurately determining whether the amplitude of an audio waveform is excessively large or small, regardless of the amplitude of any speech waveform. .

  The level adjustment determination device of the present invention includes a signal level calculation unit, a first determination unit, a threshold large time calculation unit, a threshold large average level calculation unit, a second determination unit, and an adjustment command signal generation unit. Prepare. The signal level calculation unit calculates the level of the input signal. The first determination unit determines whether the level is greater than or equal to a predetermined first threshold value or greater than the first threshold value. When it is determined that the level is greater than or equal to the first threshold value or greater than the first threshold value, the threshold large time calculation unit has the level greater than or equal to the first threshold value or greater than the first threshold value within a past predetermined determination time. The threshold large time which is the total time is calculated. The threshold large average level calculation unit uses the threshold large time to calculate a threshold large average level that is an arithmetic average for a level equal to or greater than the first threshold or greater than the first threshold. The second determination unit determines whether or not the threshold large average level is greater than or equal to a predetermined second threshold or greater than the second threshold. The adjustment command signal generation unit generates and outputs an adjustment command signal for adjusting the level of the input signal according to the determination result of the second determination unit.

  The level adjustment determination apparatus of the present invention includes a signal level calculation unit, a fourth determination unit, a threshold small time calculation unit, a threshold small average level calculation unit, a fifth determination unit, and an adjustment command signal generation unit. , May be provided. The signal level calculation unit calculates the level of the input signal. The fourth determination unit determines whether the level is equal to or lower than a predetermined fourth threshold value or smaller than the fourth threshold value. When it is determined that the level is equal to or lower than the fourth threshold value or less than the fourth threshold value, the threshold small time calculation unit determines that the level is equal to or lower than the fourth threshold value or the fourth threshold value within a past predetermined determination time. The threshold small time which is the total time of the smaller time is calculated. The threshold small average level calculation unit uses the threshold small time to calculate a threshold small average level that is an arithmetic average of levels equal to or lower than the fourth threshold or smaller than the fourth threshold. The fifth determination unit determines whether or not the threshold small average level is equal to or lower than a predetermined fifth threshold or smaller than the fifth threshold. The adjustment command signal generation unit generates and outputs an adjustment command signal for adjusting the level of the input signal according to the determination result of the fifth determination unit.

  With the above configuration, it is possible to accurately determine whether the amplitude is excessively large or small, regardless of the waveform of the input signal.

  The best mode for carrying out the invention will be described below. In addition, the same number is attached | subjected to the process which performs the structure part which has the same function, and the same process, and duplication description is abbreviate | omitted. In the following description, an input signal is described as an audio signal.

  FIG. 3 shows a configuration example when the level adjustment determination apparatus of the present invention is implemented. The voice input unit 2 is, for example, a headset with a microphone and a microphone amplifier. The voice input unit 2 includes an adjusting unit 22 that adjusts the level (volume) of the input voice. The adjustment means 22 adjusts the level according to an adjustment command signal from the level adjustment determination device 4 described later. The application 6 is, for example, a voice recognition system. As an example of a situation where the level adjustment determination device is used, an operator (human) wears the voice input unit 2 (headset) and emits voice to the microphone. When the sound is input to the level adjustment determination device 4, the level adjustment determination device 4 generates an adjustment command signal for causing the input sound signal to have an appropriate level. Output to the adjusting means 22. The method for generating the adjustment command signal will be described in detail later. Then, the voice signal that has reached an appropriate level by the adjusting means 22 is input to the application 6 (voice recognition system), and voice recognition processing and the like are performed. Hereinafter, a method for generating an adjustment command signal by the level adjustment determination device 4 will be described. The application 6 is not limited to a voice recognition device.

FIG. 4 shows a functional configuration example of the level adjustment determination device 4-1 of the first embodiment, and FIG. 5 shows a main processing flow of the level adjustment determination device 4-1. First, the signal level calculation unit 102 calculates the level L of the audio signal F (t) (step S2). Here, the level L is, for example, the amplitude absolute value | F (t) | and power | (F (t)) ² | of the input voice.

The first determination unit 104 determines, determines whether the first threshold value A _max over the level L is predetermined or, if the first threshold value A _max is greater than or not the level L reaches a predetermined ( Step S4). In the following description, these may be collectively referred to as “whether or not greater than or equal to the first threshold value”. The first threshold A _max is stored in the first threshold storage unit 106 in advance.

When it is determined that the level L is greater than or equal to the first threshold value A _max , the large threshold time calculation unit 108 determines that the level L is the first within the past predetermined determination time T _f (t _{1 to} t ₂ ). calculating a first threshold value _{a max} or / is the total time of time greater than a threshold amount of time _{T H} (step S6). Further, it is preferable that t ₁ is the current time and t ₁ = 0. The calculated threshold amount of time T _H, once, it is preferable to store the threshold amount of time storage unit 110. Threshold amount of time calculating unit 108, when the level L is determined to less than / less than the first threshold value A _max, not calculated threshold amount of time T _H.

Threshold large average level computing unit 112 uses a threshold amount of time _{T H,} calculates a threshold large mean level _{M H} is the arithmetic mean of the first threshold value _{A max} or / greater level L (step S10). Specifically, the threshold large average level _MH can be expressed by the following equation.

The numerator of the formula (2) indicates that the level L is integrated at a time interval greater than or equal to the threshold large average level _MH , and the sum thereof is calculated within the determination time _Tf . Threshold large mean level M _H is once may be stored in the threshold larger average level storage unit 114.

The second determination unit 116 determines whether or not the threshold large average level _MH is greater than or equal to a predetermined second threshold B _max, or determines whether or not it is greater than a predetermined second threshold B _max. (Step S12). If the second determination unit 116 determines that _MH is not greater than or _equal to B _max or is not greater than B _max , it is determined that the level L is a little larger, and the adjustment command signal generation unit 124 receives the level L of the input signal. An adjustment command signal is generated so as to slightly lower (step S14). If the second determination unit 116 determines that _MH is _{equal to} or higher than B _max or greater than B _max , the second determination unit 116 determines that the level L is considerably high, and causes the adjustment command signal generation unit 124 to input the level L of the input signal. An adjustment command signal is generated so as to significantly lower (step S16). As described above, the adjustment command signal generation unit 124 generates and outputs an adjustment command signal for adjusting the level L of the input signal according to the determination result of the second determination unit 116. The output adjustment command signal is input to the adjustment means 22 (see FIG. 3) in the voice input unit 2.

  With these configurations, the level adjustment determination device 4-1 has a waveform (see FIG. 1) in which the waveform of the input speech is alternately present with an extremely large amplitude and a small amplitude of the waveform at short time intervals. Even if the waveform is partially excessive (see FIG. 2), the level of the input voice can be determined with high accuracy.

  The level adjustment determination device 4-1 can adjust the level of the input voice with high accuracy even if the level of the waveform of the input voice is partially excessive. This will be described in detail below.

The fourth determination unit 132 determines whether the level L is equal to or lower than a predetermined fourth threshold value A _min or determines whether the level L is smaller than a predetermined fourth threshold value A _min ( Step S24). The fourth threshold value _{A min} is stored in advance in the fourth threshold value storage unit 134.

When it is determined that the level L is equal to or smaller than the fourth threshold value A _min or less, the threshold value small time calculation unit 136 determines that the level L is the first within the past predetermined determination time T _f (t _{1 to} t ₂ ). A threshold small time _TL , which is a total time of four threshold values A _min or less / less than, is calculated (step S26). Further, it is preferable that t ₁ is the current time and t ₁ = 0. The calculated threshold small time _TL may be temporarily stored in the threshold small time storage unit 138. If it is determined that the level L is greater than or _equal to the fourth threshold A _min or greater, the threshold small time calculation unit 136 does not calculate the threshold small time T _L.

Threshold small average level computing unit 144 uses the threshold value small time _{T L,} and calculates the threshold small average level _{M L} is the arithmetic mean of the fourth threshold value _{A min} or less / smaller level L (step S30). Specifically, the threshold small average level M _L can be expressed by the following equation.

Molecule of formula (3), the level L performs integration at the threshold small average level M _L or less / smaller time interval, indicating that calculates their sum. Threshold small average level M _L is once may be stored in the threshold small average level storage unit 146.

Fifth judging unit 148 judges, it determines whether the fifth threshold value B _min below the threshold small average level M _L is predetermined, or whether the fifth threshold value B _min is less than or a predetermined (Step S32). If, fifth judging unit 148, _{M L} is not less than _{B min,} or if it is determined to be not less than _{B max,} the level L is determined a little smaller, the adjustment instruction signal generating unit 124, the input signal level L An adjustment command signal is generated so as to slightly increase (step S34). Also, the second determination unit 116, _{M H} is less than _{B max,} or if it is determined that _{B max} smaller, the level L is determined that quite small, the adjustment instruction signal generating unit 124, the input signal level L The adjustment command signal is generated so as to increase the value (step S36). As described above, the adjustment command signal generation unit 124 generates and outputs an adjustment command signal for adjusting the level L of the input signal according to the determination result of the fifth determination unit 148.

  As described above, the level adjustment determination device 4-1 has a waveform (see FIG. 1) in which the waveform of the input speech has an extremely large amplitude and a small amplitude of the waveform alternately at short time intervals (see FIG. 1). Therefore, even if the waveform has an excessively high level (see FIG. 2) or a waveform having a partially low level, the level of the input voice can be determined with high accuracy. Further, in order to determine the level of the input voice level in real time, it is preferable to perform each process shown in FIG. 5 at short time intervals.

[Modification 1]
Next, a level adjustment determination device 4-2 that is Modification 1 will be described. FIG. 6 shows a functional configuration example of the level adjustment determination device 4-2, and FIG. 7 shows a main processing flow of the level adjustment determination device 4-2.
Compared with the level adjustment determination apparatus 4-1, the level adjustment determination apparatus 4-2 includes a fourth determination unit 132, a fourth threshold storage unit 134, a threshold small time calculation unit 136, a threshold small time storage unit 138, and a threshold small value. The difference is that there is no average level calculation unit 144, small threshold average level storage unit 146, fifth determination unit 148, and fifth threshold storage unit 150. By adopting a configuration such as the level adjustment determination device 4-2, for example, even if the waveform of the input sound level is partially excessive, the input sound level can be adjusted with high accuracy.

[Modification 2]
Next, a level adjustment determination device 4-3 that is Modification 2 will be described. FIG. 8 shows a functional configuration example of the level adjustment determination device 4-3, and FIG. 9 shows a main processing flow of the level adjustment determination device 4-3.
Compared with the level adjustment determination device 4-1, the level adjustment determination device 4-3 includes a first determination unit 104, a first threshold storage unit 106, a threshold large time calculation unit 108, a threshold large time storage unit 110, and a threshold large value. The difference is that the average level calculation unit 112, the threshold large average level storage unit 114, the second determination unit 116, and the second threshold storage unit 118 are not provided. By adopting a configuration like the level adjustment determination device 4-3, for example, even if the waveform of the input sound is partially low, the input sound level can be adjusted with high accuracy.

In the voice input from the voice input unit 2 (headset), for example, a sound other than an utterance such as coughing may be input. As described above, when the volume during normal speech is appropriate, if the cough is cleared, the volume may suddenly become excessive for a short time and clipping may occur. In addition, when the speaker is silent for a short time during the utterance, there may be a slight silence (underestimation). It is not preferable to use such an excessive level L for a short time or an excessive level L for a short time as information for automatic adjustment. This is because the level of the input voice is frequently adjusted up and down, the level of the input voice is not stable, and when the adjusted voice is used in the voice recognition system (see FIG. 3), the voice is accurately set. Cannot be recognized. As a method for determining that the input speech is excessive or excessive even for such sudden and short excessive or excessive sound, there is a method of obtaining and using the short-term average value of the absolute amplitude value. is there. This technique is referred to as Conventional Technique 4. FIG. 10 shows the input voice and the average level G of the input voice calculated by the level adjustment determination device of the prior art 4. Similarly to FIG. 1 and FIG. 2, the level adjustment determination device of the prior art 4 determines that the average level G is excessive if it is greater than the upper limit A _max , and determines that it is excessive if it is less than the lower limit A _min. To do. As shown in FIG. 10, for example, when coughing is the section alpha _4, the voice of the section alpha ₄ will lower the sound level is determined excessive, conversely, a short silent interval or weak pronounce speech segment respect also, in fact despite larger than the lower limit a _min, the level will be determined that under-. As a result, the level of the input voice frequently fluctuates.

  Therefore, the level adjustment determination device 4-4 described in the second embodiment has an excessively high voice level with high accuracy even for such a sudden and short excessive voice or a short excessive voice. Underdetermined. FIG. 11 shows a functional configuration example of the level adjustment determination device 4-4, and FIG. 12 shows a main processing flow of the level adjustment determination device 4-4. The level adjustment determination device 4-4 includes a third determination unit 120, a third threshold storage unit 122, a sixth determination unit 140, and a sixth threshold storage unit 142, as compared with the level adjustment determination device 4-1. Different. Further, in FIG. 5 (the process flow of the level adjustment determination apparatus 4-1) and FIG. 11 (the process flow of the level adjustment determination apparatus 4-4), there is a step S8 between step S6 and step S10. In addition, the difference is that step S28 exists between step S26 and step S30.

The third determining unit 120 determines whether a threshold amount of time _{T H} is equal to or less than the third threshold value _{C max} predetermined or threshold amount of time _{T H} is whether third threshold _{C max} less than or ( Step S8). The third threshold value C _max is stored in advance in the third threshold value storage unit 122. Threshold amount of time _{T H} is or than the third threshold value _{C max,} that the third threshold value _{C max} is smaller than the total time of the level L of the input speech within the determination time _{T f} is _{A max} is greater than the time (a threshold amount of time T _H ) is extremely short. That is, the section exceeding the threshold is determined to be, for example, a sudden and short excessive voice (for example, coughing) time. If it is determined that the large threshold time _TH is greater than or equal to the third threshold C _max , the threshold large average level calculation unit 112 performs the process of step S12. When the threshold amount of time T _H is determined that the third threshold value C _max or less / smaller, so as not to generate an adjustment instruction signal to the adjustment instruction signal generating unit 124.

The sixth determining unit 140 (determining whether even or sixth threshold value _{C min} below the threshold small time _{T L} of the threshold small time storage unit 138, or whether the sixth threshold value _{C min} is less than or S28). That the threshold small time T _L is equal to or smaller than the sixth threshold C _max or smaller than the third threshold C _max means that the total time (the threshold small time T T) of the input speech level L is smaller than A _min within the determination time T _f . _L ) is extremely short. In other words, the section that is below the threshold is determined to be a sudden and short time of excessive voice (for example, silence of the speaker). When it is determined that the small threshold time _TL is greater than or equal to the sixth threshold C _min or greater, the process of step S30 is performed by the small threshold average level calculation unit 144. When it is determined that the small threshold time _TL is equal to or smaller than the sixth threshold C _min , the adjustment command signal generation unit 124 is prevented from generating an adjustment command signal.

FIG. 13 shows the input sound, the threshold large average level M _H (indicated by a black solid line) and the threshold small average level M _L (indicated by a white solid line) of the input sound calculated by the level adjustment determination device 4-4. Indicates. Amplitude threshold and a large average level M _H, and the threshold small average level M _L, as shown in FIG. 13, it becomes a digital waveform includes a M _H and M _L when it is less than two points This is because the value changes. In the case of the threshold large average level _MH , (1) when the audio signal F (t) becomes greater than or equal to the first threshold A _max (2) the audio signal F (t) greater than or equal to the first threshold A _max However, the amplitude value changes when it is outside the determination time _Tf . If threshold small average level _{M L,} (1) audio signal F when (t) is smaller than or less / fourth threshold _{A min} (2) fourth threshold value _{A min} or less / smaller audio signal F (t) However, the amplitude value changes when it is outside the determination time _Tf . In the section alpha ₅ in FIG. 13, the threshold large mean level _{M H} exceeds the first threshold value _{A max.} However, the threshold amount of time T _H is because shorter than the third threshold value C _max, the level L of the input speech is not determined is excessive. On the other hand, determines the interval alpha _6, threshold large mean level _{M H} is, exceeds the first threshold value _{A max,} the threshold amount of time _{T H} is is longer than the third threshold value _{C max,} the level L of the input speech is excessive Is done.

As described above, when the third determination unit 120 determines that the large threshold time T _H is smaller than the third threshold C _max , the section _exceeding the first threshold A _max is an excessively short period of time. It is determined as the time of voice (for example, coughing). Further, when the sixth determination unit 140 determines that the threshold small time T _L is smaller than the sixth threshold C _min , a section _exceeding the first threshold A _min is a sudden short time of excessive voice (for example, , The speaker's silence). In these cases, the adjustment command signal generator 124 does not generate an adjustment command signal. In other words, the level adjustment determination device 4-4 determines whether the input sound level is excessive or insufficient by using an arithmetic mean value that is larger (or smaller) than a predetermined threshold as in the prior art. Rather, the time (threshold large time _TH or threshold small time T _L ) only when the threshold is exceeded (or falls below), and the arithmetic mean value (threshold large average level _MH and threshold small average) Both the level M _L ) and the level of the input voice level are judged to be too high or too low.

  By doing this, it is possible to exclude excessive sound and excessive sound for a short time from the target of level adjustment judgment, such as coughing and slight silence, and the waveform of the input sound is extremely large in amplitude. And a waveform having a small amplitude alternating with a short time interval (see FIG. 1), a waveform with a partially excessive level (see FIG. 2), or a waveform with a partially insufficient level Even so, the level of the input voice does not frequently fluctuate, and the input voice level can be automatically adjusted with high accuracy.

[Modification 3]
Next, a level adjustment determination device 4-5 of Modification 3 will be described. FIG. 14 shows a functional configuration example of the level adjustment determination device 4-5, and FIG. 15 shows a main processing flow of the level adjustment determination device 4-5. The level adjustment determination device 4-5 is different from the level adjustment determination device 4-2 in that it includes a third determination unit 120 and a third threshold value storage unit 122.
By adopting a configuration such as the level adjustment determination device 4-5, even if the input sound level is a waveform that is partially excessive and the sound is suddenly excessive for a short time, it is highly accurate. The level of the input sound can be adjusted.

[Modification 4]
Next, a level adjustment determination device 4-6 of Modification 4 will be described. FIG. 16 shows a functional configuration example of the level adjustment determination device 4-6, and FIG. 17 shows a main processing flow of the level adjustment determination device 4-6. The level adjustment determination device 4-6 differs from the level adjustment determination device 4-3 in that it includes a sixth determination unit 140 and a sixth threshold value storage unit 142.
By adopting a configuration such as the level adjustment determination device 4-6, even if the input sound level is a waveform that is partially too low and the sound is suddenly short and short, high accuracy can be obtained. The level of the input sound can be adjusted.

The figure which showed the average level G at the time of using the level adjustment determination apparatus of the prior art 1. FIG. The figure which showed the average level G at the time of using the level adjustment determination apparatus of the prior art 1 about the input audio | voice different from FIG. The figure which shows the structural example in case the level adjustment determination apparatus of this invention is implemented. FIG. 3 is a diagram illustrating a functional configuration example of a level adjustment determination apparatus according to the first embodiment. The figure which shows the flow of the main processes of the level adjustment determination apparatus of Example 1. FIG. The figure which shows the function structural example of the level adjustment determination apparatus of the modification 1. The figure which shows the flow of the main processes of the level adjustment determination apparatus of the modification 1. The figure which shows the function structural example of the level adjustment determination apparatus of the modification 2. The figure which shows the flow of the main processes of the level adjustment determination apparatus of the modification 2. The figure which showed the average level G at the time of using the level adjustment determination apparatus of the prior art 1 about the input audio | voice containing coughing. FIG. 9 is a diagram illustrating a functional configuration example of a level adjustment determination apparatus according to a second embodiment. The figure which shows the flow of the main processes of the level adjustment determination apparatus of Example 2. FIG. The figure which showed the average level G at the time of using the level adjustment determination apparatus of Example 1 about the waveform of the input audio | voice containing coughing. The figure which shows the function structural example of the level adjustment determination apparatus of the modification 3. The figure which shows the flow of the main processes of the level adjustment determination apparatus of the modification 3. The figure which shows the function structural example of the level adjustment determination apparatus of the modification 4. The figure which shows the flow of the main processes of the level adjustment determination apparatus of the modification 4.

Claims (10)

A signal level calculation unit for calculating the level of the input signal;
A first determination unit that determines whether the level is equal to or higher than a predetermined first threshold value or greater than a first threshold value;
If it is determined that the level is greater than or equal to the first threshold or greater than the first threshold, the level is greater than or equal to the first threshold or greater than the first threshold within a past predetermined determination time. A threshold large time calculation unit for calculating a threshold large time that is the total time of
A threshold large average level calculating unit that calculates a threshold large average level that is an arithmetic average of levels greater than or equal to the first threshold or greater than the first threshold using the threshold large time;
A second determination unit for determining whether the threshold large average level is equal to or greater than a predetermined second threshold or greater than a second threshold;
An adjustment command signal generation unit that generates and outputs an adjustment command signal for adjusting the level of the input signal according to the determination result of the second determination unit;
A level adjustment determination apparatus comprising: The level adjustment determination apparatus according to claim 1,
Furthermore,
It is determined whether or not the large threshold time is equal to or smaller than a predetermined third threshold or smaller than a third threshold, and when it is determined that the large threshold time is equal to or smaller than the third threshold or smaller than the third threshold. And a third determination unit that does not cause the adjustment command signal generation unit to generate the adjustment command signal. A signal level calculation unit for calculating the level of the input signal;
A fourth determination unit that determines whether the level is equal to or lower than a predetermined fourth threshold value or less than a fourth threshold value;
When it is determined that the level is less than or equal to the fourth threshold value or less than the fourth threshold value, the time during which the level is less than or equal to the fourth threshold value or less than the fourth threshold value in a past predetermined determination time. A threshold small time calculation unit that calculates a threshold small time that is the total time of
A threshold small average level calculation unit that calculates a threshold small average level that is an arithmetic mean for a level equal to or lower than the fourth threshold or smaller than the fourth threshold using the threshold small time;
A fifth determination unit for determining whether the threshold small average level is equal to or lower than a predetermined fifth threshold or less than a fifth threshold;
An adjustment command signal generation unit that generates and outputs an adjustment command signal for adjusting the level of the input signal according to the determination result of the fifth determination unit;
A level adjustment determination apparatus comprising: The level adjustment determination device according to claim 3,
Furthermore,
It is determined whether or not the small threshold time is equal to or smaller than a predetermined sixth threshold or smaller than a sixth threshold, and when it is determined that the small threshold time is equal to or smaller than the sixth threshold or smaller than the sixth threshold. And a sixth determination unit that does not cause the adjustment command signal generation unit to generate the adjustment command signal. The level adjustment determination apparatus according to claim 1 or 2,
Furthermore,
A fourth determination unit that determines whether the level is equal to or lower than a predetermined fourth threshold value or less than a fourth threshold value;
When it is determined that the level is less than or equal to the fourth threshold value or less than the fourth threshold value, the time during which the level is less than or equal to the fourth threshold value or less than the fourth threshold value in a past predetermined determination time. A threshold small time calculation unit that calculates a threshold small time that is the total time of
A threshold small average level calculation unit that calculates a threshold small average level that is an arithmetic mean for a level equal to or lower than the fourth threshold or smaller than the fourth threshold using the threshold small time;
A fifth determination unit that determines whether the threshold small average level is equal to or lower than a predetermined fifth threshold or less than a fifth threshold;
The level adjustment determination device, wherein the adjustment command signal generation unit generates and outputs an adjustment command signal for adjusting the level of the input signal according to the determination result of the fifth determination unit. . The level adjustment determination device according to claim 5,
Furthermore,
It is determined whether or not the small threshold time is equal to or smaller than a predetermined sixth threshold or smaller than a sixth threshold, and when it is determined that the small threshold time is equal to or smaller than the sixth threshold or smaller than the sixth threshold. A level adjustment determination apparatus comprising: a sixth determination unit that does not cause the adjustment command signal generation unit to generate the adjustment command signal. A signal level calculation process for calculating the level of the input signal;
A first determination step of determining whether the level is greater than or equal to a predetermined first threshold or greater than a first threshold;
If it is determined that the level is greater than or equal to the first threshold or greater than the first threshold, the level is greater than or equal to the first threshold or greater than the first threshold within a past predetermined determination time. A threshold large time calculation process for calculating a threshold large time that is a total time of
A threshold large average level calculation step of calculating a threshold large average level that is an arithmetic average of levels equal to or greater than the first threshold or greater than the first threshold using the threshold large time;
A second determination step of determining whether the threshold large average level is greater than or equal to a predetermined second threshold or greater than a second threshold;
An adjustment command signal generation process for generating and outputting an adjustment command signal for adjusting the level of the input signal according to the determination result of the second determination process;
A level adjustment determination method characterized by comprising: A signal level calculation process for calculating the level of the input signal;
A fourth determination step of determining whether the level is equal to or lower than a predetermined fourth threshold value or less than a fourth threshold value;
When it is determined that the level is less than or equal to the fourth threshold value or less than the fourth threshold value, the time during which the level is less than or equal to the fourth threshold value or less than the fourth threshold value in a past predetermined determination time. A threshold small time calculation process for calculating a threshold small time that is a total time of
A threshold small average level calculation step of calculating a threshold small average level, which is an arithmetic average of levels below the fourth threshold or smaller than the fourth threshold, using the threshold small time;
A fifth determination step of determining whether the threshold small average level is less than or equal to a predetermined fifth threshold or less than a fifth threshold;
An adjustment command signal generation process for generating and outputting an adjustment command signal for adjusting the level of the input signal according to the determination result of the fifth determination process;
A level adjustment determination method characterized by comprising: The level adjustment determination method according to claim 7,
Furthermore,
A fourth determination step of determining whether the level is equal to or lower than a predetermined fourth threshold value or less than a fourth threshold value;
When it is determined that the level is less than or equal to the fourth threshold value or less than the fourth threshold value, the time during which the level is less than or equal to the fourth threshold value or less than the fourth threshold value in a past predetermined determination time. A threshold small time calculation process for calculating a threshold small time that is a total time of
A threshold small average level calculation step of calculating a threshold small average level, which is an arithmetic average of levels below the fourth threshold or smaller than the fourth threshold, using the threshold small time;
A fifth determination step of determining whether the threshold small average level is less than or equal to a predetermined fifth threshold or less than a fifth threshold;
The level adjustment determination is characterized in that the adjustment command signal generation step generates and outputs an adjustment command signal for adjusting the level of the input signal according to the determination result in the fifth determination step. Method. The level adjustment determination program for making a computer perform each process of the level adjustment determination apparatus in any one of Claims 1-6.