JPH04183120A - Audio equipment - Google Patents

Abstract

PURPOSE:To stop the reduction of S/N by stopping operation of the reference oscillating circuit of digital signal processing circuit, and supplying an audio signal from a tuner circuit to the following step circuit when the receiving level of the tuner circuit is below a predetermined value. CONSTITUTION:While an input changeover circuit 1 is selecting an audio signal from a tuner circuit 2, a control circuit 21 supervises the receiving level of tuner circuit 2 via an A/D converting circuit 20. If the receiving level of tuner circuit 2 drops below a predetermined value due to some reason, the control circuit 21 operates a bypass circuit 11, stops oscillating operation of a reference oscillating circuit 10, and stops operation of A/D converting circuit 5, DSP6, and D/A converting circuit 7. When control moves to this mode, lowering of the S/N due to digital noise can be stopped.

Description

DETAILED DESCRIPTION OF THE INVENTION (A) Field of Industrial Application The present invention relates to an audio device having a digital signal processing circuit.

(B) Prior Art In recent years, digital signal processing technology has advanced, and audio devices have been developed that digitally process audio signals for the purpose of providing sound localization and sound field effects. This is disclosed in, for example, Japanese Patent Laid-Open No. 63-5607.

(c) Problems to be Solved by the Invention By the way, the digital signal circuit of the above-mentioned audio device uses a number of standards such as a reference signal for sampling timing in A/D and D/A conversion, and a reference signal for quantization. Since a signal is required, a large amount of so-called digital noise will be generated. Therefore, when a tuner circuit is used as an audio signal source, digital noise affects the tuner circuit through the air and the ground, so if the reception level decreases, the S/N ratio becomes very poor and the reproduced sound becomes It became difficult to hear.

(d) Means for Solving the Problems The audio device of the present invention has filters with different center frequencies, a digital signal processing circuit for digitally processing an audio signal, and at least a tuner circuit as an audio signal source. a bypass circuit that bypasses the audio signal from the tuner circuit to the digital signal processing circuit; and when the reception level of the tuner circuit is below a predetermined value, the bypass circuit is activated and the digital signal processing circuit is operated. and a control circuit that stops the operation of the reference oscillation circuit.

(e) Operation Since the present invention is constructed as described above, when the reception level of the tuner circuit becomes less than a predetermined value, the operation of the reference oscillation circuit for the digital signal processing circuit is stopped, and the operation of the reference oscillation circuit for the digital signal processing circuit is stopped. The audio signal is given to the subsequent circuit without passing through the digital signal processing circuit.

(F) Embodiment An embodiment of the present invention will be described based on the drawings. FIG. 1 is a block diagram of the audio device of the present invention, in which (1) is an input switch for selecting one of the audio signals from a tuner circuit (2), a cassette tape recorder (3), and a disc player (4). The circuit operates based on the operation of a switching key (not shown) and outputs a signal indicating which audio signal is selected. (5) is an A/I converter circuit that A/D converts the audio signal selected by the input switching circuit (1) at a predetermined sampling frequency. (6) is a digital signal processing sensor (hereinafter referred to as DSP) that processes the digital signal from the A/D conversion circuit (5), and is a secondary IIR (Infi-
It has a seven-stage digital bandpass filter consisting of a single impulse response (nite impulse response) filter, and is designed to divide the frequency band of the audio signal into seven parts. By the way, as disclosed in, for example, Japanese Unexamined Patent Publication No. 62-291212, this digital band-pass filter is capable of adjusting the center frequency (fO) by giving a multiplication coefficient to a coefficient multiplier constituting the digital band-pass filter. Gain (G) and filter sharpness (Q) can be changed.

(7) is a D/A conversion circuit which performs D/A conversion of the output signal of the DSP' (6). (8) is the D/A conversion circuit (
7) is an amplifier that amplifies the output signal; (9) is a speaker. (10) is a reference oscillation circuit that provides a reference signal to the DSP (6), and the DSP (6) divides the frequency of this reference signal to the A/D conversion circuit (5) and the D/A conversion circuit (7). It generates signals for sampling, signals for quantization, etc., and also generates signals for its own operation. (11) is a bypass circuit consisting of an analog switch, which connects the output of the input switching circuit (1) and the amplifier (8
), and the audio signal from the input switching circuit (1) is connected to the A/D conversion circuit (5) and the DSP.
(6) The signal can be supplied to the amplifier (8) without going through the D/A conversion circuit (7). (12) is a display circuit, and as shown in Fig. 2, the operation mode of DSP (6) is O.
0N10FF display lamp (13) that indicates whether it is N or OFF, music source display lamp (14), (15)
), (16) (in this case, jazz, rock, and classical). (17) is a key input circuit, which also sets the operation mode of the DSP (6) as shown in Figure 2.
It consists of a 10FF key (18) and a source selection key (19) for selecting a music source. (20) is an A/D conversion circuit that A/D converts the received level signal of the tuner circuit (2). (21) is a control circuit consisting of a microprocessor, which controls each circuit according to a program written in advance. Note that this control circuit (21) has multiplication coefficients corresponding to jazz, rock, and classical music written in advance in the same manner as the program, and can select one of jazz, rock, and classical music according to the operation of the source selection key (19). The multiplication coefficient is given to the DSP (6), and the equalization according to the selected music source is performed by the DSP (6).
6).

FIG. 3 is a flowchart of the main part of the program written in the control circuit (21), and the operation will be explained below based on this. First, when the power is turned on, the control circuit (
Step 21) sets a predetermined music source (here jazz) (data representing the source is stored in the memory that stores the mode state) and lights up the source display lamp (14) indicating jazz (step S-1
,2). In the initial state, the DSP mode is in the OFF state, so the oscillation operation of the reference oscillation circuit (10) is stopped and the A
/D conversion circuit (5), DSP (6), D/A conversion circuit (
7) is stopped, the bypass circuit (11) is activated, and the output of the input switching circuit (1) is directly connected to the amplifier (8).
) (If the 0N10FF indicator lamp (13) is on, it will be turned off) (Steps S-3 to S-5). In this state, turn the 0N10FF switch (
18) is operated and the DSP mode is turned on,
The control circuit (21) transfers the multiplication coefficient of the set music source (jazz) to the DSP (6), stops the operation of the bypass circuit (11), and starts the reference oscillation circuit (
10) is activated (step 5-6). This results in
Desired equalization can be achieved.

In this state, the 0N10FF indicator lamp (13) is turned on to notify that the DSP mode is ON (step 5-7). If the source selection key (19)
is operated and the music source is changed, the control circuit (2
1) changes the settings to the changed music source, transfers the multiplication coefficient for the music source to the DSP (6), and lights up the source display lamp corresponding to the music source (steps S-8 to S-11). ). This results in
Equalization by D S P (6) can be changed. Further, when the 0N10FF switch (18) is operated and the DSP mode is turned off, the process moves to step S-4 described above.

By the way, the input switching circuit (1) is the tuner circuit (2).
When the audio signal of the control circuit (21
) is connected to the tuner circuit (2) via the A/D conversion circuit (20).
) (Step 5-13.14)
. If for some reason the reception level falls below a predetermined value (for example 40dB) for 3 seconds, the bypass circuit (1
1), and also stops the oscillation operation of the reference oscillation circuit (10), and the A/D conversion circuit (5), DSP (6), and
Stop the operation of the /A conversion circuit (7) (step 5-
15.16). In this state, the control circuit (21
) switches the source display lamp corresponding to the set music source from lighting to blinking to notify that the mode has shifted to the bypass mode (step S-17). Furthermore, by shifting to this mode, the S/N due to digital noise
This can prevent the ratio from decreasing.

When the mode shifts to bypass mode, the control circuit (21
) monitors the reception level of the tuner circuit (2) again,
If the reception level exceeds a predetermined value (for example, 50 dB) for 3 seconds, the operation of the bypass circuit (11) is stopped.
At the same time, the operation of the reference oscillation circuit (10) is restarted (step 5-22.23.19). After the processing, the control circuit (21) returns to step 5-10 described above, causes the DSP (6) to perform equalization using the set music source (music source before shifting to bypass mode), and Change the source display lamp from flashing to lit. Note that if the input switching circuit (1) selects an audio signal other than the tuner circuit (2) while monitoring the reception level, there is no need to consider the influence of digital noise, so the process moves to step 5-19 described above. (Step S-18). Also, when the 0N10FF switch (18) is operated and the DSP mode is turned off (for example, if the reception condition does not improve no matter how many minutes you wait and you want to cancel the DSP mode), the source indicator lamp will turn on. Return to step S-5 and turn on the 0N10FF lamp (1
3) will be turned off. (Step 5-20.21
).

(G) Effects of the Invention The present invention stops the operation of the reference oscillation circuit of the digital signal processing circuit when the reception level of the tuner circuit becomes less than a predetermined value, and passes the audio signal from the tuner circuit through the digital signal processing circuit. Since the signal is configured to be applied to the circuit at the subsequent stage without any interference, it is possible to prevent the S/N ratio from decreasing due to digital noise in the case of a weak electric field.

[Brief explanation of the drawing]

FIG. 1 is a block diagram of the audio device of the present invention, FIG. 2 is an explanatory diagram of the display circuit and key input circuit, and FIG. 3 is a flowchart of the main part of the program written in the control circuit. (6)...DSP, (10)...Reference oscillation circuit, (1
1)... (Ipass circuit, (21)... Control circuit. Applicant: Sanyo Electric Co., Ltd. and 1 other representative Patent attorney Takuji Nishino (2 others) 0”ゝ 1゜

Claims (1)

[Claims] (1) A digital signal processing circuit that has filters with different center frequencies and digitally processes an audio signal, and a tuner circuit as at least an audio signal source, wherein the audio signal from the tuner circuit is processed by the digital signal processing circuit. comprising a bypass circuit that bypasses the circuit, and a control circuit that activates the bypass circuit and stops the operation of the reference oscillation circuit of the digital signal processing circuit when the reception level of the tuner circuit is below a predetermined value. An audio device featuring: