JPS6276316A - Digital filter - Google Patents

Abstract

PURPOSE:To reduce ripples at a flat region by switching polarity of the coefficient of a digital main filter inversely or non-inversely to changeover the main filter to an HPF or LPF. CONSTITUTION:One-sample delay sections 161-16l, multiplication sections 141-14l, and adder sections 131-13l constitute an HPF or an LPF. One-sample delay sections 121-12m and a multiplication section 3 constitute a full band filter 2. Coefficients a1-al fed from the multiplication sections 141-14l are fed to a terminal 9 of a code inverter 10, and the polarity of the coefficients a1-al is switched by a switching signal d2. The coefficients a1-al are set to function windows. In obtaining a high frequency emphasis characteristic, the inverter 10 makes the filter coefficients, except the coefficient am, negative to constitute a high frequency filter 11a and a switch 5 sets a coefficient at1.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention The present invention relates to a digital filter, and more particularly to a digital filter capable of emphasizing and attenuating low or high frequencies of an audio signal.

2. Description of the Related Art Conventional digital filters are generally designed with a focus on the cutoff frequency (center frequency), and do not focus on plateau characteristics in frequency characteristics.

Problems to be Solved by the Invention For the above reasons, the conventional FIR digital filter has a high frequency emphasis characteristic of 1 as shown in FIG. 5(A) and 1 as shown in FIG.
If 2 is designed for the low-frequency emphasis characteristic shown in Figure 2, ripples will occur in the flat-111 frequency characteristic below frequency f1 and above frequency 12, and in both cases, echoes and coloring due to dispersion, that is, the tone will become unnatural. There were changing issues.

On the other hand, in order to reduce ripples in a flat region below frequency f1 and ripples in a flat region above frequency 12, a technique using an IIR digital filter described in, for example, Japanese Patent Laid-Open No. 58-182315 is known. However, since it is an IR digital filter, the phase is non-linear, and the rounding I+' (difference) deteriorates the S/N ratio in the high range, and there is also the problem that it is prone to oscillation.

An object of the present invention is to provide a digital filter that has small ripples in the normal jrI range, can therefore provide a natural tone, and has a good signal-to-noise ratio.

Means for solving the problem In Fig. 1 (A), 2 is an FIR digital all-pass filter (all-pass filter), 5 is a switch, 10 is a sign inverter,
11a and 11b are FIR digital high-pass filters (high-pass filters) or low-pass filters (low-pass filters)
(main filter).

action For example, the FIR digital main filter 11a.

By switching the polarity of the coefficient of coefficient 11b between inverted and non-inverted, the main filters 11a and 11b are switched to high-pass filters and low-pass filters, and the average level of the frequency characteristics to be obtained is equal to the flat level of the frequency characteristics of the whole area filter 2 and the corresponding The main filter 11a is set according to the frequency characteristics to be set so as to correspond to the normal 1u level of the frequency characteristics of the high-pass filter and the low-pass filter, respectively.

11b and the entire range filter 2 are set to substantially add the output of the husband/Z.

Embodiment Figure 1 (△>, (B) is a circuit diagram (hardware configuration) of the first embodiment of the digital filter of the present invention and part 1.
■Illustrated diblock system -jl, in Figure 1 (△), 1 sample R extension section 16 - 162° Higashisuzu section 141~
14, the 17i characteristic KI+ shown by the solid line in FIG. Filter lb is configured, while 1 + J filter ii
t section 121-121Il, s12 section (level adjustment section) 3
A whole range filter (substantially a delay circuit and an attenuator) 2 is configured.

10 is a sign inverter, from a terminal 9 to a filter coefficient supply section (not shown), which multiplies the filters 1a and 11b into a power ci section 141.
The polarity of the coefficients a1 to a2 supplied to ~14fl is switched by the switching signal d2, or the polarity of the input signal supplied from the terminal 11 to the filters 1a and 11b is switched by the switching signal d.
It is configured such that it can be switched at 1. Coefficient F: 11~
a2 is set, for example, to the function window (in the case of the high-pass filter 1a) shown in FIG. 6 (Δ).

Reference numeral 5 is a switch, and switches the ratio a:3 tl, a B shown in No. 61' fl (B) to Tosuibu 3 (1, H=5 (j3
Reno replacement supply by JJru. 7 is a micoating circuit;
11 is formed, and the output of the switching signal (4i and C crimping section (3) is supplied to the terminal 81 (111) and is not supplied.

The output of the whole range filter 2 is supplied to the high pass filter 1a (or to the intermediate tap m of the low pass filter 11b/ii'?, that is, to the gauze part 13m.
The outputs of IJll are added in any of the IJll n sections 132 to 13Ill, and the output is added to b or as shown in Figure 1 (B).
Even if part 6'c addition ζ) is added, the result is the same.

Here, when the high frequency emphasis characteristic MI K 1 shown in FIG.
The high-pass filter 1a is configured as negative except for , and the coefficient a11 is set by the switch 5. In this case, Fig. 5 (△
), the high-pass filter (solid line) and the whole-range filter (
(dashed line) to obtain the high-frequency emphasis characteristic (dashed line) K1.

On the other hand, the low frequency emphasis RfL K 2 shown in FIG.
+′? , the sign inverter 10 changes the filter coefficients to a
Configure the low-pass filter 11b as positive except for Ill,
Switch 5 sets coefficient at2. In this case, the fifth
As shown in Figure (B), the low-pass emphasis characteristic (dashed line) K
2 (qru.

When the sign inverter 10 changes l/J of the switch 5, the inverter 10 activates the inverting circuit 7 at the switching sign d4. ), as shown in
When switching from 7-dore △ to (-does B), there is a very short period (τ
) The data selector inputs the ground side and sets it to the left to set the output to zero. The period of τ is selected to be, for example, τ-2·td (where d is 1 ripple iY extension time). This results in
Cut? No noise is extracted to IF, 'i.

In this way, in the present invention, in particular, the high-frequency emphasis characteristic (,1
A1jl 7 below frequency f1? In the j-characteristic and low-frequency emphasis characteristics, the flat 1-blue characteristic at frequencies f2 and higher involves a whole range filter, so there is less ripple in the upper jf1 region compared to the conventional one.

FIG. 2 shows a circuit diagram of a second embodiment of the filter of the present invention,
In the same figure, the same numbers as in FIG. By simply changing the coefficients a and 1°at2 with the switch 5, the combination of the high 1 FFi filter and the full range filter, and the combination of the low pass filter and the full range filter can be effectively set to 117. , the combination of the high-pass filter and the whole-range filter can be 1q, just as in the first embodiment where the coefficient is set to at1, and which combination U of the low-pass filter and the whole-range filter is set when the coefficient is set to at2. The combination of a low-pass filter and a full-range filter causes a phase inversion in the frequency characteristic r1 of the low-pass filter, but this is due to the fact that audio A (particularly on bad days) ffi
stomach.

These things are cut off at muting circuit 7 by 1% I+￥
Even if you don't take out the noise, of course this can happen.

FIG. 3 shows a circuit diagram of a third embodiment of the filter of the present invention,
In the figure, the same numbers as those in FIG. 1 (△) and FIG.

These are 1! with the coefficient at1 set by switch 5!
1 The coefficient of the code switch 15 is set to -11 (this sets the coefficient at
When setting 2? The coefficient of the J″r′i switch 15 is set to 1. As a result, when the coefficient at2 is set, (
1 (frequency of the filter!!), phase is inverted to the special bamboo characteristic and returned to the normal phase.Other operations are the same as in the first and second embodiments.

41 Oh? As the T switching device 15, one with a different configuration than t b
be. For example, f-ta]A-? Since it is sufficient to invert the MSR when the number 1- is a two's complement number, it is possible to invert one bit of the MSR using an inverter.

Therefore, it is not limited to the power f;5.

FIG. 4 shows a circuit diagram of a fourth embodiment of the filter of the present invention,
In the figure, the same components as in FIGS. 1A and 3 are designated by the same numbers (=j) and their explanations will be omitted.

This one does not have a special whole range filter, but the east exit part 14
Set the coefficient hm of switch 5.

-a l-a 11 and σh m -d m + a
Cut 1 at t2! /! m2 is fixed, and the addition Q part 17
J3 in a, + a mouth and F) 4-21 (
Play 2. East exit (coefficient F of section 1/11 to 1/I2
) In the case of a high-pass filter, P is as shown in FIG. 1)/2
(e is an odd number, for example 45).

This is actually equivalent to the sized circuit diagram shown in FIG.

In addition, in the case of a low-pass filter, the coefficient of No. 11 switch 15 is -
When set to 1, the function 'f1 window in FIG. 8 <C> is set to 15.

'j J3, as shown in Fig. 5(C), in addition to obtaining ↑'IK1°K2, the coefficients of the filter J11~:h e,
h 1 to h as appropriate, and the coefficient a tty
By switching a t2, holding MK1, to 3 (
Keep the low level constant and 'C'! ill! 2 (when enhancing and attenuating) and the characteristic K, 4 (when Ha is balanced) can be reduced to 1!7.

Also, using the above hardware configuration, the digital Shinkyu αjri-cho-jun can be controlled by program software 1~.
,stomach.

Effects of the Invention According to the present invention, the normal characteristic above a predetermined frequency and the STZ 1 mouth Tj FJ: The ripple in < r < si! ? , to this, J.S.
Compared to the conventional FL using a digital filter, it is possible to enhance the level and reduce the level with a more natural tone to the audio signal. , compared to using a digital filter in PI anti-iiλ,
J1 inversion circuit (J can be used to make virtually 111 filters of various iW + It, so the circuit can be constructed more easily and at a lower cost than if a filter is provided separately. 1q1 or filter coefficient ¥1.c'', set up an exhibition and set up a If the system is structured so that the payment is made each time, it has the advantage of being able to shorten the time spent on leave.

[Brief explanation of drawings]

Figures 1 (Δ) and (B) are circuit diagrams and schematic block diagrams of the first embodiment of the filter of the present invention, and Figures 2 to 4 are the second to fourth embodiments of the filter of the present invention. circuit diagram,
Figure 5 shows the frequency characteristics of the filter 11, and Figure 6 shows Figure 1 (
△) The coefficients of the filters shown in Fig. 1 and Fig. 7 are shown in Figure 7. 3 is a diagram illustrating coefficient values of the filter shown in FIG. 1.11... Input terminal, 2... Whole range filter, 3°1/l to 1/1/ip,... Multiplication Q part, 5... Switch, 6°132~13I),...・Ka r, ) part, 7
... Mikotig circuit, 8.81 ... Output terminal, 1
0-71'i inverter, 11a. 11b...high(or,・'(l(lor filter (main filter), 121・~12m, 161~16□...1
Sample bar Nobube. Patent applicant Victor Japan Co., Ltd.? 1 generation I'1' person but l! n t (
J' Tadahiko Higashi! ...pa,・ko'−−
”'ffi・) “ ′,・Sodo Patent Attorney Kanet Matsuura,
, 5.1, ----Go】' Sakae 1 Figure 2 Figure 1 Figure 3 1 Donomaki →

Claims (4)

[Claims] (1) By providing an FIR digital main filter and an FIR digital all-pass filter, and switching the polarity of the coefficients of the FIR digital main filter between inverting and non-inverting, the FI
The R digital main filter is switched to a high-pass filter and a low-pass filter, and the flat level of the frequency characteristics to be obtained is the flat level of the frequency characteristics of the FIR digital all-pass filter and the flat level of the frequency characteristics of the high-pass filter and the low-pass filter. The coefficients of the FIR digital main filter and the FIR digital all-pass filter are set according to the frequency characteristics to be set so as to correspond to the output of the FIR digital main filter and the FIR digital all-pass filter, respectively. A digital filter characterized in that it is configured to add the output of a pass filter. (2) An FIR digital main filter and a FIR digital all-pass filter are provided, and the polarity of the input signal entering the FIR digital main filter is switched between inverted and non-inverted, thereby converting the FIR digital main filter into a high-pass filter and a low-pass filter. should be set so that the flat level of the frequency characteristic to be obtained corresponds to the flat level of the frequency characteristic of the FIR digital all-pass filter and the flat level of the frequency characteristic of the high-pass filter and the low-pass filter, respectively. The coefficients of each of the FIR digital main filter and the FIR digital all-pass filter are set according to frequency characteristics, and the output of the FIR digital main filter and the output of the FIR digital all-pass filter are substantially added. A digital filter characterized by: (3) An FIR digital main filter and an FIR digital all-pass filter are provided, and by inverting or non-inverting the polarity of the output of the FIR digital all-pass filter, the output can be effectively converted into a high-pass filter, an all-pass filter, and a low-pass filter. Switch to each combination of all-pass filters so that the flat level of the frequency characteristics to be obtained corresponds to the flat level of the frequency characteristics of the FIR digital all-pass filter and the flat level of the frequency characteristics of the high-pass filter and the low-pass filter, respectively. , set respective coefficients of the FIR digital main filter and the FIR digital all-pass filter according to the frequency characteristics to be set, so that the output of the FIR digital main filter and the output of the FIR digital all-pass filter are substantially equal to each other. A digital filter configured to add. (4) An FIR digital main filter and an FIR digital all-pass filter are provided, and by inverting or non-inverting the polarity of the output of the FIR digital all-pass filter, the output can be effectively converted into a high-pass filter, an all-pass filter, and a low-pass filter. Switch to each combination of all-pass filters so that the flat level of the frequency characteristics to be obtained corresponds to the flat level of the frequency characteristics of the FIR digital all-pass filter and the flat level of the frequency characteristics of the high-pass filter and the low-pass filter, respectively. , set respective coefficients of the FIR digital main filter and the FIR digital all-pass filter according to the frequency characteristics to be set, so that the output of the FIR digital main filter and the output of the FIR digital all-pass filter are substantially equal to each other. A digital filter characterized in that it is configured to perform addition and then invert the polarity of the addition output.