JPH0279530A - Demodulation circuit for stereo composite signal - Google Patents

Abstract

PURPOSE:To demodulate a digital stereo composite signal with a simple constitution by extracting an (L-R) component among digital stereo composite signals, thinning the component to one over a prescribed number, extracting the lower side band of the (L-R) component and the (L+R) component, thinning them to one over a prescribed number, extracting the L component, subtracting it from the former to extract the R component. CONSTITUTION:The sampling frequency of the output (L+R) component of an LPF 10 is converted into fs/4=38kHz by a decimeter 12. On the other hand, the components of >=fs/4=38kHz are removed by a LPF 16 to obtain the lower side band of the (L+R) component, the (L-R) component and the sampling frequency is converted into fs/4=38kHz by a decimeter 18 and the signal components of 0-38kHz are folded into the components of 38-0kHz by ariasing, and the L component is obtained. Only the R component is obtained by subtracting the output of the decimeter 18 from the output of the decimeter 12. Thus, the L, Rch digital signals are separated from the digital stereo composite signal with the comparatively simple constitution.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a demodulation circuit E for a stereo composite signal, and particularly to a demodulation circuit for a stereo composite signal using a digital signal system.

[Problems to be solved by conventional techniques and inventions] In recent years,
Digital type demodulation circuits that demodulate FM signals are attracting attention due to their good S/N ratio, linearity, and temperature characteristics (for example,

Kobayashi; [Characteristics of Quadrachi medium-sized FM demodulator using digital signal processing technology], Proceedings of the Institute of Electronics and Communication Engineers (B)
, J65-B,? , PP: 890-897 (July 1982), or Ogiwara, Nakayo; [Characteristics of an improved TAN-format FM demodulator using digital signal processing technology], Proceedings of the Institute of Electronics and Communication Engineers (B), J67 -8,5. PP: 5
45-551 (May 1981)).

However, in these conventional techniques, a digital stereo composite signal is demodulated, and separation of RcH is not considered.

From a digital stereo composite signal.

Digital demodulation of RcH may be performed by simply replacing sampling/holding MPX in analog format with digital format, for example, but this method requires extraction of the pilot signal and requires consideration of the phase of the pilot signal. Since digital signal processing must be performed, it is expected that it will be difficult to implement the circuit.

SUMMARY OF THE INVENTION In view of the problems of the prior art, it is an object of the present invention to provide a demodulation circuit for a stereo composite signal using a digital signal system with a simple configuration.

[Means to solve the problem]

In the present invention, a first low-pass filter extracts the (LR) component of the digital stereo composite signal, a first decimator thins out the output of the first low-pass filter to a predetermined number, and a digital stereo composite signal. a second low-pass filter that extracts the (LR) component and the lower sideband of the (L + R) component of the stereo composite signal; and thinning the output of the second low-pass filter to a predetermined fraction. a second decimator for extracting the decimator component; a level adjusting means for adjusting the output of the first decimator and the output of the second decimator to the same level; It is characterized by comprising a subtraction means for subtracting the decimator output to extract the R component.

(Embodiment) Next, one embodiment of the present invention will be described with reference to FIG.

FIG. 1 shows a demodulation circuit for stereo composite signals according to the present invention.

A digital chill stereo composite signal, which is digitally detected from an analog FM stereo signal by an appropriate circuit, is input to the input terminal IN.

The frequency spectrum of this digital stereo composite signal is shown in (1) of FIG.

In this example, the (L+R) component in the range of θ to 15kHz, the 19kHz pilot signal, and the 23kHz to
(L-R) component between 53kHz and 59-75kHz
It is assumed that the sub-audio component of z is included.

Furthermore, the sampling frequency of the digital stereo composite signal is assumed to be r s =152 kHz.

The input terminal IN is divided into two systems, one of which is connected to the first LPF (digital) 10, so that Is/8=
Components above 19kHz are removed.

As a result, the output of the first LPFIO becomes only the (L+R) component (see (2) in FIG. 2).

A first decimator 12 that decimates the data to 174 is connected to the output side of the first LPFIO, and the sampling frequency is converted to fs/4-38kHz.

At this time, since components of 19k)lx or higher are removed in advance by the first LPFIO, other signal components do not overlap with each other due to aliasing in the range of 0 to 19kHz seen in the frequency spectrum.

On the other hand, a second LPF is connected to the input terminal IN as the other system.
16 are connected, and components of fs/4=38kHz or higher are removed (see (3) in FIG. 2).

As a result, the output of the LPF 16 is composed of (L + R) components and (
This is the lower sideband of the L'-R) component.

The second LPF 16 also has a function as a level adjustment means, and the gain of the second LPF 16 is equal to that of the 'l'th LPF.
The gain is set to 1/2 of the gain of 10.

A second decimator 18 that decimates the data to 1/4 is connected to the output side of the second LPF 16, and the sampling frequency is converted to fs/4 = 38kHz, and the frequency spectrum is reduced by aliasing. The signal components seen from 0 to 38 kHz are folded back to 38 to 0 kHz.

As a result, the signal component in the range of 0 to 15 kHz in the frequency spectrum is half the sum of the (L + R) component and the (LR) component, and the L component is obtained ((
4)).

The output side of the first decimator 12 is connected to a subtracter 14 as subtracting means, and the output of the second decimator 18 is subtracted from the output of the first decimator 12.

Therefore, the output of the subtracter 14 has only the R component obtained by subtracting the L component from the (L+R) component in the range of 0 to 15 kHz as seen in the frequency spectrum (see (5) in FIG. 2).

In this way, two first . 2nd LPFlo, 16
and two first. A digital stereo composite signal is generated using a relatively simple configuration of a second decimator 12, 18 and a subtracter I4.

The digital signal of RcH can be separated.

Note that the output of the second decimator 18 and the output of the subtracter 14 contain components of 19 kHz or higher, but the LPF
It is only necessary to treat only frequencies below 19 kHz as effective components, such as by passing through the signal.

Further, in the above embodiment, the target is a digital stereo composite signal that includes sub-audio, but it is also possible to use a signal that does not include sub-audio.

〔Effect of the invention〕

According to the stereo composite signal demodulation circuit according to the present invention, of the digital stereo composite signal,
A first low-pass filter that extracts the (LR) component, and a first low-pass filter that thins out the output of the first filter to a predetermined number.
a decimator, a second low-pass filter that extracts the (LR) component and the lower sideband of the (L + R) component of the digital stereo composite signal, and a second low-pass filter that extracts the lower sideband of the (L + R) component, and a second decimator for thinning out a component by a fraction, a level adjustment means for adjusting the output of the first decimator and the output of the second decimator to the same level, and a first decimator after level adjustment. By providing a subtraction means for subtracting the second decimeter output from the output to extract the R component, a stereo composite 2-tone signal can be obtained from a digital stereo composite signal with a simple configuration, and can demodulate a digital signal of Rct(). This has the excellent effect of providing a demodulation circuit.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing a demodulation circuit for a stereo composite signal according to an embodiment of the present invention, and FIG. 2 is a frequency spectrum diagram illustrating the operation of FIG. 1. Explanation of main symbols +0 + first LPF, +2: first decimator,
14: Subtractor, +6: Second LPF, +8:
Second decimator. Q) To 0 To 2 2

Claims (1)

[Claims] Of the digital stereo composite signal, (L-R
); a first decimator that thins out the output of the first low-pass filter to a predetermined number;
component and the lower sideband of the (L+R) component.
a low-pass filter, a second decimator that thins out the output of the second low-pass filter to a predetermined number and extracts the L component, and adjusts the output of the first decimator and the output of the second decimator to the same level. 1. A demodulation circuit for a stereo composite signal, comprising: a level adjustment means for subtracting a second decimeter output from a first decimeter output after level adjustment to extract an R component.