JPH1141048A - Digital bus boost circuit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a digital bus boost circuit whose dynamic range is improved by ensuring a prescribed bus boost characteristic independently of an amplitude of an input signal almost without clipping the input signal. SOLUTION: This circuit is provided with a low pass filter 101 that provides an output of a signal with an emphasized low frequency component of a digital input signal, a D/A converter 102 that converts an output of the low pass filter 101 into an analog signal, an amplifier 103 that amplifies an output of the D/A converter 102 to provide an output, and a control circuit 104 that controls the operation of the low pass filter 101 and the amplifier 103. When the digital bus boost circuit is active, the gain of the low pass filter 101 is set to +3dB for low frequencies and to -6dB for high frequencies, white the grain of the amplifier 103 is set to +6dB for both the low and high frequencies.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a digital bass boost circuit for emphasizing low frequencies of a digital signal.

[0002]

2. Description of the Related Art As a digital bus boost circuit of this kind, specifications such as a digital filter SM5853AF manufactured by Nippon Precision Circuits ('95 NPC DATA BO
OK I AUDIO p418) is known.
This digital bus boost circuit changes the amplitude of an output signal according to the amplitude and frequency of an input signal.

First, the operation when the frequency of the input signal is low will be described. When the amplitude of the input signal is -30.1 dB or less, the amplitude of the input signal is changed from +20 dB to +14 dB.
The signal is amplified by the gain B and output. Input signal amplitude is -3
From 0.1 dB to -3.4 dB, -16.1 dB
To -3.4 dB according to the amplitude of the input signal. When the input signal amplitude is -3.4 dB to 0 dB, the output is performed at the input signal level.

As the frequency of the input signal increases, the gain of the output signal with respect to the input signal decreases.
That is, the lower the input signal, the higher the gain, and the higher the input signal, the lower the gain. Thus, the digital bus boost characteristic is realized.

[0005]

In the above-mentioned conventional digital bus boost circuit, since the input / output signal is operated within a limited operation word length, the gain in the bass boost band should not exceed 0 dB. To prevent signals in the bass boost band from clipping. for that reason,
It is necessary to perform gain adjustment according to the amplitude of the input signal. When a signal having an amplitude close to 0 dB is input,
Fixed bass boost characteristics cannot be obtained. Conversely, in order to always obtain a constant bass boost characteristic regardless of the input signal amplitude, the signal amplitude in the high frequency range must be reduced, and the dynamic range is narrowed by the bass boost characteristic.

Therefore, the present invention provides a digital bus boost circuit which can secure a constant bass boost characteristic independent of the amplitude of an input signal without almost clipping the input signal of a commercially available compact disk or the like. The purpose is to do.

[0007]

A digital bass boost circuit according to the present invention comprises a low-pass filter for amplifying the amplitude of a digital input signal in a low band and attenuating it in a high band, and converting a digital output signal of the low-pass filter into an analog signal. A D / A converter for conversion, an amplifier for receiving an analog output signal of the D / A converter and amplifying the signal with a predetermined gain, and a control circuit for switching on / off of the low-pass filter and the amplifier. When the low-pass filter and the amplifier are turned on by switching of the control circuit, the gain of the low-pass filter is set to a value exceeding 0 dB in a low band, and the gain exceeding 0 dB in a low band from a desired bass boost characteristic in a high band. Set to the value subtracted by the minute,
When the high-pass and low-pass gains of the amplifier are set to values that compensate for the high-pass attenuation of the low-pass filter, the low-pass filter is turned off when the low-pass filter and the amplifier are turned off by switching the control circuit. And the gains of the amplifier in the low band and the high band are set to 0 dB.

With the above arrangement, when the digital bus boost circuit is on, almost no input signal from a commercially available compact disc or the like is clipped, and a constant bus boost characteristic is always maintained irrespective of the input signal amplitude. can do.

In the configuration of the present invention described above, it is preferable that the number of bits of the input signal of the low-pass filter is equal to the number of bits of the output signal, thereby suppressing an increase in the operation word length.

As a preferred specific configuration, the low-pass filter gain can be set to about +3 dB. In this case, the input signal of a commercially available compact disc or the like is hardly clipped, and a constant bass boost characteristic is always secured regardless of the input signal amplitude.
A reduction in the dynamic range can be avoided.

[0011]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing an embodiment of a digital bus boost circuit according to the present invention. In FIG. 1, a control circuit 104 includes, for example, a switch, and controls on / off of the digital bus boost circuit by controlling on / off of the low-pass filter 101 and the amplifier 103.

The low-pass filter 101 sets the number of bits N of the input signal and the output signal to 16 bits, and when turned on by the control circuit 104, +3 dB in the low band.
In order to always maintain a constant bass boost characteristic (for example, a gain difference of 9 dB) in a high frequency range, −6 is set.
Set to dB. On the other hand, when the low-pass filter 101 is turned off by the control circuit 104, the frequency characteristics of the low-pass filter are flattened in all bands, and the gain is set to 0 dB.

The D / A converter 102 converts the digital signal output from the low-pass filter 101 into an analog signal. The amplifier 103 includes, for example, a non-inverting amplifier circuit using an operational amplifier, and receives and amplifies an output signal of the D / A converter 102. When turned on by the control circuit 104, the low-pass filter 101 compensates for the gain of −6 dB attenuated in the high band by +6
Amplify with a gain of dB. On the other hand, when turned off by the control circuit 104, the amplifier 103 sets the gain to 0 dB.
To output an analog signal.

FIG. 2 shows a configuration example of the low-pass filter 101 in FIG. In FIG. 2, a multiplier 211 multiplies an input signal by a ₁ and outputs the result. The adder 201 is a multiplier 21
1 and the output of the multiplier 212 are added and output. The delay unit 221 delays the output of the adder 201 by one clock of the sampling frequency (hereinafter referred to as fs). The multiplier 212 multiplies the output of the delay unit 221 by b ₁ and outputs the result.
The multiplier 213 multiplies the output of the adder 201 by a ₂ and outputs the result. The adder 202 adds the output of the multiplier 213 and the output of the multiplier 214 and outputs the result. The delay unit 222 delays the output of the adder 202 by one clock of fs. The multiplier 214 multiplies the output of the delay unit 222 by b ₂ and outputs the result. The multiplier 215 multiplies the input signal by a ₃ and outputs the result. The adder 203 adds the output of the multiplier 215 and the output of the adder 202 and outputs the result, which is the output of the low-pass filter 101.

The operation of the digital bus boost circuit configured as described above will be described below. First, the transfer function H1 (z) of the low-pass filter 101 is represented by the following equation (Equation 1).

[0016]

(Equation 1)

When the digital bus boost circuit is turned on by the control circuit 104, the transfer function H1
Each coefficient of (z) is quantized by 10 bits, and a ₁ = 12,
a ₂ = 11, a ₃ = 256, and b ₁ = b ₂ = 500. The transfer function H2 (z) of the low-pass filter 101 at this time
Is given by the following equation (Equation 2).

[0018]

(Equation 2)

The sampling frequency fs is 44.1 kHz
When a digital signal of 0 dB is input, the output signal amplitude of the low-pass filter 101, that is, the frequency characteristic of the gain of the low-pass filter 101 is +3 dB in the low band and −6 dB in the high band as shown in FIG. The digital output signal of the low-pass filter 101 is supplied to the D / A converter 1
02 is converted to an analog signal and amplified by the amplifier 103. Assuming that the gain of the amplifier 103 is +6 dB in both the low band and the high band, the output signal amplitude of the amplifier 103, that is, the frequency characteristic of the entire digital bass boost circuit is +9 dB in the low band and 0 dB in the high band as shown in FIG. , And a constant bass boost characteristic is always obtained.

When the digital bus boost circuit is turned off by the control circuit 104, each coefficient of the transfer function H1 (z) of the equation (Equation 1) is quantized by 10 bits, and a ₁
= A ₂ = 0, a ₃ = 512 and b ₁ = b ₂ = 0. The transfer function H3 (z) of the low-pass filter 101 at this time is shown in (Equation 3).

[0021]

(Equation 3)

At this time, the frequency characteristic of the gain of the low-pass filter 101 is 0 dB in the entire band. The digital output signal of the low-pass filter 101 is converted to an analog signal by the D / A converter 102 and amplified by the amplifier 103. The frequency characteristic of the analog output of the amplifier 103 is also set to 0 dB in the entire band. As a result, when the digital bus boost circuit is off, the gain becomes 0 dB in the entire frequency band, and the digital input signal is analog-output with the same frequency characteristics.

This digital bus boost circuit has a constant bus boost characteristic (for example, about 9 dB) when it is turned on.
In order to obtain the gain difference between the low-pass filter 101 and the high-pass filter, the respective coefficients are set so that the low-frequency gain of the low-pass filter 101 is approximately +3 dB and the high-frequency gain is approximately −6 dB, as shown in FIG. Amplifies the gain of +6 dB. If a signal having a low-frequency amplitude of 0 dB is input to the low-pass filter 101, the low-pass filter 101
Output signal is clipped, but there is practically no signal having an amplitude close to 0 dB except for a test disk for audio or the like. In most existing signal sources (music signal sources: compact disk, mini disk, DAT, etc.), the amplitude of the included signal is less than about −3 dB. Therefore, even if the low-pass gain of the low-pass filter 101 is set to about +3 dB, the input signal hardly clips.

In this way, a fixed bass boost characteristic can be always secured without almost clipping the input signal of a commercially available compact disk or the like and irrespective of the input signal amplitude. Then, a decrease in the dynamic range can be prevented without increasing the operation word length.

Note that the specific configuration of the low-pass filter 101 is not limited to the one illustrated in FIG. 2. If the frequency characteristic shown in FIG. 3 is obtained, a finite impulse response filter configuration, an infinite impulse response filter configuration, or , A filter composed of these combinations may be used. Further, the number N of input / output bits and the coefficients a ₁ ,
_{a 2, a 3, b 1} , for b ₂ is also not necessarily limited to the specific values mentioned in the embodiment. In addition, regarding the frequency characteristics of the gain near DC lower than the bass boost band,
It is not necessary to particularly define, and any characteristics may be used.

[0026]

According to the present invention as described above,
The gain of the low-pass filter is set to a value exceeding 0 dB in the low range, and the gain is set to a value obtained by subtracting the gain exceeding 0 dB in the low range from the desired bass boost characteristic in the high range.
By applying a predetermined gain by the subsequent amplifier, a constant bass boost characteristic can be always obtained without almost clipping an input signal of a commercially available compact disk or the like. As a result, the dynamic range can be improved without increasing the operation word length.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a digital bus boost circuit according to an embodiment of the present invention.

FIG. 2 is a block diagram showing a configuration example of a low-pass filter in the digital bus boost circuit of FIG. 1;

FIG. 3 is a diagram illustrating frequency characteristics of the low-pass filter of FIG. 2;

FIG. 4 is a diagram illustrating frequency characteristics of the digital bus boost circuit of FIG. 1;

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 101 Low-pass filter 102 D / A converter 103 Amplifier 104 Control circuit 201-203 Adder 211-215 Multiplier 221 and 222 Delayer

Claims (3)

[Claims] 1. A low-pass filter that amplifies the amplitude of a digital input signal in a low band and attenuates it in a high band, a D / A converter that converts a digital output signal of the low-pass filter into an analog signal, and the D / A. An amplifier that receives an analog output signal of the converter and amplifies the signal with a predetermined gain;
And a control circuit for switching on / off the low-pass filter and the amplifier. When the low-pass filter and the amplifier are on by switching the control circuit, the gain of the low-pass filter is set to a value exceeding 0 dB in a low band. In the high frequency range, a value obtained by subtracting a gain exceeding 0 dB in the low frequency range from the desired bass boost characteristic is set, and the gain in the high frequency range and the low frequency range of the amplifier is reduced by the attenuation in the high frequency range of the low-pass filter. A digital bus for setting the low-pass filter and the amplifier to 0 dB when the low-pass filter and the amplifier are turned off by switching the control circuit. Boost circuit. 2. The digital bus boost circuit according to claim 1, wherein the number of bits of the input signal of the low-pass filter is equal to the number of bits of the output signal. 3. The digital bass boost circuit according to claim 2, wherein the low-pass filter has a low-frequency gain of about +3 dB.