KR100813566B1 - Hfc transmission network monitoring apparatus - Google Patents

Abstract

An HFC(Hybrid Fiber Coaxial) transmission network monitoring apparatus is provided to check a cause of noise or the concentration of traffic from an HFC transmission network apparatus installed in each cell or node in real time, thereby taking a quick measure for the cause of noise or the concentration of traffic. A filtering unit(41) receives an uplink signal to filter signals except a preset frequency domain. A signal intensity detector(42) outputs the signal of a voltage level corresponding to the intensity of the uplink signal filtered by the filtering unit. A signal comparing unit(43) outputs a first comparison signal when the voltage level of the signal is greater than that of a preset reference signal, and outputs a second comparison signal when the voltage level of the signal is smaller than that of the preset reference signal. A digital converter(44) converts the signal outputted from the signal intensity detector into a digital signal. A control unit(45) controls the digital converter to convert the signal into the digital signal in response to each reception of the first comparison signal and the second comparison signal when the first comparison signal and the second comparison signal are successively outputted from the signal comparison unit, and determines a state of the uplink signal on the basis of the digital signal converted in response to each of the first comparison signal and the second comparison signal.

Description

HFC Transmission Network Monitoring System {HFC TRANSMISSION NETWORK MONITORING APPARATUS}

The present invention relates to an HFC transmission network monitoring apparatus, and more particularly, is installed in an HFC transmission network apparatus for relaying signal transmission between a subscriber terminal connected to an HFC network and a headend center from the subscriber terminal through the HFC transmission network apparatus. The present invention relates to an HFC transmission network monitoring apparatus for monitoring an uplink signal transmitted to a headend center.

In recent years, in the broadband integrated network (BcN) environment in which wired / wireless convergence, broadcasting and communication are converged, the subscriber network type of the high-speed infrastructure for providing high-speed Internet service and digital broadcasting service is copper line-based ASL (Asymmetric Digital Subscriber Line) / VDSL. (Very high-data Digital Subscriber Line), hybrid fiber-coaxial (HFC), and fiber-based Fiber To The Home (FTTH).

Here, the HFC (Hybrid Fiber Coaxial) network is an optical-coaxial mixed network in which a fiber cable and a coaxial cable are mixed. In order to transport broadband content such as video, data, and voice, different types of networks are used. It is a communication technology that uses fiber optic cable and coaxial cable together.

The HFC network overcomes the limitations of transmission speed and bandwidth by combining the advantages of optical and coaxial cables, and has been widely used in recent years because of its excellent bidirectional characteristics and low maintenance and facility costs.

The current cable TV transmission network is being replaced by HFC network, which divides one wire broadcasting area into several unit cells and uses fiber optic cable from the broadcasting station to the corresponding unit cell and coaxial cable from the unit cell to the subscriber. It takes a form to say.

Signals used in HFC networks can be divided into up and down, which is a signal from the subscriber to the head-end center, generally using a frequency band of 5 ~ 42MHz or 5 ~ 56MHz.

However, in a system using an existing RF communication network, an optical communication network, or a LAN communication network, there is a lack of technology for managing an HFC network in a trend that HFC networks are widely used.

For example, a spectrum analyzer is installed in a headend center to measure a downlink signal or an uplink signal. However, since the spectrum analyzer itself is expensive, economical efficiency is inferior.

In addition, for upstream signals, analyzing the upstream signals from each cell and node through a spectrum analyzer installed in the headend center is only a matter of integrated and synthesized signal analysis from a large number of subscribers belonging to that cell. Even if the upstream signal is analyzed at the center, it is impossible to determine which node location is mixed in and where it occurs at each cell composed of many individual nodes.

For this reason, a technician is currently working on each node or cell to determine in which cell or node the noise mixed in the upstream signal occurs, especially in the particular cell or node that causes the overall network overload. By checking the installed HFC transmission network devices such as optical node units (ONUs) or amplifiers one by one and searching for the cause of the noise generated in the upstream signal, it is not only time-consuming but also quick response. It is a major source of customer complaints.

The present invention overcomes the difficulty of measuring the uplink signal generated in the existing HFC network as described above, and promptly responds to the cause of noise or the concentration of traffic in real time from the HFC transmission network apparatus installed in each cell or node. The aim is to provide a possible HFC network monitoring device.

According to the present invention, the object is installed in the HFC transmission network device for relaying the signal transmission between the subscriber terminal and the head end center connected via the HFC network and is transmitted to the headend center from the subscriber terminal through the HFC transmission network device An HFC transmission network monitoring apparatus for monitoring a signal, the apparatus comprising: a filter unit configured to receive the upstream signal and filter a signal outside a preset frequency band; A signal strength detector for outputting an intensity signal having a voltage level corresponding to the signal strength of the upstream signal filtered by the filter; A signal comparison outputting a first comparison signal when the voltage level of the strength signal is greater than a voltage level of the reference signal; and outputting a second comparison signal when the voltage level of the strength signal is less than the voltage level of the reference signal. Wealth; A digital converter converting the strength signal output from the signal strength detector into a digital signal; When the first comparison signal and the second comparison signal are sequentially output from the signal comparison unit, the digital conversion unit converts the strength signal into a digital signal in response to receiving each of the first comparison signal and the second comparison signal. And a control unit which controls to convert, and determines a state of the upstream signal based on the converted digital signal corresponding to the first comparison signal and the second comparison signal, respectively. do.

Here, the signal strength detection unit may be provided in the form of a received signal strength indicator (RSSI).

The signal comparison unit may include a reference value generator configured to output the reference signal; A comparator for comparing the intensity signal with the reference signal and outputting a logic signal having a logic value corresponding to the comparison result; And an amplifier for amplifying the logic signal output from the comparator and outputting the first comparison signal and the second comparison signal having a TTL level.

The digital converter may include an A / D converter for converting the intensity signal into a digital signal; The control unit may include a sample / holder configured to control signal conversion of the A / D converter.

The control unit may include: a comparison signal receiver configured to receive the first comparison signal and the second comparison signal from the signal comparison unit; A data receiver which receives the digital signal converted by the digital converter; An event output unit for outputting an event signal for causing the A / D converter to convert the intensity signal into a digital signal to the sample / holder unit; When the first comparison signal and the second comparison signal are sequentially received through the signal comparison unit, the event output unit outputs the event signals corresponding to the received first comparison signal and the received second comparison signal, respectively. And a module controller configured to determine a state of the uplink signal based on the digital signal received through the data receiver.

The filter unit, the signal strength detector, the signal comparator and the digital converter are provided in a module form and connected to the HFC transmission network device. The controller may be installed in hardware and software in the HFC transmission network device.

Here, the HFC transmission network device may include at least one of an optical node unit (ONU) and an amplifier.

The module controller may transmit information about the determined state of the uplink signal to the headend center through the HFC network.

According to the present invention, by overcoming the difficulty of measuring the uplink signal generated in the existing HFC network, it is possible to quickly cope by checking the cause of the noise or the concentration of traffic in real time from the HFC network device installed in each cell or node HFC transmission network monitoring device is provided.

Hereinafter, with reference to the accompanying drawings will be described in detail the present invention.

1 is a diagram illustrating a configuration of an HFC network system according to the present invention. As shown in the figure, it comprises a headend center 1, an HFC transmission network apparatus 3 and a subscriber station 5.

The head end center 1 may include a head end modulator 11, a cable modem termination device 14 (CMTS: Cable Modem Termination System), an optical transmitter 12, and an optical receiver 13. The downlink signal generated from the headend modulator 11 is transmitted to the HFC transmission network device 3 via the optical transmitter 12 and provided to each subscriber station 5.

The cable modem termination device 14 connects the broadcast HFC network with the Internet network. The optical receiver 13 receives an uplink signal coming from the subscriber station 5 via the HFC transmission network device 3.

Here, the headend center 1 may be provided with a center management server 16 for monitoring and managing each configuration of the headend center 1, the center management server 16 is HFC transmission network monitoring device 40 to be described later By receiving the measurement result for the uplink signal from), it is possible to determine the state of the uplink signal in real time.

Meanwhile, the HFC transmission network device 3 may include an optical node unit 30 (ONU) and a network amplifier 31.

The optical node unit 30 converts the optical signal transmitted from the headend center 1 into an electrical signal and transmits it to the subscriber station 5. Here, the HFC network is connected to the optical node unit 30 from the head end center 1 by a fiber cable, and each subscriber station 5 through the network amplifier unit 31 from the optical node unit 30. Up to have a configuration connected by a coaxial cable (Coaxial cable).

The network amplifier 31 amplifies the electrical signal output from the optical node unit 30 so as to be transmitted to each subscriber station 5. Here, the optical node unit 30 and the network amplifier 31 operate using the power supplied from the power supply 32.

Here, one optical node unit 30 manages a plurality of subscriber stations 5, and one optical node unit 30 constitutes one cell in the HFC transmission network system according to the present invention.

Meanwhile, the HFC transmission network device 3 is provided with an HFC transmission network monitoring device 40 for monitoring an uplink signal transmitted from the subscriber station 5 to the headend center 1. In the present invention, the HFC transmission network monitoring device 40 is installed in each optical node unit 30, the network amplifier 31 and the power supply 32 as an example, but the optical node unit 30, network amplification Of course, it can be installed in at least one of the part 31 and the power supply (32).

Hereinafter, the HFC transmission network monitoring apparatus 40 according to the present invention will be described in more detail with reference to FIG. 2.

As shown in FIG. 2, the HFC transmission network monitoring apparatus 40 according to the present invention includes a filter unit 41, a signal strength detector 42, a signal comparator 43, a digital converter 44, and a controller ( 45). Here, the HFC transmission network monitoring device 40 may receive an upstream signal from the monitoring target HFC transmission network device 3, for example, an uplink signal monitor terminal provided in the network amplifier 31.

The filter unit 41 receives an uplink signal to the headend center 1 from the subscriber station 5 and filters out signals outside the preset frequency band. Here, the frequency band filtered by the filter unit 41 may be a signal other than the frequency band used as an uplink signal in the HFC transmission network system according to the present invention.

The upstream signal filtered by the filter unit 41 is input to the signal strength detector 42, and the signal strength detector 42 outputs an intensity signal having a voltage level corresponding to the signal strength of the upstream signal. Here, the signal strength detector 42 removes a carrier wave from the upstream signal filtered by the filter unit 41 and outputs an envelope-type strength signal proportional to the signal strength. In the present invention, for example, the signal strength detection unit 42 is provided in the form of a received signal strength indicator (RSSI).

The intensity signals output from the signal strength detector 42 are branched and input to the digital converter 44 and the signal comparator 43, respectively.

The signal comparing unit 43 outputs the first comparison signal when the voltage level of the intensity signal is greater than the voltage level of the preset reference signal, and outputs the second comparison signal when the voltage level of the intensity signal is less than the voltage level of the reference signal. Output

Here, the signal comparator 43 may include a reference value generator 43a, a comparator 43b, and an amplifier 43c, as shown in FIG.

The reference value generator 43a outputs a reference signal of a preset voltage level. The comparator 43b compares the voltage level of the intensity signal with the reference signal and outputs a logic signal having a logic value corresponding to the comparison result.

The amplifier 43c amplifies the logic signal output from the comparator 43b to generate and output a first comparison signal and a second comparison signal having a TTL level. The first comparison signal and the second comparison signal output through the amplifier 43c are transmitted to the control unit 45. The control unit 45 recognizes the first comparison signal and the second comparison signal as the start and end of the uplink burst. do.

On the other hand, the digital converter 44 converts the intensity signal output from the signal strength detector 42 into a digital signal under the control of the controller 45. The digital converter 44 according to the present invention controls the signal conversion of the A / D converter 44b under the control of the A / D converter 44b for converting the strength signal into a digital signal and the controller 45. The sample / holder 44a may be included.

When the first comparison signal and the second comparison signal are sequentially output from the signal comparison unit 43, the controller 45 may be configured to respond to the reception of each of the first and second comparison signals. Control to convert the strength signal into a digital signal. The controller 45 determines the state of the uplink signal based on the digital signal converted corresponding to the first comparison signal and the second comparison signal, respectively.

Referring to FIG. 2, the controller 45 may include a comparison signal receiver 45a, a data receiver 45b, an event output unit 45c, and a module controller 45d.

The comparison signal receiving unit 45a receives the first comparison signal and the second comparison signal output from the signal comparing unit 43, and the data receiving unit 45b receives the converted digital signal through the digital conversion unit 44. .

The event output section 45c, under the control of the module control section 45d, outputs an event signal for causing the A / D converter 44b of the digital conversion section 44 to convert the intensity signal into a digital signal. )

The module control unit 45d corresponds to the first comparison signal and the second comparison signal received by the event output unit 45c when the first comparison signal and the second comparison signal are sequentially received through the comparison signal receiver 45a. Control to output an event signal.

That is, when the first control signal is received through the comparison signal receiver 45a, the module controller 45d recognizes this as a start of an uplink burst of the uplink signal, and the event signal is sample / sampled through the event output unit 45c. Control to be output to the holder portion (44a).

At this time, the sample / holder 44a holds the strength signal from the signal strength detector 42 in response to the event signal from the event output 45c, and the A / D converter 44b acquires the digital signal. To control. Here, the digital signal obtained by the A / D converter 44b is transmitted to the module controller 45d through the data receiver 45b of the controller 45.

Then, when the second control signal is received through the comparison signal receiver 45a, the module controller 45d recognizes this as the end of the uplink burst of the uplink signal, and the event signal is sampled through the event output unit 45c. Control to be output to the / holder portion 44a.

At this time, the sample / holder 44a converts the strength signal from the signal strength detector 42 back into a digital signal through the A / D converter 44b in response to the event signal from the event output 45c. To control. Here, the digital signal converted by the A / D converter 44b is transmitted to the module controller 45d through the data receiver 45b of the controller 45.

The module controller 45d compares the values of the digital signals received from the digital converter 44 corresponding to each of the first comparison signal and the second comparison signal, and compares the difference between the two values in the signal-to-noise ratio (SNR: Sinal-to). -Noise Ratio) to determine the state of the uplink signal.

Then, the module control unit 45d transmits the determination result of the state of the uplink signal, that is, the measurement result to the center management server 16 of the headend center 1 through the HFC network, thereby real-time in the center management server 16. It is possible to check the state of the uplink signal.

Although the preferred embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concepts of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

1 is a view showing the configuration of an HFC transmission network system according to the present invention,

2 is a diagram illustrating a configuration of an HFC transmission network monitoring apparatus according to the present invention.

<Explanation of symbols for the main parts of the drawings>

1: Headend Center 11: Headend Modulator

12: optical transmitter 13: optical receiver

14: cable modem termination device 16: center management server

3: HFC transmission network device 30: optical node unit

31: network amplifier 32: power supply

40: HFC transmission network monitoring device 41: filter unit

42: signal strength detection unit 43: signal comparison unit

43a: reference value generator 43b: comparator

43c: amplifier 44: digital converter

44a: sample / holder 44b: A / D converter

45: control unit 45a: comparison signal receiving unit

45b: data receiving unit 45c: event output unit

45d: module control unit

Claims (8)

HFC transmission network monitoring device installed in the HFC transmission network device for relaying the signal transmission between the subscriber terminal and the headend center connected through the HFC network to monitor the uplink signal transmitted from the subscriber terminal to the headend center through the HFC transmission network device To A filter unit which receives the uplink signal and filters a signal outside a preset frequency band; A signal strength detector for outputting an intensity signal having a voltage level corresponding to the signal strength of the upstream signal filtered by the filter; A signal comparison outputting a first comparison signal when the voltage level of the strength signal is greater than a voltage level of the reference signal; and outputting a second comparison signal when the voltage level of the strength signal is less than the voltage level of the reference signal. Wealth; A digital converter converting the strength signal output from the signal strength detector into a digital signal; When the first comparison signal and the second comparison signal are sequentially output from the signal comparison unit, the digital conversion unit converts the strength signal into a digital signal in response to receiving each of the first comparison signal and the second comparison signal. And a control unit which controls to convert, and determines a state of the uplink signal based on the converted digital signal corresponding to the first comparison signal and the second comparison signal, respectively. The method of claim 1, The signal strength detection unit HFC transmission network monitoring device, characterized in that provided in the form of RSSI (Received Signal Strength Indicator). The method of claim 1, The signal comparison unit, A reference value generator for outputting the reference signal; A comparator for comparing the intensity signal with the reference signal and outputting a logic signal having a logic value corresponding to the comparison result; And amplifying the logic signal output from the comparator and outputting the first comparison signal and the second comparison signal having a TTL level. The method according to any one of claims 1 to 3, The digital conversion unit, An A / D converter converting the strength signal into a digital signal; And a sample / holder configured to control signal conversion of the A / D converter under the control of the controller. The method of claim 4, wherein The control unit, A comparison signal receiving unit receiving the first comparison signal and the second comparison signal from the signal comparison unit; A data receiver which receives the digital signal converted by the digital converter; An event output unit for outputting an event signal for causing the A / D converter to convert the intensity signal into a digital signal to the sample / holder unit; When the first comparison signal and the second comparison signal are sequentially received through the signal comparison unit, the event output unit outputs the event signals corresponding to the received first comparison signal and the received second comparison signal, respectively. And a module controller configured to determine a state of the uplink signal based on the digital signal received through the data receiver. The method of claim 5, The filter part, the signal strength detector, the signal comparator and the digital converter are provided in a module form and connected to the HFC transmission network device; The controller is installed in the HFC transmission network device in the form of hardware and software HFC transmission network monitoring device. The method of claim 5, The HFC transmission network apparatus includes at least one of an optical node unit (ONU) and an amplifier. The method of claim 5, And the module control unit transmits information on the determined state of the uplink signal to the headend center through the HFC network.

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