KR101195526B1 - Noise Eliminating Circuit - Google Patents

Abstract

 The present invention relates to a noise canceller. This is a noise canceller for removing the residual noise among the input signal mixed with the communication signal and the presence noise, and divides the input signal into the same three signals, delaying one of the distributed signals by a predetermined time, One signal is equally time delayed and phase inverted, and another signal is passed as it is, and then these signals are combined and output. This provides a significant effect, for example, where existing noise, such as that which occurs in an uplink path for CATV Internet subscribers, can be efficiently removed from the communication signal.

Description

Noise Eliminator Circuit

The present invention relates to a noise canceller, and more particularly, by separating a signal mixed with phase noise such as an uplink signal in a CATV network into a plurality of signals delayed by a communication time interval, and then canceling each other. It relates to a new noise canceller that has been attenuated and has improved signal-to-noise ratio.

Recently, communication services such as Internet access service, broadcast service, and telephone service using a cable television (CATV) network have been widely used, and data over interface specification (DOCSIS) has been developed as a cable modem standard. Docsys is a standard interface for cable modems, a device that handles data input and output between a headend and an individual or company computer or TV set. Currently, standardization of cable modem technology is established by DAXIS, IEEE802.14, DAVIC, etc., but it is actually unified to DAXIS.

Starting with CableLabs in 1995, Docsys 1.0 was released in July 1997 and is currently under development for Docsys, 2.0 and Docsys 3.0. The daxis 2.0 standard is a converged network that integrates voice, video and data services, improves the modulation / demodulation method of the physical layer as robustness to noise is required, suggests for symmetrical services, provides interoperability with daxis 1.x, and up and down channels. It is characterized by the pursuit of more symmetrical transmission structure in terms of transmission capability.

In the case of DACSIS 3.0, which is currently under development, it will be possible to transmit speeds of 200 Mbps down and 100 Mbps up. As such, the cable TV industry, which has become weak based on the optical LAN service, is expected to be able to start full-scale service of 100 megabytes with the introduction of Docsys 3.0.

In the communication service using the CATV network, the frequency of the downlink signal provided from the service provider to the subscriber and the uplink signal provided from the subscriber to the service provider is asymmetrically allocated. However, the noise problem is serious because the frequency in the 5 ~ 45 MHz band used for the uplink signal in the CATV network is easily mixed with various noises generated around us. If noise is mixed, there is a serious problem that the overall communication speed of the communication network is reduced and the communication quality is degraded.

Noise generated from the subscriber side is mainly generated by an electric motor inserted into a washing machine, a microwave oven, a vacuum cleaner, a computer, and the like, and noise is also generated by an oscillator and a divider inside a communication device. In the past, it is proposed that the noise canceller using the uplink bandpass filter focuses on the fact that such noise is mainly concentrated in the 0 to 10 MHz band. For example, Korean Patent Registration No. 10-0400077, Korean Patent Publication No. 2003-0066928 discloses a configuration of a noise removing filter using an upband pass filter.

However, as communication standards such as DAXIS are being improved, the frequency band used is also changed to a high frequency band, thereby reducing the utility of the noise canceling filter that filters the conventional low frequency band. Moreover, even in the case of low band noise, harmonic components are generated in the high frequency region in the process of synthesizing each other with noise, thereby causing problems in uplink communication.

Therefore, in the noise canceller of the communication signal in which the existing noise is mixed, such as the noise cancellation of the uplink signal of the communication service using the CATV network, the noise is eliminated by clearly distinguishing the noise from the communication signal rather than filtering only a specific frequency band. There was a need for new technologies that could be done.

The present invention has been invented to improve and supplement the noise canceling technique of a communication signal incorporating the conventional residual noise described above and to provide various additional advantages. According to the present invention, a signal having a mixed phase noise such as an uplink signal in a CATV network is separated into a plurality of signals which are time delayed by a communication time interval, and then canceled. It is an object to provide a noise canceller.

This object is achieved by a noise canceller provided according to the invention. The noise canceller provided according to an aspect of the present invention is a noise canceller for removing the residual noise from an input signal mixed with a communication signal and the presence noise, and distributes the input signal to the same three signals, but among the divided signals. One signal is delayed by a predetermined time, the other signal is time-delayed and phase inverted equally, and another signal is passed as it is, and then these signals are combined and output.

In one embodiment, the predetermined time applied to the communication delay is a time delayed communication signal unit and a non-time delayed communication signal unit in the two signals when a time delayed signal and a non-time delayed signal are combined. Have a length of time so that they do not interfere with each other.

In a specific embodiment, the noise canceller may include: a first divider for distributing an input signal into a plurality of signals; A time delay unit for delaying one signal output from the first divider by a predetermined time; A second divider for distributing the signal output from the time delay unit into two signals; A phase inversion unit for inverting one signal output from the second divider by 180 Hz; A compensation delay unit for compensating for the other signal output from the second divider by the time when the phase inverted signal is delayed from the phase inverter; Pass line for transmitting the other signal output from the first divider as it is; And a combiner configured to combine and output signals from the compensation delay unit, the phase inversion unit, and the pass line.

In another embodiment, the input signal is an upward signal from the subscriber side of the cable television (CATV) network to the headend. In this case, between the first divider and the time delay unit, an uplink bandpass filter for passing only an uplink signal may be further included.

The noise canceller according to the present invention having the above-described configuration, such as an uplink signal in a CATV network, separates a signal containing mixed noise into a plurality of signals time-delayed by a communication time interval and then cancels each other by canceling each other. There is a remarkable effect such that it is greatly attenuated and the signal-to-noise ratio is improved.

1 is a circuit diagram illustrating a circuit configuration of a noise canceller according to an embodiment of the present invention.
FIG. 2 is a schematic diagram illustrating a modification process of a communication signal passing through the noise canceler circuit shown in FIG. 1. FIG.
3 is a schematic diagram illustrating a process of modifying existing noise passing through the noise canceler circuit shown in FIG.
4 is a schematic diagram illustrating a modification process of a mixed signal passing through the noise canceler circuit shown in FIG.

Hereinafter, with reference to the accompanying drawings illustrating the present invention with a specific example as follows.

The noise canceller provided according to the present invention is a kind of noise canceling filter circuit which divides an input signal into three signals, processes them differently, and then combines and outputs them again. In other words, according to the present invention, the input signals can be divided into three identical signals and transmitted along three transmission lines, respectively, and then combined. One of the three identical signals distributed is delayed by a predetermined time along the first transmission line. The other signal is time-delayed by the same time as the above signal along the second transmission line, and is further inversed by 180 °. The last one signal proceeds along the third transmission line and passes without any further processing. These three signals can then be combined to cancel the noise and output.

In particular, the noise canceller provided according to the present invention is incorporated by various electronic devices on the subscriber side in a signal in which a communication signal such as an uplink signal from the subscriber side of the cable television (CATV) network to the headend and the presence noise are mixed. It can be applied as a noise canceller that can efficiently remove the residual noise.

The communication signal to which the noise canceller according to the present invention is applied may be transmitted as communication signal units which are distinguished from each other on the time axis, for example, as a signal of a time division multiplexing (TDM) method, and in another way of a WDM (wavelength division method) Communication signals are also possible. In the present invention, the predetermined time applied to the time delay is such that when the time delayed signal and the non-time delayed signal are combined, the time delayed communication signal unit and the non-time delayed communication signal unit in the two signals do not interfere with each other. Has a length of time. This allows communication signal units to pass through the noise canceller without any change.

1 shows a specific circuit configuration of the noise canceller 10 according to a specific embodiment of the present invention. In the illustrated example, the noise canceller 10 includes a first divider 11, an upband pass filter 12, a time delay 13, a second divider 14, a compensation delay 15 and a phase inverter. (17), and a coupler (16).

The circuit configuration of the noise canceller 10 shown divides the input signal logically into three transmission lines LA, LB, LC (see FIGS. 2-4), time delays and / or inverts, respectively, and then one again. It is a structure to combine.

First, in the illustrated example, the A transmission line LA is a first line L1 and a second divider 14 in which the first divider 11, the uplink filter 12, and the time delay unit 13 are connected in series. , The third line L3 including the compensation delay unit 15, and the coupler 16.

The signal input to the input line Lin is transformed as a signal delayed by a predetermined time while being transmitted along the A transmission line LA. That is, the first divider 11 divides the input signal into a plurality of identical signals. The uplink bandpass filter 12 may pass only an uplink signal by limiting a frequency band of one of the signals output from the first divider 11.

The time delay unit 13 delays the signal passing through the uplink bandpass filter 12 by a predetermined time. The second divider 14 divides the signal output from the time delay unit 13 into two signals. The compensation delay unit 15 further delays one of the signals output from the second divider 14, which is the phase of the other of the signals output from the second divider 14 as described later. To compensate for the delayed time when inverted. As such, a time delayed signal along the A transmission line may be input to the combiner 16.

Meanwhile, in the illustrated example, the B transmission line LB includes a first line L1 and a second divider 14 in which the first divider 11, the upward band pass filter 12, and the time delay unit 13 are connected in series. , The fourth line L4 including the phase inversion unit 17, and the combiner 16.

The signal input to the input line Lin is not only delayed by a predetermined time while being transmitted along the B transmission line LB, that is, delayed by the A transmission line LA, but also transformed as a phase inverted signal. Here, the first divider 11, the uplink band pass filter 12, the time delay unit 13, and the second divider 14 are identical to the A transmission line LA. Thereafter, the other one of the signals output from the second divider 14 is inverted by a 180 ° phase delayed through the phase inversion unit 17. As such, the time delayed and phase inverted signal may be input to the combiner 16 along the B transmission line LB.

The other one of the signals distributed from the first divider 11 may be input to the combiner 16 as it is, along with the signal input along the second line, that is, the pass line L2, without any further processing.

In the combiner 16, a time delayed signal from the compensation delay unit 15, a time delayed and phase reversed signal from the phase inversion unit 17, and signals which have not been processed by the pass line L2 are input, Can be output to the output line (Lout) by combining.

Specific examples of the waveform of the signal processed by the noise canceller 10 having the above-described configuration are illustrated in FIGS. 2 to 4. 2 shows the transmission state of the communication signal, FIG. 3 shows the transmission state of the residual noise, and FIG. 4 shows the mixed signal of the two.

Referring to FIG. 2, an example of a communication signal of a TDM (Time Division Multiplexing) communication method according to the DAXIS standard having a time interval between communication signal units is shown. In the example shown, the input signal (input communication signal) Sin is distributed in three paths at the distribution point Ld, where the same signals are distributed for the three paths. A C communication signal SC having the same time and phase as the input communication signal Sin is transmitted along the C transmission line LC. The A communication signal SA transmitted along the A transmission line LA and the B communication signal SB transmitted along the B transmission line LB are, for example, 360 ° or 720 ° or more than the C communication signal SC. May be delayed by phase (eg, time T). The B communication signal SB has a phase angle of the A communication signal SA. However, the phase angles of the A communication signal SA and the C communication signal SC are 0 degrees, and the A communication signal SA has a time T delay than the C communication signal SC. Only the C communication signal SC does not have a phase delay.

At the coupling point Lc, the A, B, and C communication signals SA, SB, and SC are input and combined. The A communication signal SA and the B communication signal SB have the same time delay, while the phase is out of phase. Because they are 180 ° different, they cancel each other out. Only the C communication signal SC is output through the output line Lout.

Referring to Figure 3, a process of removing the residual noise by the noise canceller according to the present invention is shown. As shown, the input noise Nin has a characteristic as background noise existing in the background of the signal, and the waveform is irregular.

In the example shown, the input noise Nin is distributed in three paths at the distribution point Ld where the same signals are distributed over the three paths. The C noise NC having the same time and phase as the input noise Nin is transmitted along the C transmission line LC. A noise (NA) transmitted along the A transmission line (LB) and B noise (NB) transmitted along the B transmission line (LB) are, for example, 360 ° or 720 ° or greater phase (time) than C noise (NC). May be delayed by T). B noise (NB) has a phase angle of A noise (NA). However, the phase angles of the A noise NA and the C noise NC are 0 degrees, and the A noise NA has a delay of time T more than the C noise NC. Only C noise (NC) has no phase delay.

A, B, and C noises (SA, SB, and SC) are inputted and combined at the coupling point (Lc). A noise (NA) and B noise (NB) have the same time delay, but are 180 ° out of phase. Therefore, they cancel each other out.

On the other hand, C noise (NC) has the same phase and frequency as A noise (NA). However, unlike the case of the communication signal existing only in a certain time interval shown in FIG. 2, the C noise is a background noise existing only in all time intervals although only a certain period is indicated in the drawing. Therefore, at the coupling point Lc, the C noise NC in the time T section of the figure is output as it is because there is no other noise to cancel or overlap. On the other hand, the portion of the C noise (NC) after the time T has elapsed overlaps the A noise (NA), and the overlapped C noise (NC) portion has the same time delay and inversion phase for the A noise (NA). It may be offset by the B noise (NB) having a and output. Accordingly, the output noise Nout after the T time can be almost eliminated as in the example shown on the output line Lout of FIG. 3.

In FIG. 4, the input signal SNin mixed with the communication signal and noise illustrated in FIGS. 2 and 3, the time delayed A signal SNA on the A transmission line, and the time delayed and phase inverted B signal SNB on the B transmission line ), The same C signal SNC as the input signal on the C transmission line and consequently the noise-free output signal SNout is illustrated.

Thus, according to the noise canceller according to the present invention, it is possible to remove the noise as much as the T time at which the time delay is performed, but it can provide an advantage that the noise after this T time can be almost completely removed.

Although the present invention has been described with reference to specific embodiments, those skilled in the art of eliminating the presence noise from the mixed signal of the presence noise and the communication signal as well as in the CATV network, those skilled in the art will refer to the various features described herein. Various and modified circuit configurations are possible in combination. Therefore, it should be pointed out that the scope of the present invention should not be limited to the described embodiments, but should be interpreted by the appended claims.

10: noise canceller 11: first divider
12: upward band pass filter 13: time delay unit
14: second divider 15: compensation delay unit
16: Combiner 17: Phase Inverter

Claims (5)

The input signal Sin is divided into the same three signals SA, SB, and SC to delay one signal SA of the distributed signals by a predetermined time, and equally time the other signal SB. Phase reversal with delay, and pass another signal SC as it is, and then these three signals are combined and output while canceling the existing noise;
The predetermined time applied to the time delay has a length of time such that when the time delayed signal and the non-time delayed signal are combined, the time delayed communication signal unit and the non-time delayed communication signal unit in the two signals do not interfere with each other. A noise canceller configured to remove the residual noise from the input signal mixed with the communication signal and the existing noise;
The noise canceller includes a first divider 11 for distributing an input signal into a plurality of signals, a time delay unit 13 for delaying one signal output from the first divider 11 by a predetermined time, and A second divider 14 for distributing the signal output from the time delay unit 13 into two signals, and a phase inverter 17 for phase reversing one signal output from the second divider 14 by 180 °. And a compensation delay unit 15 for compensating for the other signal output from the second divider 14 by the time that the phase inverted signal is delayed from the phase inverter 17, and the first divider. 11, a pass line L2 for transmitting another signal output from the same, and the signals from the compensation delay unit 15, the phase inversion unit 17, and the pass line L2 are combined and output. Characterized in that it comprises a coupler (16) Is a noise canceller.
delete delete The method according to claim 1,
The input signal is an uplink signal directed from the subscriber side of the cable television (CATV) network to the head end, and an uplink bandpass filter 12 for passing only an uplink signal between the first distributor 11 and the time delay unit 13. Noise canceller, characterized in that further comprises. delete

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