JPH0715281A - Noise shaping device - Google Patents

Abstract

PURPOSE:To reduce quantizing noise in the sense of hearing by matching the amplitude frequency characteristic of the quantizing noise of a digital signal with a hearing sensitivity characteristic to be changed corresponding to a noise level. CONSTITUTION:The level of the input signal of (m) bits is detected by a level detector 3, and the decided result of the detected level at a level decider 4 is inputted to a filter coefficient storage memory 5. The filter coefficient storage memory 5 previously stores filter coefficients for matching the amplitude frequency characteristic of the quantizing level noise with the hearing sensitivity characteristic to be changed corresponding to the level of the input signal of (m) bits, and the characteristic of a variable filter 6 is decided by the filter coefficient selected corresponding to the level decided by the level decider 4. Next, difference between the input signal of (m) bits and the output signal of (n) bits requantized by a quantizer 7 outputted from an adder 2 is inputted to the variable filter 6 and as a negative feedback signal, the output of the variable filter 6 is added to the input signal of (m) bits.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a noise shaping device for audibly reducing quantization noise by matching the amplitude frequency characteristic of the quantization noise of a digital signal with the human auditory sensitivity characteristic.

[0002]

2. Description of the Related Art In recent years, digital audio equipment has been widely used. In this digital audio device, the reduction of quantization noise that is always generated when quantizing an analog signal is the most important issue. This quantization noise is A /
The ΔΣ modulator has been conventionally used as a means for efficiently reducing the quantization noise, which depends on the accuracy of the D converter. Hereinafter, a conventional ΔΣ modulator will be described with reference to the drawings. FIG. 4 shows a block diagram of a conventional first-order ΔΣ modulator. In FIG. 4, 20 and 21 are adders and 2
3 is a quantizer, 22 is a 1-sample delay device, 24 is an input terminal, and 25 is an output terminal. In the adder 21, the quantization noise q (z) obtained by subtracting the input signal input to the quantizer 23 from the output signal quantized by the quantizer 23 is 1 in the 1-sample delay unit 22. After the sample delay, the adder 20 subtracts the input signal from the input terminal 24. By performing error feedback in this way, the quantization noise q (z), which does not have the conventional frequency characteristic, has the frequency characteristic.

The signal transfer characteristic of this first-order ΔΣ modulator is obtained. Assuming that the input signal is x (z), the output signal is y (z), and the quantization noise generated by the quantizer 23 is q, y (z)-{x (z) -q * z- ¹ } = q When this formula is arranged, y (z) = x (z) + (1-z ⁻¹ ) q. Therefore, when the quantization noise Ns generated before and after the quantization is Ns = y (z) -x (z) and z ⁻¹ = exp (−jωT) is substituted, the quantization noise Ns becomes Ns = (1 −exp (−jωT)) q. Power Ns ^{is, Ns 2 = (1-exp} (-jωT)) 2 q 2 = 4sin 2 (ωT / 2) can be obtained as q ^2. Therefore, the quantization noise q having no frequency characteristic has its frequency characteristic changed by the first-order ΔΣ modulator. FIG. 3 shows quantization noise when an analog signal is quantized into 20 bits without using a ΔΣ modulator, and amplitude frequency characteristics of quantization noise generated when a 20-bit input signal is requantized into 16 bits. ,
The amplitude frequency characteristic of the quantization noise generated when re-quantizing a 20-bit input signal whose frequency characteristic has been changed by using a conventional ΔΣ modulator into 16 bits is shown. Further, a ΔΣ modulator type digital filter in which the frequency characteristic of the quantization noise is approximated to an equal loudness curve which is one of human auditory characteristics by increasing the order of the ΔΣ modulator is also used.

[0004]

However, the above configuration has a problem in that the frequency characteristic of the quantization noise Ns is not sufficiently approximate to the human auditory sensitivity characteristic. In particular, if the order of the ΔΣ modulator is increased in order to reduce the quantization noise in the midrange, as shown in FIG. 3, the increase in the quantization noise in the high range will adversely affect the hearing. There were also problems. Further, human auditory sensitivity characteristics are characterized in that they change according to the level of the sound that can be heard.
However, the conventional noise shaping device uses a ΔΣ modulator type noise shaping filter having a fixed characteristic that is predetermined regardless of the level of the input signal, and the human auditory sensitivity that changes according to the noise level. There was also a problem that it did not match the characteristics.

The noise shaping device of the present invention has been made in order to solve the above-mentioned conventional problems. Even if the level of the input signal changes, the amplitude frequency characteristic of the quantization noise becomes the frequency characteristic of human hearing sensitivity. An object of the present invention is to provide a noise shaping device that can be matched.

[0006]

In order to achieve the above object, a noise shaping device of the present invention has a quantizer for requantizing an m-bit input signal and n bits requantized by the quantizer. A second adder for adding an m-bit input signal as a subtraction signal to the output signal of, a variable filter for changing the amplitude frequency characteristic of the quantization noise which is the output of the second adder, and a variable filter output A first adder for adding to the m-bit input signal as a feedback signal of
Level detection means for detecting the level of the m-bit input signal, level determination means for determining the level of the m-bit input signal detected by the level detection means, and human hearing sensitivity characteristics that change according to the sound pressure level Corresponding to the output of the level determining means, the filter coefficient storing means stores the filter coefficient for giving the variable filter the amplitude frequency characteristic of the quantization noise obtained in advance. There is.

[0007]

According to the present invention, in the above structure, the m-bit input signal is requantized, and the requantized n-bit addition output signal and the m-bit subtraction input signal are added by the second adding means. , The difference, the quantization noise, is input to a variable filter that changes the amplitude frequency characteristic, and the variable filter output is added as a negative feedback signal to the m-bit input signal by the first adding means. On the other hand, the level of the m-bit input signal is detected by the level detection means and added to the level determination means to determine the level. From the filter coefficients stored in advance in the filter coefficient storage means, the filter coefficient according to the level of the input signal determined by the level determination means is selected, and the variable filter is
The selected filter coefficient acts so as to have a predetermined characteristic.

[0008]

Embodiments of the present invention will be described below with reference to the drawings. 1 is a block diagram of a noise shaping device according to a first embodiment of the present invention. The noise shaping device of FIG. 1 is provided with an input terminal 8 for inputting an m-bit digital signal, and the m-bit input signal input to the input terminal 8 is branched into two, one of which is a first signal. It is input to the adder 1 which is an adder, and the other is input to the level detector 3 to control the coefficient of the variable filter 6.
Entered in. The output of the adder 1 is branched into two, and one of them is added to a quantizer 7 which requantizes an m-bit input signal and outputs an n-bit digital signal (where m>
n). The n-bit output of the quantizer 7 is branched into two, one of which is output from the n-bit output signal terminal 9 and the other is added to the adder 2 which is the second adder.
The other output of the adder 1 is added to the adder 2 as a subtraction signal. The output of the adder 2 is added as a subtraction signal to the adder 1 via the variable filter 6.

On the other hand, the output of the level detector 3 is input to the filter coefficient storage memory 5 via the level determiner 4, and the filter coefficient is given to the variable filter 6.

The operation of the first embodiment of the present invention constructed as above will be described below.

First, an m-bit input signal branched to control the variable filter 6 will be described. The level detector 3 detects the level of the m-bit input signal every k samples. The level of the m-bit input signal at time t is the average of the absolute values of the amplitude of the input signal from time (t−k * Ts) to time t. Ts is a sampling period. The level thus detected is determined by the level determiner 4, and the determined level is input to the filter coefficient storage memory 5.

Now, the coefficients stored in advance in the filter coefficient storage memory 5 will be described. First, FIG. 5 shows an equal loudness curve used in this example. Figure 5
The vertical axis of is the sound pressure level at which a human actually perceives a reference sound of constant sound pressure, and the horizontal axis is the frequency. Each curve in FIG. 5 represents that when the sound pressure level of the reference sound is changed, the frequency characteristic of the sound pressure level that a person actually feels changes. According to this characteristic, a filter coefficient for matching the amplitude frequency characteristic of the quantization noise with the human auditory sensitivity characteristic that changes according to the level of the input signal is obtained in advance and stored in the filter coefficient storage memory 5 as shown in FIG. There is. In the filter coefficient storage memory 5, a filter coefficient corresponding to the level of the input signal determined by the level determiner 4 is selected, and the selected filter coefficient is sent to the variable filter 6,
The characteristic of the variable filter 6 is determined.

Next, the m-bit input signal input to the adder 1 will be described. The output of the adder 1 is 2
In order to take the difference with the addition signal requantized by the requantizer 7, one is requantized by the quantizer 7 and output as an n-bit digital signal, It is input to the adder 2 as a subtraction signal. The output of the adder 2 is input to the variable filter 6 whose characteristic is determined as described above in accordance with the level of the m-bit input signal, and the output of the variable filter 6 is added as a negative feedback signal to the adder. Returned to 1. The above process is repeated.

FIG. 3 shows amplitude frequency characteristics of quantization noise when the present embodiment is used when requantizing a 20-bit input signal into a 16-bit signal. The solid line shows the amplitude frequency characteristics of the quantization noise when the input signal level is A and the broken line is the input signal level B. However, B> A. As shown in FIG. 3, the characteristic of the variable filter 6 is determined by the filter coefficient selected in the filter coefficient storage memory 5 according to the level of the input signal, so that the amplitude frequency characteristic of the quantization noise changes with time. It is possible to match the human auditory sensitivity characteristic that changes according to the level of the input signal being input.

FIG. 2 shows a second embodiment of the present invention. The second embodiment is characterized in that a coefficient interpolator 10 is used in addition to FIG. 1 of the first embodiment. Components having the same functions as those in FIG. 1 are designated by the same reference numerals, and detailed description thereof will be omitted. The level of the m-bit input signal input from the input terminal 8 is detected by the level detector 3 every k samples, and the level is determined by the level determiner 4. In the filter coefficient storage memory 5, similarly to the first embodiment, the filter coefficients stored in advance are selected according to the level of the input signal determined by the level determiner 4 and input to the coefficient interpolator 10. It In the coefficient interpolator 10, the time (t−
The filter coefficient corresponding to the level of the input signal of k * Ts) is stored, and when the filter coefficient corresponding to the level of the input signal of time t is input, the time (t−k * Ts)
The interpolation calculation of the filter coefficient at time (t−k * Ts) and the filter coefficient at time t is performed so that the variable filter at time t is smoothly changed to the variable filter at time t. The interpolation coefficient calculated by the coefficient interpolator 10 is the time (t−k * T).
By determining the characteristic of the variable filter 6 between s) and time t, the amplitude frequency characteristic of the quantization noise from time (t−k * Ts) to time t is smoothly changed.
Although the interpolation calculation between the filter coefficients between two times has been described above, the interpolation calculation between three or more times may be performed. Therefore, according to this embodiment, when the variable filter is changed, there is no audible unnaturalness.

In the first and second embodiments, the filter coefficient storage memory 5 is used, but instead of the filter coefficient storage memory 5, the input coefficient is changed depending on the approximate expression of the built-in equal loudness characteristic. It is also possible to use a filter coefficient calculator (means) for calculating so that the filter coefficient has the target characteristics in the above embodiment.

[0017]

As described above, according to the present invention, m
By controlling the filter coefficient given to the variable filter according to the level of the bit input signal, the amplitude frequency characteristic of the requantization noise can be changed with time. By matching the amplitude frequency characteristic of the quantization noise with the auditory sensitivity characteristic, it is possible to provide a noise shaping device that reduces the feeling of noise.

[Brief description of drawings]

FIG. 1 is a block diagram of a noise shaping device according to a first embodiment of the present invention.

FIG. 2 is a block diagram of a noise shaping device according to a second embodiment of the same.

FIG. 3 is an amplitude frequency characteristic diagram of quantization noise common to the embodiment of the present invention and the conventional ΔΣ modulator.

FIG. 4 is a block diagram of a conventional first-order ΔΣ modulator.

FIG. 5 is an explanatory diagram of an equal loudness curve.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 adder (first adder) 2 adder (second adder) 3 level detector (level detection means) 4 level determiner (level determination means) 5 filter coefficient storage memory (filter coefficient storage means) 6 Variable filter 7 Quantizer 8 Input terminal 9 Output terminal 10 Filter coefficient interpolator (filter coefficient interpolation calculation means)

Claims (3)

[Claims] 1. A quantizer for requantizing an m-bit input signal, and an n-bit output signal (m> n) requantized by the quantizer, wherein the m-bit input signal is used. Is added as a subtraction signal, a variable filter that changes the amplitude frequency characteristic of the quantization noise that is the output of the second adder, and the output of the variable filter as a negative feedback signal A first adder for adding to the bit input signal, a level detecting means for detecting the level of the m-bit input signal, and a level determining means for determining the level of the m-bit input signal detected by the level detecting means. And the amplitude frequency characteristic of the quantization noise obtained in advance corresponding to the output of the level determination means so as to match the human auditory sensitivity characteristic that changes according to the sound pressure level. Noise shaping device having a filter coefficient storage unit that filter coefficients are stored for giving to. 2. A quantizer for requantizing an m-bit input signal, and an m-bit input signal added as a subtraction signal to the n-bit output signal requantized by the quantizer. A second adder, a variable filter that changes the amplitude frequency characteristic of the quantization noise that is the output of the second adder, and the output of the variable filter as a negative feedback signal to the m-bit input signal. A first adder for adding, a level detecting means for detecting a level of an m-bit input signal, a level determining means for determining a level of the m-bit input signal detected by the level detecting means, and a sound pressure level In accordance with the output of the level determining means so as to match the human auditory sensitivity characteristic that changes in accordance with Noise shaping device comprising a filter coefficient storage unit that filter coefficients are stored, and a filter coefficient interpolation calculation means for calculating a filter coefficient as a filter coefficient output from the filter coefficient memory means is gradually changed for. 3. A filter coefficient calculation means for calculating a filter coefficient so as to match the characteristic of the variable filter with the human auditory sensitivity characteristic in accordance with the output of the level determination means, instead of the filter coefficient storage memory. 1 or 2
The noise shaping device according to 1.