JP2917273B2 - Noise reduction device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The noise reduction device of the present invention will be described according to the following items.

A. Industrial application fields B. Summary of the invention C. Prior art [Fig. 2] a. General background b. Conventional example [Fig. 2] D. Problems to be solved by the invention [Fig. 3] E. Means for Solving the Problems F. Embodiment [FIG. 1] a. Circuit b. Operation G. Effects of the Invention (A. Industrial Applications) The present invention relates to a novel noise reduction device. More specifically, the present invention relates to a novel noise reduction device that includes an encoder and a decoder, in which both the encoder and the decoder are configured by a feedforward loop, thereby enabling digitization of the noise reduction device.

(B. Summary of the Invention) The noise reduction device of the present invention can stabilize the reproduction output by configuring both the encoder and the decoder in the feedforward loop in the noise reduction device having the encoder and the decoder, and can achieve the phase rotation. It is possible to provide a noise reduction device that can be digitized without any noise.

(C. Prior art) [Fig. 2] (a. General background) A noise reduction circuit, a so-called noise reduction (NR), has been considered as a noise countermeasure for a cassette tape having a low tape speed. This is to automatically amplify and record only low-level signals prior to recording, and then automatically lower the playback amplification level during playback and reverse the playback to achieve the NR effect. Things.

(B. Conventional Example) [FIG. 2] FIG. 2 shows an example a of a conventional complementary noise reduction device.

The NR circuit a is composed of an encoder b for amplifying a small-level signal before recording and a decoder c for returning an encoded original signal to an original signal.

The encoder b comprises an adder d forming a feedforward loop, a multiplier e for a coefficient β, and an amplifier f having a gain of -1.

Reference numeral g denotes a recording / reproducing circuit which records a signal from the encoder b on a recording medium, for example, a cassette tape, and reproduces the signal.

h is an adder of the decoder c. The signal from the adder h is amplified by the amplifier i having a gain of -1, and is then multiplied by β by the multiplier j to return to the adder h again. , A feedback loop is formed.

Thus, the input signal is-(1+
β) times, the signal is recorded on a tape by a recording / reproducing circuit g, and is reproduced by a decoder c during reproduction. Since the signal is amplified twice and reproduced, noise at the reproducing stage generated from the tape or the head can be reduced.

Since a normal noise reduction device is mainly used for a device (for example, a tape deck or the like) requiring both a recording system and a reproduction system, a changeover switch k is provided as shown in FIG. Switching of the encoder / decoder is realized on the same circuit by switching k.

(D. Problems to be Solved by the Invention) [FIG. 3] However, when attempting to digitize the above-described method, one of the encoder and the decoder is formed as a feedback loop having no delay element. (1) The output value within one sampling period is fed back via the multiplier and enters the adder again, affecting the output value, and the output value is not determined.

Therefore, it is conceivable to insert a delay element 1 between the multiplier and the adder as shown in FIG.

By doing so, the output value is determined, but this time, a problem occurs around the phase of the feedback value. For example, in the audio band, when the sampling frequency f _s = 44.1 KHz and the maximum audible frequency f _Max = 20 KHz, the phase circumference is converted to 20 KHz. It will be a level that can not be ignored.

(E. Means for Solving the Problems) In order to solve the above-mentioned problems, the noise reduction device of the present invention uses a complementary noise reduction device having an encoder and a decoder in the following (a) to (a). It has the configuration shown in d).

(B) Both the encoder and the decoder are configured as a feedforward loop.

(B) The encoder applies a first signal to the input signal and the input signal.
And a configuration in which the result of addition with the signal multiplied by the coefficient is amplified and output.

(C) The decoder is configured to amplify and output the addition result of the input signal and a signal obtained by multiplying the input signal by a second coefficient.

(D) The relationship between the first coefficient and the second coefficient is defined so that the product of the transfer function of the encoder and the transfer function of the decoder becomes 1.

Therefore, according to the present invention, since either the encoder or the decoder is not constituted by a feedback loop, it is possible to obtain a fixed reproduction output without phase rotation, and it is possible to provide a noise reduction device corresponding to digitization. Become.

(F. Embodiment) [FIG. 1] FIG. 1 is a block diagram showing an example 1 of an embodiment of a noise reduction device according to the present invention.

(A. Circuit) Reference numeral 2 denotes an encoder. The encoder 2 includes an adder 3 forming a feedforward loop, a multiplier 4 for a coefficient β, and an amplifier 5 having a gain of -1.

That is, one of the input signals branched at one point on the main line is directly input to the adder 3, and the other is input to the multiplier 4 of the coefficient β.
, And the output of the adder 3 is input to the amplifier 5.

Reference numeral 6 denotes a recording / reproducing circuit which records an encoded input signal on a recording medium and reproduces the recorded signal.

Numeral 7 denotes a decoder connected to the reproducing side of the recording / reproducing circuit 6, which comprises a multiplier 8 and an adder 9 which also form a feedforward loop, and an amplifier 10 having a gain of -1. (B. Operation) The operation of the noise reduction device of the present invention is as follows.

First, an input signal (X) is encoded by the encoder 2 to obtain an output signal (Y).
It should be noted that the output signal Y is β
The sum with the doubled βX is equal to the value multiplied by −1 by the amplifier 5, ie, − (1 + β) · X. Therefore, when the transfer function of the encoder 2, H _1, Will be represented.

Thereafter, the output signal Y is recorded on the recording medium by the recording / reproducing circuit 6 and reproduced.

At this time, the reproduced signal (X ') is decoded by the decoder 7 and the output signal (Y').
The output signal Y 'is a value obtained by multiplying the sum of the reproduced output signal X' within one sampling period by αX 'multiplied by α by the multiplier 8 by -1 by the amplifier 10, that is, − (1 + α) · X ′. Therefore, when the transfer function of the decoder 7 and H _2, as described above From Becomes

After all, the transfer function (H) as a whole is obtained from the equations (1) and (2). And the original signal is obtained.

As described above, since the encoder 2 and the decoder 7 are configured by the feedforward loop including the adder and the multiplier, it is possible to obtain a fixed reproduction output having no phase rotation within one sunring period.

In the above-described example, different multipliers are used in the encoder 2 and the decoder 7. However, the multipliers are configured by a variable filter, a detector, a waiter, and a limiter, and the weights of the waiters are different from each other. The transfer function of the variable filter of the decoder is β, By doing so, these encoders and decoders can be constituted by the same components.

(G. Effects of the Invention) As is apparent from the above description, the noise reduction device of the present invention is a complementary noise reduction device having an encoder and a decoder, which is described in the following (a) to (d). It is characterized by.

(B) Both the encoder and the decoder are configured as a feedforward loop.

(B) The encoder is configured to amplify and output the addition result of the input signal and the signal obtained by multiplying the input signal by the first coefficient.

(C) The decoder is configured to amplify and output the addition result of the input signal and the signal obtained by multiplying the input signal by the second coefficient.

(D) The relationship between the first coefficient and the second coefficient is defined so that the product of the transfer function of the encoder and the transfer function of the decoder becomes 1.

Therefore, according to the present invention, since both the encoder and the decoder are configured by the feedforward loop,
Regardless of analog or digital, a stable reproduction output without phase rotation can be obtained.

In the above-described embodiment, an example in which the present invention is applied to a recording / reproducing apparatus has been described. However, the present invention is not limited to this, and can be applied to a transmitting / receiving apparatus.

[Brief description of the drawings]

FIG. 1 is a block diagram showing an embodiment of a noise reduction device according to the present invention, and FIG. 2 is a block diagram showing a conventional noise reduction device.
FIG. 3 is a diagram showing switching between an encoder and a decoder, and FIG. 3 is a block diagram showing an improvement plan. DESCRIPTION OF SYMBOLS 1... Noise reduction device, 2... Encoder, 7... Decoder, β... First coefficient, α.

──────────────────────────────────────────────────続 き Continuation of the front page (72) Inventor Kyoichi Murakami 6-7-35 Kita-Shinagawa, Shinagawa-ku, Tokyo Inside Sony Corporation (56) References JP-A-57-162812 (JP, A) (58) Surveyed field (Int.Cl. ⁶ , DB name) H04B 1/62 G11B 5/027-5/09 H03G 7/00

Claims (1)

(57) [Claims] 1. A complementary noise reduction device having an encoder and a decoder, wherein (a) both the encoder and the decoder are formed by a feedforward loop, and (b) the encoder includes an input signal and a first coefficient added to the input signal. (C) The decoder amplifies and outputs the result of addition of the input signal and the signal obtained by multiplying the input signal by the second coefficient. (D) the relationship between the first coefficient and the second coefficient is defined so that the product of the transfer function of the encoder and the transfer function of the decoder becomes 1. Noise reduction device.