The present invention contains subject matter related to Japanese Patent Application JP 2005-342521 filed in the Japanese Patent Office on Nov. 28, 2005, the entire contents of which being incorporated herein by reference.
1. Field of the Invention
The invention relates to an audio signal noise reduction device that is equipped in a digital private electrical appliance, for example, and reduces the noise level of an audio signal captured by a small-sized microphone, and an audio signal noise reduction method.
2. Description of the Related Art
Digital private electrical appliances each including therein a small-sized microphone, e.g., video cameras, digital cameras, and IC recorders, are becoming increasingly smaller in size. Such a smaller-sized appliance often causes problems of arising unpleasant shock noise, touch noise, or click noise at the time of audio reproduction. Such noise is caused by frequent accidental touch on a microphone and therearound at the time of capturing audio, or click operations of various function switches SW, resulting in the noise entering the microphone after being transmitted through a cabinet. There is another problem caused by the proximity between the internal microphone and a recording device, e.g., tape unit and disk unit, equipped in the private electrical appliance. Such proximity possibly causes noise of the recording device, e.g., vibration noise and acoustic noise, to enter the microphone.
For the aim of reducing such noise, in the internal microphone, a microphone unit is made to be suspended using an insulator such as rubber damper, or the microphone unit is made to be floated using a rubber wire or others. With such a configuration, any vibration coming from the cabinet is absorbed so that no noise is transmitted to the microphone unit. However, this configuration is not enough to achieve the vibration-free environment, i.e., the insulator does not work right if with strong vibration or some vibration frequency, or the resonant vibration occurs with some unique frequency. As such, designing such a configuration is difficult, being the factors that have been hindering the cost saving or size reduction.
For betterment, various other noise reduction methods have been proposed, however, none is satisfactory in terms of meeting users' asking level. This is because the above-described noise includes not only the vibration noise coming from the cabinet but also the acoustic noise that is transmitted as sound in air together with the vibration. Such a noise complicates the transmission path of the noise toward the microphone unit, thereby resulting in a limitation of noise reduction with the previous passive methods.
For the same purpose, the applicant of the invention has proposed the noise reduction technology in Patent Document 1 (JP-A-2005-57437; Microphone Unit, Noise Reduction Method, and Recording Device). In Patent Document 1, the noise reduction is implemented by generating a pseudo noise signal using an adaptive filter, and subtracting the pseudo noise signal from a noise-included audio signal.
The concern here is that, in the technology in Patent Document 1, the larger bandwidth any pseudo-noise signal has, or the longer the time of a successive segment gets, the larger number of taps the adaptive filter for use for the noise reduction shows the tendency of requiring. In an exemplified case of appropriating a noise waveform of 10 mS segment in a band up to a Nyquist rate with a sampling frequency of 48 kHz, required is an adaptive filter of about 480 taps. This resultantly arises a need for a several-fold number of product-sum operation per sample compared with for the number of taps, thereby resulting in the increase of the scale of the operation. This also arises a need for hardware including a large-sized logic circuit and a high-speed DSP (Digital Signal Processor), for example. Since the time delay caused by the operation cannot be neglected, and the audio signals have to be delayed at the same time, the audio capturing often fails to be done in real time.
The above-described noise, i.e., shock noise, touch noise, or click noise, is not always generated continuously but generated only with any accidental shock. The most noise is thus generated abruptly in the time range of about several mS to several tens of mS. The applicant of the invention has thus proposed, in JP-A-2005-303681 entitled “Noise Reduction Method and Device”, to utilize a masking phenomenon observed in the human sense of hearing to perform noise reduction effectively.
Described now is the masking phenomenon observed in the human sense of hearing. The human being hears no small sound behinda relatively large sound, e.g., people find it difficult to hear any human voice in noisy environment. This is referred to as a masking phenomenon, and has been under study for a long time. Although with some findings that the phenomenon is dependent on the characteristics, e.g., frequency component, sound pressure level, and time of duration, the in-depth mechanism is still under study.
Such a hearing masking phenomenon is broadly grouped under frequency masking and time masking, and the time masking is grouped under simultaneous masking and non-simultaneous masking (referred also to as temporal masking). Such a masking phenomenon is currently utilized for high efficiency coding of compressing an audio signal of a CD (Compact Disk) down to ⅕ to 1/10, for example.
By referring to
The front masking is generally larger in amount than the rear masking, and although depending on the time conditions, the masking phenomenon occurs about several hundreds of mS at the maximum. Under specific conditions, the gap period of
1. The gap period is lengthened when there is a correlation between the signals A and B in terms of frequency band. The gap period is also lengthened if the signals A and B show continuity with respect to their frequencies.
2. The gap period is lengthened not with a single sine wave but with a band signal.
3. When the signals A and B share the same level, the lower the levels of the signals are, the more the gap period is lengthened, and if the levels of the signals are increased beyond a specific value, the gap period shows no change.
4. The gap period is lengthened when the signal B is lower in level than the signal A.
5. The lower the center frequency in a signal is, the more the gap period is lengthened, and the higher the frequency is, the more the gap period is shortened.
As such, in the previous papers, such detection conditions for the length of the gap period are used as a basis to remove the above-described noise, i.e., shock noise, touch noise, and clock noise, without making people perceive, by hearing, the noise removal. In the below description, such conditions are referred to as masking conditions 1 to 5. In JP-A-2005-303681 (i.e., “Noise Reduction Method and Device”), the masking conditions are used as a basis to control the length of the gap period as appropriate at the time of generation of noise. The issue here is that, under conditions like shortening the length of the gap period in the masking conditions, the period of noise to be arisen may be longer than the length of the gap period to be masked in some cases, i.e., when the signals A and B are both a tone signal being close to a sine wave with the masking condition 2, when the level of the signals A and B is relatively high with the masking condition 3, or when the frequency band in the signals A and B is relatively high with the masking condition 5. In such cases, the noise removal does not work accurately for some period of the noise signal.
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The noise to be generated at the seek operation is caused by the vibration of the portion of an actuator. The vibration occurs when the magnetic head 15 is rapidly accelerated or decelerated to move by the VCM 14 to the data read/write position on the disk. When the noise is generated as such, the built-in microprocessor 10 with DSP outputs a noise timing signal 12 to gap period generation means 8. A microphone 1 is any arbitrary microphone unit, and a negative output terminal of the microphone 1 is grounded to a circuit ground (GND), and a positive output terminal is connected to an amplifier (AMP) 2 so that an output signal is derived.
This output signal is supplied to one fixed contact point 4a of a selection switch 4, and then to the other fixed contact point 4b thereof via noise removal means 3. The output signal is also input to level detection means 6 so that the audio level is detected. Thus detected audio level is used as a basis for masking amount determination means 7 to determine the masking amount, and the result is forwarded to the gap period generation means 8. Based on the generation result, i.e., length of a gap period, a signal selected by the selection switch 4 is output from an output terminal 5 via a movable contact point 4c.
Described next is the operation of the noise reduction device of
If an audio signal is input at the same time, it means that the audio signal will be also cut off. In consideration thereof, the level of the audio signal is detected by the level detection means 6, and based on thus detected level, the masking amount determination means 7 and the gap period generation means 8 generate the gap period to be masked by the human sense of hearing. Thus generated gap period is then used as a basis to control the time to connect the movable contact point 4c of the selection switch 4 to the fixed contact point 4b thereof.
By referring to
As to a sensor 18, a negative output terminal is grounded to the circuit ground (GND), and a positive output terminal is connected to an amplifier (AMP) 19 so that an output signal is input to a comparator 20. The output signal is compared in level with a signal of a pre-configured REF (reference) level coming from an input terminal 9. The comparison result is forwarded from the comparator 20 to the gap period generation means 8.
The output signal coming from the amplifier 2 is supplied to the fixed contact point 4a of the selection switch 4, and also to the level detection means 6 so that the audio level is detected. Based on thus detected audio level, the masking amount is determined by the masking amount determination means 7, and the determination result is forwarded to the gap period generation means 8. In accordance with the length of the generated gap period, the signal selected by the selection switch 4 is output from the output terminal 5. The selection switch 4 here is the one whose fixed contact point 4b is grounded to the circuit ground (GND).
Described now is the operation of another exemplary noise reduction device of JP-A-2005-303681, i.e.,
If an audio signal is input at this time, it means that the audio signal will be also cutoff. In consideration thereof, the level of the audio signal is detected by the level detection means 6, and based on thus detected level, the masking amount determination means 7 and the gap period generation means 8 generate the gap period to be masked by the human sense of hearing. Thus generated gap period is then used as a basis to control the time to connect the movable contact point 4c of the selection switch 4 to the side of the fixed contact point 4b (GND) thereof.
When the vibration signal provided by the sensor 18 is of the level higher than the level set by the reference level input, for example, the comparator 20 determines that some shock is currently given. When the level is lower than the reference level, the comparator 20 determines that there is currently no shock. Based on the level provided by the level detection means 6, the masking amount determination means 7 lengthens the gap period under the masking condition 3, more when the audio level is low than being high. Under the masking condition 4, the masking amount determination means 7 controls the gap generation period so that the gap period can be lengthened when the audio level is being decreased rather than being increased over a period of time.
It is thus desirable to provide an audio signal noise reduction device that is an improvement of JP-A-2005-303681, and is capable of reducing even long-lasting noise.
According to an embodiment of the invention, there is provided an audio signal noise reduction device that includes: input means for making an input of one or more audio signals; timing generation means for generating a gap period in accordance with a generation period of noise coming from a noise generation source included in the audio signal; noise removal means for removing the noise from the audio signal; level envelope detection means for continuously detecting a level envelope of the audio signal; coefficient generation means for generating a coefficient for the level envelope in the gap period in accordance with a signal level provided by the level envelope detection means; interpolation signal generation means; level modulation means for subjecting a signal from the interpolation signal generation means to level modulation using the coefficient generated by the coefficient generation means; mixing means for mixing an output from the noise removal means and an output from the level modulation means; and selection means for outputting a signal from the mixing means in a period corresponding to the gap period, and outputting the audio signal not in the gap period.
According to another embodiment of the invention, there is provided an audio signal noise reduction device that includes: input means for making an input of one or more audio signals; timing generation means for generating a gap period in accordance with a generation period of noise coming from a noise generation source included in the audio signal; noise removal means for removing the noise from the audio signal; level envelope detection means for continuously detecting a level envelope of the audio signal; masking amount determination means for determining, in accordance with a signal level provided by the level envelope detection means, a masking level for a human sense of hearing in the gap period; interpolation signal generation means; level modulation means for subjecting a signal from the interpolation signal generation means to level modulation using a coefficient generated by the masking amount determination means; mixing means for mixing an output from the noise removal means and an output from the level modulation means; and selection means for outputting a signal from the mixing means in a period corresponding to the gap period, and outputting the audio signal not in the gap period.
According to still another embodiment of the invention, there is provided an audio signal noise reduction device that includes: input means for making an input of one or more audio signals; timing generation means for generating a gap period in accordance with a generation period of noise coming from a noise generation source included in the audio signal; noise removal means for removing the noise from the audio signal; level envelope detection means for continuously detecting a level envelope of the audio signal; first coefficient generation means for generating, in accordance with a signal level provided by the level envelope detection means, a level coefficient for the level envelope in the gap period; spectrum envelope detection means for continuously detecting a frequency spectrum of the audio signal; second coefficient generation means for generating a spectrum coefficient in the gap period in accordance with spectrum information provided by the spectrum envelope detection means; interpolation signal generation means; level modulation means for subjecting a signal from the interpolation signal generation means to level modulation using the coefficient generated by the first coefficient generation means; mixing means for mixing an output from the noise removal means and an output signal from the interpolation signal generation means via the level modulation means modulating the signal using the coefficient generated by the first coefficient generation means and variable filter means that performs frequency modulation using the coefficient generated by the second coefficient generation means; and selection means for outputting a signal from the mixing means in a period corresponding to the gap period, and not in the gap period, outputting the audio signal.
According to still another embodiment of the invention, there is provided an audio signal noise reduction method that includes the steps of: generating a gap period in accordance with a generation period of noise coming from a noise generation source included in one or more incoming audio signals; detecting continuously a level envelope of the audio signal; generating a coefficient for the level envelope in accordance with a signal level being a detection result; generating an interpolation signal, and subjecting the interpolation signal to level modulation using the coefficient; mixing an output being a result of the level modulation and an output being a result of removing the noise from the audio signal; and outputting a signal being a mixing result in a period corresponding to the gap period, and not in the gap period, outputting the audio signal as it is.
According to still another embodiment of the invention, there is provided an audio signal noise reduction method that includes the steps of: generating a gap period in accordance with a generation period of noise coming from a noise generation source included in one or more incoming audio signals; detecting continuously a level envelope of the audio signal; determining, using a signal level being a detection result, a masking level for a human sense of hearing in the gap period; generating an interpolation signal, and subjecting the interpolation signal to level modulation using a coefficient generated by the masking level determination; mixing an output being a result of the level modulation and an output being a result of removing the noise from the audio signal; and outputting a signal being a mixing result in a period corresponding to the gap period, and not in the gap period, outputting the audio signal as it is.
According to still another embodiment of the invention, there is provided an audio signal noise reduction method that includes the steps of: generating a gap period in accordance with a generation period of noise coming from a noise generation source included in one or more incoming audio signals; detecting continuously a level envelope of the audio signal; generating a level coefficient for the level envelope in accordance with a signal level being a detection result; detecting continuously a frequency spectrum of the audio signal; generating a spectrum coefficient in the gap period in accordance with spectrum information being a detection result; generating an interpolation signal, and subjecting the interpolation signal to level modulation using the level coefficient and to frequency modulation using the spectrum coefficient; mixing an output being a result of the level modulation and an output being a result of removing the noise from the audio signal; and outputting a signal being a mixing result in a period corresponding to the gap period, and not in the gap period, outputting the audio signal as it is.
In the embodiments of the invention, a gap period is subjected to level-envelope interpolation using a signal independently generated so that any long-lasting noise can be reduced.
In the embodiments of the invention, in consideration of time masking being a part of a masking phenomenon observed in the human sense of hearing, any segment of the gap period not to be masked is interpolated so that any long-lasting noise can be reduced.
In the embodiments of the invention, an interpolation signal in the gap period is not only modulated in level but also changed in frequency characteristics so that the signal continuity can be retained, and the masking effects can be increased to a further degree.
In the below, described is an exemplary best embodiment of the invention for a practical use of an audio signal noise reduction device and method by referring to the accompanying drawings. In
In
A noise removal filter 3 is configured by a filter such as BEF (Band Elimination Filter) to attenuate every band including any noise. One or more bands are configured as a target for the BEF. If with an HDD, any vibration of the portion of an actuator occurring when the magnetic head 15 is rapidly accelerated or decelerated to move during the seek operation is checked in advance to see its frequency distribution. The BEF is so set as to filter the frequency band of the vibration noise. Alternatively, the BEF may be provided as a plural to be ready for various modes in accordance with any change characteristics, i.e., seek profile, when the actuator is accelerated or decelerated to move.
Although not shown, for a seek operation in an optical disk unit such as DVD (Digital Versatile Disc), the BEF configuring as the noise removal filter 3 is so set as to filter any band including vibration noise of a tracking motor or others moving a pickup.
Considered here is a case that the noise frequency band is completely cut off by the noise removal filter 3. If this is the case, the audio signal in the band is also removed at the same time, thereby causing a problem that the gap period is possibly sensed by hearing. In consideration thereof, in JP-A-2005-303681, the gap period is suppressed to a range over which the masking effects can serve well for the human sense of hearing so that the noise reduction is carried out.
The concern here is that, with some length of the noise period generated, the length of the noise period becomes longer than the gap period to be masked, thereby causing a problem of not being able to completely remove every period of the noise signal. Accordingly, in this embodiment, an interpolation signal is generated in the gap period for addition in the adder 21 for the aim of increasing the masking effects for human audibility.
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That is, in
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The reason of such signal mixing is that a general audio signal is configured by a tone signal and a random signal. The tone signal has the frequency characteristics showing one or more peaks in a predetermined frequency, and the random signal has the frequency characteristics showing relative flatness. The mixing ratio for use by the mixer 43 is optimized as appropriate in consideration of the noise removal band characteristics of the noise removal filter 3. Alternatively, either the tone signal or the random signal may be set to 0 for the mixing ratio, e.g., only the random signal from the M-sequence signal generator 42 may be used.
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Note that the selection switch 4 of
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If an audio signal is input also at the same time, it means that the audio signal will be also cut off. In consideration thereof, the level of the audio signal is continuously detected by the level envelope detector 25, and based on thus detected level, a masking amount determiner 28 determines the masking amount to be masked by the sense of human hearing. In accordance with the masking amount, the coefficient generator 26 generates a level coefficient for use to subject an interpolation signal to level modulation by the level modulator 24, and the result is output to the adder 21. Herein, the interpolation signal is the one to be generated by the interpolation signal generator 22 and the inverse filter 23, both of which are configured similarly to those in
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Note that, similarly to
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In
Similarly to
The noise removal filter 3 is configured similarly to
For continuously detecting a frequency spectrum of an incoming signal, a spectrum envelope detector 51 detects the level of the incoming signal for every frequency by a fast Fourier transformer (FFT) or a plurality piece of band dividers. A coefficient generator 52 then generates a filter coefficient so as to reproduce the detected frequency spectrum in the variable filter 53. The gap period is thus continuously interpolated not only by level but also by frequency component so that the masking effects can be increased to a further extent. Alternatively, the level envelope detector 25 and the coefficient generator 26 may be replaced by the level envelope detector 25 and the masking amount determiner 28 of
JP-A-2005-303681 (i.e., “Noise Reduction Method and Device”) is simply a noise reduction method in which only a noise generation period is gated utilizing the masking phenomenon observed in the sense of human hearing. In this embodiment, the gap period is subjected to level-envelope interpolation using a signal independently generated so that any long-lasting noise can be also reduced.
Also in this embodiment, in consideration of time-masking being a part of a masking phenomenon observed in the human sense of hearing, any segment of the gap period not to be masked is interpolated so that any long-lasting noise can be reduced.
Further, this embodiment serves effective to remove any click noise and shock noise generally included in an audio signal, especially effective to remove any noise generated in small-sized equipment including therein a microphone, for example.
In this embodiment, a sensor is utilized to detect a noise generation period, and extract any period showing a high noise level. If such a sensor is disposed in the vicinity of a noise generation source, the noise detection can be completed with ease, and if the sensor is provided as a plural, the detection can be done with higher accuracy. If the reference level is adjusted in the comparator, any timing showing the highest noise level can be detected and removed so that the effects of noise removal can be increased even if with a short gap period.
In this embodiment, when the noise generation source is under the control of the microprocessor or others as a seek noise coming from a disk unit, for example, noise timing information exists in advance. Therefore, even if the sensor or others are not used, it can be realized to confine the noise generation period with ease.
In this embodiment, even if any noise band of the gap period is removed using a filter or others, and the audio signal with the noise is completely removed, no problem occurs because the gap period is interpolated in such a manner as to be masked for human audibility. What is more, any band signal other than the noise band is provided with the continuity before and after the gap period so that the gap period to be masked can be advantageously lengthened.
In this embodiment, the audio signal is deemed a result of mixture of a plurality of sine waves. For reproduction of such an audio signal, a periodic signal and a random signal are mixed together repeatedly, thereby enabling to generate the signal with relative ease. Also in this example, the audio signal is not aimed to be reproduced with fidelity, and signal interpolation is performed only to make up for a shortage in the gap period and satisfy the masking conditions.
In this embodiment, since no overshoot or ringing occurs at the time of switching between a normal period and a gap period, and band-broadening because of any harmonic noise does not occur, the masking effects serve advantageously.
In this embodiment, an interpolation signal in the gap period is not only modulated in level but also changed in frequency characteristics so that the signal continuity can be better kept, and the masking effects can be increased to a further degree.
Exemplified in the above embodiments is a case with a single channel with a single microphone. This is surely not restrictive, and it will be easily understood that two or more channels will also do.
While the invention has been described in detail, it is understood that numerous other modifications and variations can be surely devised without departing from the scope of the invention.
It should be understood by those skilled in the art that various modifications, combinations, sub-combinations, and alterations may occur depending on design requirements and the other factors insofar as they are within the scope of the appended claims or the equivalents thereof.
Number | Date | Country | Kind |
---|---|---|---|
2005-342521 | Nov 2005 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
5341457 | Hall et al. | Aug 1994 | A |
5535300 | Hall et al. | Jul 1996 | A |
5742928 | Suzuki | Apr 1998 | A |
5794187 | Franklin et al. | Aug 1998 | A |
5909663 | Iijima et al. | Jun 1999 | A |
6055497 | Hallkvist et al. | Apr 2000 | A |
6862558 | Huang | Mar 2005 | B2 |
7272556 | Aguilar et al. | Sep 2007 | B1 |
7454330 | Nishiguchi et al. | Nov 2008 | B1 |
Number | Date | Country |
---|---|---|
9 6397 | Jan 1997 | JP |
10 111699 | Apr 1998 | JP |
2002 251823 | Sep 2002 | JP |
2002-268696 | Sep 2002 | JP |
2003-223198 | Aug 2003 | JP |
2004-138756 | May 2004 | JP |
2004-138789 | May 2004 | JP |
2005 303681 | Oct 2005 | JP |
Number | Date | Country | |
---|---|---|---|
20070150261 A1 | Jun 2007 | US |