JP2013143763A - Loudness correction means and sound quality adjustment means - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide loudness correction and sound quality adjustment of change in sound quality resulting from different frequency characteristics of a sound that a person feels (auditorily) depending upon how loud the sound is and use thereof, and measurement of a sound pressure level in a method other than using a noise meter.SOLUTION: Loudness correction and sound quality adjustment is performed by an equalizer having characteristics approximated polygonally with three linear filter curves obtained by analyzing a loudness curve of ISO226:2003, having gradients and levels determined with values of differences in sound pressure level between a sound source and output, and arranged within ranges of 20-800 Hz, 800 Hz-6.3 kHz, and 6.3-12.5 kHz, and a sound is processed. Further, the sound pressure level is measured with a difference in signal voltage (sound pressure) level when signals of two different frequencies are heard equally in loudness (at the same auditory level) by utilizing the fact that the sound pressure level and auditory level have linear relation in frequency units, but have a large level difference in a low frequency range and almost at 1 kHz.

Description

  In the present invention, when an electroacoustic device is used, the sound quality degradation caused by the frequency characteristics of hearing depending on the magnitude of the sound pressure level is a value of the difference in sound pressure level between the sound source and the output. The present invention relates to a loudness correction method, a sound quality adjustment method, and a sound pressure measurement method characterized by an equalizer having a broken line approximation characteristic determined by three straight lines. Each of the above methods includes an audio device, computer software, and media such as a CD, a DVD, and broadcast audio.

  It has been known for a long time that changing the volume of a speaker changes not only the volume of the sound but also the volume feeling (sound quality) of the low range and the high range with respect to the volume sense of the mid range. This phenomenon is attributed to the fact that human hearing has frequency characteristics with respect to the sound pressure level. Equal loudness curves that express this characteristic were the Fletcher-Manson curve in the 1930s and the Robinson-Dudson curve in the 1950s. In August 2003, a new equal loudness curve ( FIG. 17) was published as the international standard ISO 226: 2003.

  Loudness correction has been put into practical use with some stereo amplifiers as loudness control, but it is represented by the circuit and characteristics shown in FIG. 18 (a), probably because the isoloudness curve before the ISO226: 2003 announcement was inaccurate. Although correction using a characteristic curve centered on 1 KHz was performed, it was evaluated that the bass sound was only lumpy, and there was a drawback that accuracy was low. Further, there is a sound quality adjustment (tone control) shown in FIG. 18C in which the sound quality can be adjusted with a similar characteristic curve.

  After that, correction (Fig. 18 (b)) by graphic equalizer (analog equipment) and digital processing (hereinafter, meaning of signal processing by CPU or DSP) became common. A method of adjustment is performed, and it is necessary to readjust the memory data every time the volume is changed or to recall the memory data when the volume is adjusted in advance. This method relies on the individual's sensibility and there is no specific quantified guideline.

  Recently, the level of each signal obtained by dividing the input signal and the output measured with a microphone into about 6 bands and the equal loudness curve are compared by digital processing, and the level of each band is adjusted and recombined. A method characterized by correcting the loudness has been proposed. However, it has not become a definitive product or established method.

  The sound pressure level is measured only by a measurement method using a sound level meter using a microphone. FIG. 18D shows an example of a block diagram of the sound level meter.

JP 2009-111538 A Special table 2009-538554

Press release "Precise determination of all auditory areas of 2D equal loudness curves" National Institute of Advanced Industrial Science and Technology

  The problem to be solved by the present invention is a phenomenon of sound quality degradation that occurs due to a difference between a sound source of an electroacoustic device and a sound pressure level of an output due to a human hearing having a loudness frequency characteristic depending on the sound pressure level. ISO 226: 2003 etc. to provide a method, sound apparatus, computer software and media capable of performing loudness correction by a technique capable of obtaining and realizing a clear loudness correction curve through analysis, trial production and experiment of ISO 226: 2003. Furthermore, the present invention is to provide a sound quality adjustment method and a sound pressure measurement method using the obtained loudness correction method.

  Hereinafter, the sound pressure level (Sound Pressure Level) is abbreviated as SPL, and dB is used as a unit. The level of loudness (Hearing Level), which is a sense of human loudness, is abbreviated as HL, and Phons is used as a unit for distinction.

  The sound source sound pressure level in the present invention is the SPL of a sound generator (sound source) when, for example, a musical instrument or voice is picked up by a microphone and a speaker is played online. Generally, it is said that the SPL of live orchestra is 80 to 100 dB.

  However, the sound source sound pressure level of media such as recording media such as CDs, DVDs, movies, and broadcast media including TV, FM broadcasts, and the Internet is the SPL of the monitor sound in the adjustment room adjusted for mixing. This is because the media worked in the adjustment room of the music recording studio is the one that is adjusted by hearing, that is, the loudness correction is performed by the SPL of the monitor sound in the adjustment room. Generally, the adjustment room of a music recording studio is said to be 85 to 90 dB. Also, the broadcast audio adjustment room is often lower than the music recording studio, but it is considered that there is no unified level regulation.

  Similarly, the output sound pressure level is the SPL that enters the listener's ear listening through a speaker or earphone. Generally, listening to television at home is said to be about 60 dB, and in store BGM, about 30 dB. In addition, it is considered that it is about 30 dB to 75 dB although it is very different in the home stereo. For example, when listening to television at home, the user listens with a loudness frequency characteristic around 60 dB. Note that SPL measurement of loudness characteristics such as ISO226: 2003 is described as “calibrated without a human head at a position where the center of the human head comes”, and is based on the same concept.

  The difference between the SPL of the sound source and the output will be described below on the assumption that a domestic viewer listens to a 60 dB SPL of an FM broadcast DJ program monitored at an SPL of 75 dB in the FM station adjustment room. In the FM station adjustment room, the voice of the announcer listens to the monitor to make equalizing adjustments, but the music CD adjusted in the 90 dB (SPL) music recording studio is sent out without adjustment.

  At this time, in the FM adjustment room listening at 75 dB, the CD music has a difference of about 15 dB from the 90 dB of the music recording studio adjustment room, and there is little deterioration in sound quality. On the other hand, the viewer who listens at 60 dB, in the announcer's voice, the difference from 75 dB in the FM adjustment room is about 15 dB, but the CD music is 30 dB because it is different from 90 dB in the music recording studio adjustment room. Listen with loudness frequency characteristics. (See Figure 11)

  As a result, it is possible to hear unbalanced music in which the low-frequency and high-frequency sounds are small compared to the mid-range sound. A prominent example appears in the phenomenon that the base sound cannot be heard in the BGM of the store, and the characteristics of the ceiling speaker are not only bad.

  The sound pressure measurement method is a measurement method for specifying SPL. The sound pressure level plays an important role for the loudness correction method of the present invention, and a measurement method suitable for the correction of the present invention is required in addition to the sound level meter for measuring the sound pressure level of noise.

  Means for solving the above-mentioned problem “loudness correction method” include the linear approximation line (Linear Application) slope (dB / Oct) between 20 to 800 Hz and the linear approximation line between 800 to 6.3 kHz shown in FIG. The level difference (dB) and the slope (dB / Oct) of the linear approximation line between 6.3 kHz and 12.5 kHz are characteristics that are approximated by a broken line by three linear approximation lines determined by the SPL difference (dB). The loudness correction method using an equalizer is used.

算出出来る。

It can be calculated.

きい時はプラスで計算し、プラスの時に図１の近似線は上下対象に反転する。また、２０〜８００Ｈｚの近似線は８００〜６．３ｋＨｚの近似線と８００Ｈｚで接続し、同様に６．３〜１２．５ｋＨｚの近似線は８００〜６．３ｋＨｚ近似線と６．３ｋＨｚで接続する。なお、交点付近は適当な曲線で接続し、特に１ＫＨｚでは、０ｄＢに接近するように設定する。

When it is threshold, it is calculated as plus, and when it is plus, the approximate line in FIG. An approximate line of 20 to 800 Hz is connected to an approximate line of 800 to 6.3 kHz at 800 Hz, and similarly, an approximate line of 6.3 to 12.5 kHz is connected to an approximate line of 800 to 6.3 kHz at 6.3 kHz. . Note that the vicinity of the intersection is connected by an appropriate curve and is set to approach 0 dB particularly at 1 KHz.

  Hereinafter, the operation principle of the loudness correction method according to the present invention will be described with reference to the drawings.

  FIG. 2 shows the ISO 226: 2003 loudness curve of FIG. 17 by quantifying the values so that the horizontal axis is SPL and the vertical axis is HL for each main frequency. It can be seen that when HL is 20 Phons or more, each curve is a straight line, that is, a linear relationship between SPL and HL, and a 1 kHz curve in which SPL vs. HL is 1: 1 as the frequency goes away from 1 kHz to low and high frequencies. It can be seen that they are moving away with increasing inclination in the same direction.

  FIG. 3 shows only the 1 kHz and 63 Hz curves of FIG. 2 and shows the relationship between the SPL required when HL is 90 Phones and 60 Phones. In order for A's 1 kHz and 63 Hz sound to be heard at the same 90 Phons, 63 Hz needs to be 14.5 dB larger than 1 kHz, and at B's 60 Phons, if the SPL is lowered by 30 dB with the same level relationship as 90 Phons, 63 Hz HL can be heard 18Phons smaller than 60Phons. It can be seen that for the same HL, 11.7 dB must be added to 14.5 dB. This 11.7 dB is a loudness correction for a 30 dB SPL difference.

  FIG. 4 shows that three sounds C of 63 Hz which can be heard at 80 and 100 phons of HL difference of 90 phons and ± 10 phons are 104.5 dB of D increased by +14.5 dB in the SPL and three SPLs of ± 6.1 dB in SPL. become. This is reduced by 30 dB in the same SPL level relationship, and E obtained by adding 14.5 dB of SPL difference at 90 phons and 11.7 dB of loudness correction can be heard at 60 phons of F and 50 and 70 phons of ± 10 phons difference. That is, it can be seen that loudness correction can be performed with the same balance even if the SPL is lowered by 30 dB. This is true for other frequencies as well.

FIG. 5 shows an equal loudness curve in which ISO 226: 2003 in FIG. 17 is digitized and 0 and 10 having low practicality and 100 Phons having a small amount of data are excluded.
FIG. 6A shows the values of 3.15 kHz with the highest ear sensitivity in FIG. 5 so that each curve becomes 0 dB (the curves are translated vertically).
FIG. 6B is a graph in which each curve is shown as a difference from the 60 Phons curve with the 60 Phons curve in FIG. 6A as a reference (0 dB).

  In FIG. 6 (b), it can be seen that there are three regions spreading in a fan shape with regularity in a portion with little difference centered on 3.15 kHz, and in a low region and a high region. This figure shows the loudness correction amount with respect to 60 phons, and it is one of the important features of the present invention to analyze centering on this 3.15 kHz.

  FIG. 7 shows the conventional method in which 1 kHz of the conventional method becomes 0 dB. This figure is considered to be the cause of the idea of correcting the signal by dividing it into about 6 bands. However, in electroacoustics, the discussion is based on 1 kHz, and in the ISO226: 2003 loudness curve, the value of 1 kHz is defined as 0 dB.

  FIG. 8 shows a curve resulting from a difference from 60 Phones in FIG. 6B with a difference between the original levels and a straight line approximation line. A solid line shows what is obtained from the equal loudness curve of FIG. 5, and a broken line is a straight line approximation line (folded line approximation) entered with regularity. Although there is some error at 20 phons, the whole can be approximated accurately. It can also be seen that the “Difference in SPL” is a 0 dB line, and the upper and lower sides are targets, and the correction value can be calculated simply by reversing the correction direction regardless of which SPL is large between the sound source and the output.

FIG. 9A is a band of 20 to 800 Hz, which is indicated by “HL vs. slope of approximate line (dB / Oct)”, but it can be seen that there is a linear relationship.
FIG. 9B is a band of 6.3 k to 12.5 kHz, which is indicated by “HL vs. slope of approximate line (dB / Oct)”, but it can be seen that there is a linear relationship.
FIG. 9 (c) is a band in the range of 800 to 6.3 kHz and is expressed by “HL vs. reference SPL (SPL at 1 KHz) and SPL difference (dB) between each approximate line”, but has a linear relationship. I understand that.

  In addition, it was found that the difference in SPL change at, for example, 100 Hz or 12.5 kHz also has a linear relationship.

  FIG. 10 shows each curve with a level difference added using the method of FIG. 8 with the 80 phons curve as a reference (0 dB). Since the curve obtained from the equal loudness curve and the approximate curve match in a wide range, it can be seen that this approximation can be applied in a wide range.

なものとなっている。音源音圧レベルが９０ｄＢのＣＤを出力音圧レベルが３０ｄＢのＢＧＭで聴くと、６３Ｈｚで−２２ｄＢ、１２．５ｋＨｚでは−９ｄＢであり、中域だけが聴こえることの理由が判る。

It has become a thing. When a CD with a sound source sound pressure level of 90 dB is listened to with a BGM with an output sound pressure level of 30 dB, it is -22 dB at 63 Hz and -9 dB at 12.5 kHz, and the reason why only the midrange can be heard.

  FIG. 12 (a) compares the definition of the sound pressure level (absolute level), which is the energy ratio (the reference value is 20 μPascal), with the formula of the ratio of power (power), thereby comparing the sound pressure level ratio Relative level) can be replaced with voltage ratio (relative level). As is generally said, it can be seen that a correction curve obtained by the difference in SPL can be adopted as a correction characteristic curve based on the voltage ratio (dB) of the equalizer circuit.

  FIG. 12B is an example of the loudness correction curve of the present invention as described above. Since the approximation factors in the terms [0029] to [0031] are linear in a wide range, the calculation formula of the approximate line obtained using the proportional relationship between the approximate curves is the formula [0019]. FIG. 12B shows the calculation and description. The broken line is a broken line approximation, and the solid line is described with realistic characteristics reflecting [0020] [Connecting the vicinity of the intersection with an appropriate curve, especially at 1 KHz, set to approach 0 dB].

  FIG. 13A is an example of an equalizer circuit for correcting the difference in SPL (−32 dB) in the present invention. R3 to R8 and C1 to C3 create a low frequency characteristic, A2 and R9 and R10 adjust the gain, and R9 and C6, L1 and R11 use LC resonance to create a high frequency characteristic. It should be noted that L1 and R11 can be replaced with a simulated inductor. The R1 and R2 ATTs (attenuators) are for varying the volume, A1 performs impedance conversion by performing impedance conversion, C4 is for direct current cut, and C5 is for phase compensation.

FIG. 13B shows the frequency characteristics produced by the low-frequency and high-frequency equalizer circuits shown in FIG.
FIG. 13C shows the total frequency characteristics produced by the equalizer circuit shown in FIG.
According to FIGS. 13A to 13C, the conventional loudness control circuit of FIG. 18A using only one capacitor and one resistor capable of producing only a 6 dB / Oct curve cannot produce the characteristics of the present invention. It can be clearly seen that the present invention is significantly different from the characteristics of the conventional method.

  FIG. 14A is an example of a block diagram for carrying out the present invention. In this method, a correction equalizer circuit and ATT are integrated every 2 dB, and the volume and correction are simultaneously varied.

  FIG. 14B is an example of a block diagram in the case where a large number of equalizer circuits are required in FIG. A system in which a correction equalizer circuit of 2, 4, 8, 16, and 32 dB and an ATT are integrated in series, and the volume and correction are controlled simultaneously by passing or bypassing each circuit in binary. is there.

  FIG. 14C shows a switch and a correction equalizer that simultaneously control the volume and the correction by arranging the correction equalizer circuit and the ATT in FIG. 14B separately and adding a binary addition / subtraction logic to the control circuit. 2 is an example of a block diagram based on a system in which two switches that can only be changed are arranged and a function capable of fine adjustment of correction is added.

  FIG. 15A shows an example of a circuit that can be continuously varied by volume control, although FIGS. 14A to 14C are step type adjustments.

  FIG. 15B shows frequency characteristics of the circuit shown in FIG. Note that the B curve is used for the volume, and step type FIGS. 14 (a) to 14 (c) are advantageous for confirming the accurate level, and the secondary variable circuit is useful for simple adjustment and sound quality adjustment. is there.

  From the items [0035] to [0041], it can be seen that the present circuit technology can sufficiently perform the loudness correction of the present invention, and the circuit and the configuration can be performed in various ways. It can also be seen that digital processing methods can be replaced with current technology.

  However, it was confirmed by the trial listening on the prototype that there were large and small variations in the low frequency range on the CD side. Some of these can be determined to be caused by differences in the volume of the monitor, that is, the sound source sound pressure level. To solve this problem, a unified standard is determined, and the sound source side, that is, the media (CD, DVD, movie, TV, FM broadcast). Have realized that it is necessary to process and correct the sound source sound pressure level, or to record or add the sound source sound pressure level to the digital data or transmission signal.

  Humans can listen to music only by hearing, and the sound source sound pressure level is an important guideline (numerical value) for the correction, but currently the sound source sound pressure level is not unified or provided. However, if the sound source sound pressure level is different, it can be corrected by finely adjusting the correction amount.

  The means for solving the problem “sound quality adjustment method” is that the sound quality adjustment (tone control) based on the conventional circuit and characteristics shown in FIG. However, in the present invention, sound quality adjustment for hearing is performed by using the circuits and characteristics in the loudness correction of FIGS. Implementation is sufficiently feasible with current circuit technology.

  Means for solving the problem “sound pressure measurement method” will be described below with reference to the drawings and the operation principle of sound pressure measurement according to the present invention will be described.

  FIG. 16 (a) uses the ISO 226: 2003 loudness curve of FIG. 17 in numerical form, the horizontal axis is “difference in sound pressure level between 80 Hz and 1 kHz”, and the vertical axis is “SPL”. Is written. A solid line shows what is obtained from an equal loudness curve, and a broken line is a straight line approximation. It can be seen that the curves have a linear relationship above 30 dB (SPL).

The above relationship can be calculated from the voltage (sound pressure) level difference (dB) by the following formula.
Sound pressure level (dB) = 126− (2.99 × voltage level difference)

  From this, the sound pressure level (SPL) can be obtained from the value of the difference in signal voltage (sound pressure) level when signals of two different frequencies (80 Hz and 1 kHz) can be heard at the same magnitude (hearing level). I understand that.

  In FIG. 16 (a), the relationship was explained using 80 Hz and 1 kHz as signals of two different frequencies, but as shown in FIG. 2, SPL and HL in frequency units are linear at 30 dB (SPL) or more. From the relationship, it can be seen that the concept of [0049] can be adopted even if the frequency is changed. However, the constants of the formula change.

  2 and 5, the difference in sound pressure level from 1 kHz increases as the frequency decreases, and the manner of change also increases. From FIG. 5, the range between 630 and 1 kHz is the same as 1 kHz. It can be heard that it can be heard, and it is a reference for selecting the frequency and type of the two signals.

  FIG. 16B shows a block diagram as one embodiment of the sound pressure measuring method of the present invention. In the figure, 1 kHz and 80 Hz are recorded as an oscillator or digitally recorded as two signals, and a volume and a level meter are respectively arranged, and a signal mixed by a mix amplifier is sent to a speaker via a power amplifier.

  The measurement is made according to the size of listening to or listening to the 1 kHz signal, and then the frequency is increased by 80 Hz, and the difference in the value of each level meter when listening to the same size as 1 kHz is shown in FIG. SPL can be obtained by the calculation formulas a) and [0048]. The signal used at this time can be a single frequency, a method using white noise or the like through a narrow bandwidth filter, or a method using a familiar sound such as a piano.

  The input to EXT IN is made in advance by using a music editing software to create a signal that alternately outputs 1 kHz and 80 Hz as shown in the signal waveform at the bottom of the figure so that the two volumes have the same volume. This is a method of creating a specific sound pressure level by adjusting the volume. A similar method is possible by adding a volume to the output of the mix amplifier in [0052] and using the volume of each signal as a preset.

  In FIG. 16B, the difference between the levels of 80 Hz and 1 kHz is 20 dB, which is the difference between the levels when the SPL is about 66 dB, and 1 kHz is set to −20 dBFS. The reference level of the CD is −18 dBFS to Matched to -20dBFS. By recording this signal on a CD disc and adjusting the volume as a CD with a playback device, the CD reference level can be adjusted to an output sound pressure level with an SPL of approximately 66 dB. A medium such as a CD on which a signal made by this method is recorded is one of the methods for measuring the sound pressure.

  Even if the volume of the CD that was previously purchased and was judged to be poorly recorded by the prototype according to the present invention is low, the bass that was not heard at that time has a firm rhythm, the cymbals sing and the vocals are naturally thick. I became able to listen to the overall balance. In addition, even if the volume is changed, the balance does not change.

  Until now, only the vague explanations such as “It becomes difficult to hear low and high sounds when the human ear is low” and “100 Hz should be raised” and “Equal loudness curve graph” are attached to the characteristics of hearing. There was no material, but when there was Fig. 11, “Since it was 10 times away from the speaker on the outdoor stage, the SPL decreased by 20 dB with the distance, and the loudness frequency characteristic further decreased by 7 dB at 100 Hz, so the music balance was lost. I can hear it specifically. "

  In addition, what was given up as "caused by the directivity, linearity, and ear characteristics of the speakers" for "checking the CD of the BGM song at a high volume and only listening to the middle range when listening at the BGM volume" “The sound source sound pressure level of the CD is 85 dB and the output sound pressure level is 35 dB, so a loudness correction of 50 dB is necessary.”

  8 and 10, the change of the auditory characteristic is linear and has an accurate proportional relationship. From FIG. 5, for example, at 20 Hz, the bass level does not reach a level that can be heard easily, but it is 800-6. It was heard that the change was twice that of 3 kHz, and the low level adjustment was critical.

  Furthermore, many CDs were listened to with a small volume on the prototype, but it was confirmed that there was a large difference in volume depending on the CD, as well as variations in the low frequency. This difference in low frequency can be determined to be due to the difference in the monitor speaker frequency characteristics during recording adjustment and the difference in the volume of the monitor, that is, the sound source sound pressure level. With regard to the characteristics of the speakers, the current technology that can drive the frequency characteristics and phase to the limit using FFT is solved, but the sound quality generated due to the difference between the sound source sound pressure level and the output sound pressure level Deterioration needs to be corrected with strict control of monitor volume and numerical guidelines as shown in FIG.

  The best solution is to set a standard for the sound source sound pressure level and adjust the level, but providing the SPL of the monitor in addition to the media data is also considered as one of the solutions. In the unified standard, it is considered that 90 dB with a small difference in level between the low range and the high range is suitable for listening, and the level conversion can be performed by using this loudness correction in the equipment that cannot produce the standard volume.

  Compared to the fact that the quality of the video can be assured with high quality as seen in digital terrestrial broadcasting by carefully managing the illuminance, color adjustment, etc., the audio is the “audio standard for TV broadcasting”. It seems that the difference in volume will be reduced by the operation of, but it will not be solved that the music can be heard as long as the loudness frequency characteristics are not dealt with.

  Improving sound quality is essential to accurately convey the artist's artistry to the listener, and the frequency characteristics felt by the listener should be an important element of sound quality. The only measure against the frequency characteristic of the is the loudness correction. In addition, the present invention shows the characteristics of hearing with graphs and numerical values supported by international standards. From the above, it is considered that what is presented in the present invention gives a new direction to the relationship between electroacoustics and hearing.

（ａ）は，ＳＰＬの差による補正曲線のｄＢ値を電圧比のｄＢ値に置き換えた特性曲線で補正出来ることを示している。（ｂ）は，各近似が線形であることから、比例計算で算出した本発明のラウドネス補正曲線の一例を示している。 （ａ）は，本発明でのＳＰＬの差（−３２ｄＢ）をラウドネス補正するイコライザ回路の一例を示している。（実施例１） （ｂ）は，図１３（ａ）の低域と高域イコライザ回路での、各の周波数特性を示している。（ｃ）は，図１３（ａ）のイコライザ回路のトータル周波数特性を示している。 （ａ）は，補正イコライザ回路とＡＴＴを一体にしたものをレベル毎に作り、音量を切り替え選択する実施例の一つとしてのブロック図を示している。（実施例２） （ｂ）は，２、４、８、１６、３２ｄＢの補正イコライザ回路とＡＴＴを一体にしたものを直列に配置し、各回路を通過又はパスを２進法で制御することで音量を切り替え選択する、実施例の一つとしてのブロック図を示している。（実施例３） （ｃ）は，図１４（ｂ）での補正イコライザ回路とＡＴＴを別々配置し、同様に音量を切り替え選択する制御回路に２進法の加減算ロジックを追加し、補正とＡＴＴが同期して動作するスイッチとイコライザ回路のみを調整出来るスイッチを配置した、実施例の一つとしてのブロック図を示している。（実施例４） （ａ）は，本発明でのＳＰＬの差（ＭＡＸ−１６ｄＢ）をボリュームコントロールで連続的にラウドネス補正するイコライザ回路の一例を示している。（実施例５） （ｂ）は，図１５（ａ）のイコライザ回路での、周波数特性の変化を示している。 （ａ）は，８０Ｈｚと１ｋＨｚの信号が同じ大きさで聴こえる時の信号電圧レベルの差とＳＰＬの関係を示している。（ｂ）は，本発明でＳＰＬを測定するためのブロック図の一例を示している。（実施例６） ［非特許文献１］に示す文献に記載の「２００３年８月発表の新国際規格等ラウドネス曲線 ＩＳＯ２２６：２００３」を示している。 （ａ）は，従来方法によるラウドネス補正の回路と特性の一例を示している。（ｂ）は，従来方法にグラフィックイコライザやデジタル処理でのラウドネス補正の様子を示している。（ｃ）は，従来方法による音質調整の回路と特性の一例を示している。（ｄ）は，従来方法による騒音計のブロック図の一例を示している。 3 shows a loudness correction approximate curve and a calculation formula of the present invention in which a polygonal line is approximated by three linear filter curves whose characteristics are determined by the difference in sound pressure level. An equal loudness curve is shown in SPL vs. HL for each major frequency. The loudness correction from the relationship between HL and SPL by the 1 kHz and 63 Hz curves is shown. The relationship between HL and SPL according to the 1 kHz and 63 Hz curves indicates that loudness correction can be performed. The equal loudness curve is digitized, and the graph is re-graphed by excluding the HL 0, 10, and 100 Phones curves. FIG. 5A shows FIG. 5 so that each curve becomes 0 dB at 3.15 kHz where the auditory sensitivity is high. FIG. 6B shows a difference between FIG. 6A and the curve of 60 phons as a reference (0 dB). In the method of FIG. 6A, 1 kHz of the conventional method is shown to be 0 dB. The loudness correction amount curve of FIG. 6B is shown together with a linear approximation line with the original level difference added. (A) is the band of 20 to 800 Hz, and is shown by the slope of the HL vs. approximate line. (B) is a band of 6.3 to 12.5 kHz, and is shown by the slope of HL vs. approximate line. (C) is a band of 800 to 6.3 kHz, and is shown by the difference of SPL between HL vs. reference SPL (SPL at 1 KHz) and each approximate line. In the method of FIG. 8, each curve is added with a difference of the original level using an 80 phons curve as a reference (0 dB), and is shown together with a straight line approximation line.

(A) shows that correction can be made with a characteristic curve in which the dB value of the correction curve due to the difference in SPL is replaced with the dB value of the voltage ratio. (B) shows an example of the loudness correction curve of the present invention calculated by proportional calculation because each approximation is linear. (A) shows an example of an equalizer circuit for correcting the loudness correction of the difference (−32 dB) of SPL in the present invention. (Example 1) (b) has shown each frequency characteristic in the low region and high region equalizer circuit of Fig.13 (a). (C) shows the total frequency characteristic of the equalizer circuit of FIG. (A) shows a block diagram as one embodiment in which a correction equalizer circuit and an ATT are integrated for each level and the volume is switched and selected. (Embodiment 2) In (b), a correction equalizer circuit of 2, 4, 8, 16, and 32 dB and an ATT are arranged in series, and each circuit is passed or controlled by a binary system. FIG. 3 shows a block diagram as one embodiment in which the sound volume is switched and selected. (C) Third Embodiment FIG. 14 (c) shows that the correction equalizer circuit and ATT in FIG. 14 (b) are separately arranged, and a binary addition / subtraction logic is similarly added to the control circuit for switching and selecting the volume. 1 shows a block diagram as one embodiment in which switches that operate synchronously and switches that can adjust only an equalizer circuit are arranged. Example 4 (A) shows an example of an equalizer circuit that continuously corrects the loudness of the SPL difference (MAX-16 dB) according to the present invention by volume control. (Example 5) (b) has shown the change of the frequency characteristic in the equalizer circuit of Fig.15 (a). (A) shows the relationship between the signal voltage level difference and SPL when the 80 Hz and 1 kHz signals can be heard with the same magnitude. (B) shows an example of a block diagram for measuring SPL in the present invention. (Example 6) The “new international standard loudness curve ISO 226: 2003 published in August 2003” described in [Non-Patent Document 1] is shown. (A) shows an example of a circuit and characteristics of a loudness correction by a conventional method. (B) shows the state of loudness correction by a graphic equalizer or digital processing in the conventional method. (C) shows an example of a circuit and characteristics of sound quality adjustment by a conventional method. (D) shows an example of a block diagram of a conventional sound level meter.

  The form for carrying out the invention is an electroacoustic apparatus and computer software whose functions are independent or integrated with a player, an amplifier, etc. in the loudness correction method and the sound quality adjustment method. Or media with corrections, or media with recorded or added sound source sound pressure levels.

  In the sound pressure level measurement method, a device that can measure signals with different frequencies and voltages, and a medium on which the signal is recorded.

  FIG. 13A shows an equalizer circuit as one embodiment of the loudness correction method and the sound quality adjustment method of the present invention.

  FIG. 14A is a block diagram as one embodiment of the loudness correction method and the sound quality adjustment method of the present invention.

  FIG. 14B is a block diagram as one embodiment of the loudness correction method and the sound quality adjustment method of the present invention.

  FIG. 14C is a block diagram as one embodiment of the loudness correction method and the sound quality adjustment method of the present invention.

  FIG. 15A shows an equalizer circuit as one embodiment of the loudness correction method and the sound quality adjustment method of the present invention.

  FIG.16 (b) is a block diagram as one of the Examples in the sound pressure measuring method of this invention.

  Industrial applicability includes stereo audio equipment, headphone regenerators, vehicles such as cars and store audio equipment, audio equipment for music industry, broadcasting industry, PA industry, etc., various audio media and sound measurement equipment, etc. In particular, it is an area where music is recorded and played.

Claims (4)

  The slope and level are determined by the difference between the sound pressure level of the sound source and the output. The line is broken by three linear filter curves arranged between 20 and 800 Hz, between 800 and 6.3 kHz, and between 6.3 kHz and 12.5 kHz. A loudness correction method that corrects deterioration in sound quality caused by the fact that the sense of loudness of humans (hearing) has different frequency characteristics depending on the magnitude of the sound, using an equalizer with approximate characteristics An acoustic device that uses the loudness correction method, which has a function that uses only correction equalization, a function that works in synchronization with volume adjustment, a function that uses a function that only synchronizes with the correction function, and a specific sound pressure level. A function that extracts some of the correction curves (for BGM, etc.), a change that is continuously variable or stepped, a low frequency and a high frequency are separate, and high frequency correction is omitted Things and the like, include those processing method according to digital processing and by analog circuits, the correction function is solely that as the player or device integral ones and computer software, such as amplifiers.   Sound quality adjustment and signal conversion with functions such as sound quality adjustment (tone control) and signal conversion using the equalizer curve obtained by the above loudness correction method (including those in which the low frequency and high frequency are separated or the high frequency is omitted) Methods and processing methods are analog circuits and digital processing devices and computer software.   Depending on the loudness correction method and the correction curve, it is possible to use BGM or earphones for sending signals, that is, media such as recording media such as CD (including compressed ones such as MP3), DVD, movies, and broadcasting media including TV, FM, and the Internet Media for which correction (processing) has been added (including display) so as to be unified for listening at a specific sound pressure level, or for sound source sound pressure level, such as for 60 dB and for 60 dB. In addition, the sound source sound pressure level is recorded or added to the digital data (including an abbreviated code) or added media.   A sound pressure measurement method using the fact that the sound pressure level (SPL) can be specified by the difference in signal voltage (sound pressure level) when signals having different frequencies and voltages are heard in the same sound level (hearing level). And sound pressure level measuring device and media recording signals for measurement.

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