KR20180002989U - Coaxial cable adapter to monitor signl of hybrid fiber coaxial network - Google Patents

Abstract

The present invention relates to a signal monitoring apparatus for allowing an optical transmission / reception apparatus (e.g., an ONU) provided in a photonic network (hereinafter referred to as an HFC network) to have a remote monitoring function, and an optical transmission / reception apparatus It is possible to perform remote monitoring without replacing an existing optical transmission / reception device (e.g., an ONU), thereby preventing unnecessary resources and manpower from being wasted, And it can improve the overall operational efficiency.

Description

{COAXIAL CABLE ADAPTER TO MONITOR SIGNAL OF HYBRID FIBER COAXIAL NETWORK}

The present invention relates to a signal monitoring apparatus for monitoring a signal of a photonic network (hereinafter referred to as an HFC network), and more particularly, to a signal monitoring apparatus for monitoring a signal of a coaxial cable It is about the adapter.

In general, an HFC network is a transmission network in which a fiber cable and a coaxial cable are mixed. In order to transport broadband contents such as video, data and voice, an HFC network coaxially connects an optical cable and a coaxial cable use.

That is, in the HFC network, a cable modem termination system (CMTS) and an optical transceiver (for example, ONU) located outdoors are connected by an optical cable, and an optical transceiver (for example, ONU) The cable modem of the terminal is connected by coaxial cable.

These HFC networks combine the advantages of optical cable and coaxial cable to improve the transmission speed and bandwidth so that they are widely used because of their excellent bidirectional characteristics and low installation and maintenance costs.

However, most optical transceivers (eg, ONUs) currently installed in the HFC network do not have a remote monitoring function. Accordingly, when an obstacle occurs in the HFC network, there is an inconvenience that an optical transmission / reception device (e.g., an ONU) installed on a main body of a vehicle using a high-performance work vehicle must be individually checked to identify a point where a failure occurs. In addition, since it is not possible to immediately check the point where the fault occurs, it takes a long time to recover the fault.

In order to solve this problem, it is possible to consider replacing an existing optical transmission / reception device (eg, ONU) with a new optical transmission / reception device (eg, ONU) having a remote monitoring function. However, Replacing an optical transceiver (eg, an ONU) that is operating normally will waste unnecessary resources and require a significant amount of time and manpower to be replaced, limiting the overall operational efficiency.

The present invention has been made in view of the above circumstances. It is an object of the present invention to provide a new signal monitoring apparatus which has a remote monitoring function of an existing optical transmission / reception apparatus (for example, ONU) will be.

According to another aspect of the present invention, there is provided a signal monitoring apparatus for connecting a cable and an optical transceiver to an HFC transmission network, the apparatus comprising: a first connection terminal for connection with the optical transceiver; A second connection terminal for connection with the cable; A signal checker for outputting specific information related to an RF signal from a specific signal input through the first connection terminal or the second connection terminal; And a control unit for monitoring an abnormality of the RF signal based on the specific information.

The specific signal includes a first specific signal that is a combination of a downlink RF signal and an AC power signal transmitted from a CMTS (Cable Modem Termination System), and a second specific signal that corresponds to an uplink RF signal to be transmitted to the CMTS .

Wherein the signal check unit comprises: a first input / output unit receiving the first specific signal from the first connection terminal; A second input / output unit receiving the second specific signal from the second connection terminal; A first input / output unit connected to one end of the first input / output unit, and a second input / output unit connected to the other end of the first input / output unit, and when the first specific signal is input, A signal separation / combiner for checking and passing the uplink RF signal from the second specific signal when a second specific signal is input; And a filtering unit for outputting the specific information related to the downlink RF signal or the uplink RF signal input from the signal separation / combination unit.

When the downlink RF signal is input, the filtering unit detects the signal intensity of the downlink RF signal that has passed through the high pass filter as first specific information. When the uplink RF signal is input, the filtering unit And the signal intensity of the uplink RF signal is detected as the second specific information.

The control related unit determines that the downlink RF signal is abnormal if the first specific information is less than or equal to a preset threshold value and if the second specific information is less than or equal to a predetermined threshold value, And generates a warning message for notifying that an abnormality has occurred in the downlink RF signal or the uplink RF signal, and transmits the generated warning message to the external server via radio.

The control-related section is characterized in that the control-related section is operated by using the AC power supply signal input from the detection section or by using the power supply of the battery.

Therefore, according to the coaxial cable adapter for monitoring signals of the present invention, the optical transmission / reception device (for example, ONU) has a remote monitoring function, so that the optical transmission / reception device (for example, ONU) It is possible to prevent unnecessary resources and manpower from being wasted because it is possible to perform remote monitoring without replacement, and it is possible to quickly check the abnormality based on the result of performing remote monitoring, do.

FIG. 1 shows an example of a structure of a mixed-radial axis network to which the present invention is applied.
2 is a diagram schematically showing the structure of the signal monitoring apparatus shown in FIG.

It is noted that the technical terms used herein are used only to describe specific embodiments and are not intended to limit the present invention. Also, the technical terms used herein should be interpreted in a sense that is generally understood by those skilled in the art to which the present invention belongs, unless the context clearly dictates otherwise. Should not be construed to mean, or be interpreted in an excessively reduced sense. Also, when a technical term used in the present specification is an erroneous technical term that does not accurately express the idea of the present invention, it should be understood that it is replaced with a technical term that can be understood by a person skilled in the art. In addition, the general terms used in this specification shall be interpreted according to pre-defined or contextual and shall not be construed in an excessively reduced sense.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, wherein like reference numerals are used to designate identical or similar elements, and redundant description thereof will be omitted. In the following description of the present invention, a detailed description of related arts will be omitted if it is determined that the gist of the present invention may be blurred. Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

FIG. 1 shows a structure of a copper-axis hybrid network (hereinafter referred to as HFC network) to which the present invention is applied.

As shown in FIG. 1, the HFC network of the present invention includes a CMTS (Cable Modem Termination System) 100, a CMTS 100, and a CMTS 100 for providing a high-speed Internet service and a two- An optical repeater 200 for relaying an RF signal between the CMTS 100 and an optical transceiver 300 located outside the building and an optical repeater 200 for transmitting and receiving an RF signal between the optical repeater 200 and a cable modem CM of a subscriber terminal The optical transceiver 300 and the optical transceiver 300 located outside the optical transceiver 300 have a remote monitoring function. At this time, the CMTS 100 and the optical repeater 200 are connected by a coaxial cable 20, the optical repeater 200 and the optical transceiver 300 are connected by an optical cable 10, (300) and the cable modem (CM) are connected by a coaxial cable (20).

In the HFC network according to the embodiment of the present invention, not only the above-mentioned CMTS 100, the optical repeater 200, the optical transceiver 300, and the signal monitor 400 but also a variety of various devices For example, a distributor, etc.), but for the convenience of explanation, only the minimum configuration will be mentioned.

In the case of the optical transceiver 300 provided in the HFC network, the HFC network 300 may be a transmission network device disposed outdoors, and includes an ONU (Optical Network Unit), a TBA (Trunk Bridge Amplifier), and the like. Most of the optical transceivers 300 do not have a remote control function.

In this case, it may be considered to replace the optical transmitter / receiver 300 installed in the HFC network with a new optical transmitter / receiver having a remote monitoring function. However, the optical transmitter / : ONU) will waste unnecessary resources and require a lot of time and manpower to be replaced, which limits the overall operational efficiency.

Accordingly, the present invention proposes a new signal monitoring apparatus implementation scheme in which the optical transceiver 300 installed in the HFC network has a remote monitoring function.

Hereinafter, the structure of the signal monitoring apparatus 400 for allowing the optical transceiver 300 according to the embodiment of the present invention to have a remote monitoring function will be described in detail with reference to FIG.

The signal monitoring apparatus 400 according to the present invention includes a first connection terminal CN1 for connection to the optical transmitter-receiver 300, a second connection terminal CN2 for connection to the coaxial cable 20, A signal checking unit 410 for detecting specific information related to the RF signal from the specific signal input through the connection terminal CN1 or the second connection terminal CN2, And a control related part 420.

The signal monitoring apparatus 400 having such a configuration operates as a connector which is connected (attached) between the optical transmitting / receiving apparatus 300 and the coaxial cable 20 to enable a remote monitoring function.

More specifically, the signal monitor 400 is coupled to the optical transmitter / receiver 300 through the first connection terminal CN1 and receives the first specific signal through the first connection terminal CN1. Here, the first specific signal is a signal transmitted to the optical transmitter / receiver 300 for downlink transmission from the CMTS 100, and has a form of a superimposed signal in which a downlink RF signal and an AC power signal (e.g., AC power) .

Meanwhile, the signal monitoring device 400 is coupled through the coaxial cable 20 and the second connection terminal CN2, and receives the second specific signal through the second connection terminal CN2. Here, the second specific signal is a signal to be input to the optical transmitter / receiver 300 for uplink transmission to the CMTS 100, and has a signal value corresponding to the uplink RF signal.

In the present invention, the second specific signal includes only the upward RF signal. However, the present invention is not limited to this, and the first specific signal may be an uplink RF signal and an AC power signal (e.g., AC power) It is of course also possible to have a superposition signal form. In addition, although the first specific signal is referred to as a downlink RF signal and the second specific signal is referred to as an uplink RF signal, the present invention is not limited thereto. Depending on the installation environment, the first specific signal may be an uplink RF signal, .

The signal monitoring apparatus 400 includes a power supply unit 430 for supplying power for driving the signal monitoring apparatus 400, a low power wireless communication modem 440 for wireless communication with an external server, and a low power wireless communication modem 440 to transmit and receive wireless signals.

All or at least a part of the configuration of the signal monitoring apparatus 400 including the signal checking unit 410, the control related unit 420, the power supply unit 430, the low power wireless communication modem 440 and the wireless antenna 450 , A form of a software module executed by a processor or a form of a hardware module, or a combination of a software module and a hardware module.

As a result, the signal monitoring apparatus 400 according to the embodiment of the present invention performs the remote monitoring without replacing the optical T / R in the present HFC network by allowing the optical T / R unit connected thereto to have a remote monitoring function It is possible to prevent unnecessary resources and waste of manpower, and it is possible to check the abnormality on the basis of the result of the remote monitoring, and to respond accordingly, so that the overall operational efficiency can be improved. Hereinafter, Each configuration in the monitoring apparatus 400 will be described in detail.

The signal check unit 410 includes a first input / output unit 411a, a second input / output unit 411b, a signal separation / combination unit 412, and a filtering unit 413.

The first input / output unit 411a receives the first specific signal input from the optical transmitter / receiver 300 through the first connection terminal CN1. That is, the first specific signal is inputted from the optical transmitter / receiver 300 through the first input / output unit 411a.

The second input / output unit 411b receives the second specific signal input from the coaxial cable 20 through the second connection terminal CN2. That is, the second specific signal is inputted from the coaxial cable 20 through the second input / output unit 411b.

The signal separation / combination unit 412 has one end connected to the first input / output unit 411a and the other end connected to the second input / output unit 411b. The signal separating / combining unit 412 receives the first specific signal from the first input / output unit 411a and receives the second specific signal from the second input / output unit 411b.

The signal separation and coupling unit 412 includes a first signal separation and coupling unit 412a including a first coil 4121 and a first condenser 4122 and a second signal separation and coupling unit 412b including a second coil 4123 and a second condenser 4124, And a second signal separating / combining unit 412b including the second signal separating / combining unit 412b.

More specifically, when the first specific signal is inputted from the first input / output unit 411a, the first signal separation / combination unit 412a extracts an AC power supply signal (for example, : AC power). Thereafter, the first signal separating / coupling unit 412a transfers the separated AC power signal (for example, AC power) to the power supply unit 430.

Further, the first signal separation / combination unit 412a separates the downlink RF signal from the first specific signal using the first condenser 4122. [ Thereafter, the first signal separation / combination unit 412a transmits the separated downlink RF signal to the filtering unit 413. [

If the second specific signal having no AC power source (e.g., AC power) is input to the second signal separation / combination unit 412b and only the upward RF signal is transmitted, the first signal separation / Regenerates a second specific signal having a signal value corresponding to the upward RF signal by using the first capacitor 4122. [ Thereafter, the first signal separation / combination unit 412a transfers the regenerated second specific signal to the optical transceiver 300 through the first connection terminal CN1.

On the other hand, when the second specific signal is inputted from the second input / output section 411b, the second signal separation / combination section 412b does not superpose the AC power source signal (for example, AC power source) on the second specific signal, And uses the capacitor 4122 to confirm the uplink RF signal from the second specific signal. Thereafter, the second signal separation / combination unit 412b transmits the uplink RF signal to the filtering unit 413.

If the AC power source signal (e.g., AC power source) of the first specific signal and the downlink RF signal are separately transmitted from the first signal separation / combination unit 412a, the second signal separation / combination unit 412b outputs The coils 4123 and the second condenser 4124 are used to re-superpose the AC power source signal (e.g., AC power source) and the downstream RF signal to regenerate the first specific signal. Thereafter, the second signal separation / combination unit 412b transmits the regenerated first specific signal to the coaxial cable 20 through the second connection terminal CN2.

When the downlink RF signal of the first specific signal is input from the first signal separation / combination unit 412a or the uplink RF signal of the second specific signal is input from the second signal separation / combination unit 412b, (413) detects specific information associated with the downlink RF signal / uplink RF signal.

Here, the specific information may be basic measurement information for remote monitoring, such as a signal intensity of a downlink RF signal / an uplink RF signal.

The filtering unit 413 includes an RF distributor 4131, a high pass filter (HPF), and a low pass filter (LPF).

More specifically, when the downlink RF signal of the first specific signal is input from the first signal separation / combination unit 412a, the filtering unit 413 converts the downlink RF signal into a high pass filter (HPF) using the RF distributor 4131, ) And a low-pass filter (LPF). At this time, it is assumed that the downlink RF signal has a high frequency.

That is, the downstream RF signal transmitted from the RF distributor 4131 passes through the high pass filter HPF. Accordingly, the filtering unit 413 can output the signal strength of the downlink RF signal that has passed through the high pass filter (HPF) as the first specific information to the control related unit 420.

When the uplink RF signal of the second specific signal is input from the second signal separation and combination unit 412b, the filtering unit 413 outputs the uplink RF signal to the high pass filter HPF using the RF distributor 4131 Pass filter (LPF). At this time, it is assumed that the uplink RF signal has a low frequency.

That is, the upstream RF signal transmitted from the RF distributor 4131 passes through the low-pass filter LPF. Accordingly, the filtering unit 413 can output the signal intensity of the upward RF signal that has passed through the low-pass filter (LPF) as the second specific information to the control related unit 420.

The control related part 420 monitors whether the RF signal is abnormal based on the specific information.

More specifically, when the first specific information related to the downlink RF signal is received from the filtering unit 413, the control related unit 420 determines whether the first specific information is less than or equal to a predetermined threshold value.

That is, when the first specific information is equal to or less than a preset threshold value, the control related part 420 determines that an abnormality has occurred in the downlink RF signal. Thereafter, the control unit 420 generates a warning message to notify that an error has occurred in the downlink RF signal, and transmits the generated warning message to the external server.

Here, it is preferable that the warning message includes information that is confirmed at the time of monitoring, such as a time at which an abnormality is detected in a downlink RF signal, a signal strength of a downlink RF signal, and surrounding environmental condition information (e.g., temperature).

If the first specific information is greater than or equal to a preset threshold value, the control related part 420 determines that the downlink RF signal is in a normal state in which it is normally being transmitted and received.

On the other hand, when the second specific information related to the uplink RF signal is received from the filtering unit 413, the control related unit 420 determines whether the second specific information is less than or equal to a preset threshold value.

That is, when the second specific information is less than or equal to a preset threshold value, the control related part 420 determines that an abnormality has occurred in the uplink RF signal. Thereafter, the control-related unit 420 generates a warning message to notify that an abnormality has occurred in the uplink RF signal, and transmits the generated warning message to the external server.

Here, it is preferable that the warning message includes information that is confirmed at the time of monitoring, such as a time at which an abnormality is detected in an uplink RF signal, a signal strength of an uplink RF signal, surrounding environment status information (e.g.

If the second specific information is greater than or equal to a preset threshold value, the control related part 420 determines that the uplink RF signal is in a normal state in which it is normally being transmitted and received.

On the other hand, the control-related unit 420 monitors the power input to the power supply unit 430 to generate and store the power monitoring result, and delivers the result when the external server requests it. Here, the power supply monitoring result may include a point of time when an AC power source (e.g., an AC power source) is applied, a degree to which the AC power is applied, and the like.

That is, when receiving the monitoring request message requesting monitoring of the power state from the external server, the control related part 420 transmits the accumulated power monitoring result to the external server in response to the monitoring request message.

If it is determined that the power supply is interrupted while monitoring the power supplied to the power supply unit 430, the control unit 420 generates a warning message to inform that the power supply is cut off and transmits the warning message to the external server.

The power supply unit 430 supplies power for driving the signal monitoring apparatus 400.

The power supply unit 430 includes a Switched Mode Power Supply (SMPS) 431 and a battery 432.

When the first specific signal transmitted from the optical transmitter / receiver 300 is input to the signal check unit 410 and the AC power source signal of the first specific signal (for example, AC power source) is separated and transmitted, Converts AC power of the AC power source signal (for example, AC power source) into DC power and transmits the DC power source to the control related part 420.

Therefore, the control related part 420 can control the operation for remote monitoring using the DC power supplied from the SMPS 431. [

The battery 432 supplies power to the control related part 420 when an AC power source signal (for example, AC power source) is not inputted to the SMPS 431.

As described above, according to the present invention, since the optical transceiver has a remote monitoring function, remote monitoring can be performed without replacing the optical transceiver installed in the HFC network, thereby preventing unnecessary resources and wasted manpower , It can improve the overall operational efficiency because it can confirm the abnormality quickly and respond to it based on the result of the remote monitoring.

It will be understood by those skilled in the art that although specific embodiments of the present invention have been illustrated and described, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention, It is obvious to those who have. Therefore, such modifications or variations should not be individually understood from the technical idea or viewpoint of the present invention, but the modified embodiments should be included in the claims of utility model registration of the present invention.

100: Cable modem termination system 200: Optical repeater
300: Optical transceiver 400: Signal monitor
410: Signal verification unit 420: Control related unit
430: Power supply unit 440: Low power wireless communication modem
450: Wireless antenna

Claims (6)

A signal monitoring apparatus for connecting a cable and an optical transmission / reception apparatus associated with an HFC transmission network,
A first connection terminal for connection with the optical transceiver;
A second connection terminal for connection with the cable;
A signal checker for outputting specific information related to an RF signal from a specific signal input through the first connection terminal or the second connection terminal; And
A control-related unit for monitoring the abnormality of the RF signal based on the specific information,
Wherein the signal monitoring apparatus comprises: The method according to claim 1,
The specific signal may be,
And a second specific signal corresponding to an uplink RF signal to be transmitted to the CMTS, the first specific signal including a downlink RF signal and an AC power signal superimposed on a CMTS (Cable Modem Termination System) Monitoring device. 3. The method of claim 2,
Wherein the signal check unit comprises:
A first input / output unit receiving the first specific signal from the first connection terminal;
A second input / output unit receiving the second specific signal from the second connection terminal;
A first input / output unit connected to one end of the first input / output unit, and a second input / output unit connected to the other end of the first input / output unit, and when the first specific signal is input, A signal separation / combiner for checking and passing the uplink RF signal from the second specific signal when a second specific signal is input; And
And a filtering unit for outputting the specific information related to the downlink RF signal or the uplink RF signal input from the signal separation / combination unit. The method of claim 3,
Wherein the filtering unit comprises:
When the downlink RF signal is input, detects the signal strength of the downlink RF signal that has passed through the high pass filter as first specific information,
And detects the signal strength of the uplink RF signal that has passed through the low pass filter as the second specific information when the uplink RF signal is input. 5. The method of claim 4,
The control-
Determining that an abnormality of the downlink RF signal occurs when the first specific information is less than or equal to a predetermined threshold value and determining that the uplink RF signal is abnormal if the second specific information is less than or equal to a predetermined threshold value,
And generates a warning message to notify that an abnormality has occurred in the downlink RF signal or the uplink RF signal, and transmits the generated warning message to the external server via radio. The method of claim 3,
The control-
Wherein the signal monitoring unit operates using the AC power supply signal input from the detection unit or operates using the power supply of the battery.

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