JP4001836B2 - Wired network communication noise monitoring device and wired communication network noise monitoring system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a wired communication network inflow noise monitoring apparatus and a wired communication network inflow noise monitoring system that monitor inflow noise included in an upstream signal from a node to a center station in a wired communication network such as a CATV network.
[0002]
[Prior art]
In a wired communication network of tree type or hub type connection typified by a bidirectional cable television network, there is a specific noise called ingress noise in communication from the end of the network, that is, from the node to the center station (head end). Exists. This is a major obstacle to communication, and often causes communication interruption.
[0003]
As a means for monitoring such inflow noise, there is a system in which selection of an input signal to the spectrum analyzer is performed by sequentially switching a plurality of nodes by a switch such as a high-frequency switch.
[0004]
Patent Document 1 discloses a wired communication network joint noise measuring device capable of recording in real time the joint noise of a wired network composed of a plurality of trunk lines with a single spectrum analyzer.
[0005]
[Patent Document 1]
JP-A-11-55164
[0006]
[Problems to be solved by the invention]
However, the former method has a problem that the handling and operability of signal switching are difficult and the monitoring operation cannot be performed smoothly. That is, in the control method using only the high frequency switch, it is impossible to sequentially monitor only the desired nodes in advance, and the monitoring time (node switching timing) cannot be easily set or changed. Furthermore, the target node at the time of operation cannot be visually grasped (intuitive) with characters or the like. That is, since the node name is not displayed on the frequency spectrum monitoring screen (monitor screen), the node being monitored cannot be recognized in real time.
[0007]
In addition, as in Patent Document 1, in the method of combining signals and displaying a frequency spectrum, it is possible to recognize the presence or absence of infusion noise in band units, but the occurrence of infusion noise in node units. It cannot be recognized.
[0008]
The present invention has been made in view of the above-described problems, and can perform monitoring work smoothly and efficiently, and can be used for a wired communication network in-line noise monitoring apparatus and a wired communication network stream that are excellent in handling and operability. An object is to provide a noise monitoring system.
[0009]
In addition, the present invention provides a wired communication network infusion noise monitoring apparatus and a wired communication network infusion noise monitoring system capable of remotely monitoring the infusion noise and setting the monitoring operation of the infusion noise. Objective.
[0010]
[Means for Solving the Problems]
In order to achieve this object, the invention according to claim 1 is provided on the head end side as shown in FIG. 1 and is included in a plurality of high-frequency signals transmitted from a plurality of nodes on a wired communication network. A wire communication network monitoring device for monitoring combined noise, wherein the signal switching unit 110 selects one of a plurality of high-frequency signals transmitted from the plurality of nodes, and is selected by the signal switching unit 110. Observation means 130 for observing a high-frequency signal, and signal switching control means 120 for controlling the signal switching means 110 by designating a node that is a transmission destination of the high-frequency signal to be selected by the signal switching means 110, The signal switching control unit 120 includes one or more node groups to be monitored from the plurality of nodes, and an operation unit 122 to which a monitoring order of the node groups is input by a user operation; The node group inputted by the operation means 122 and the storage means 124 for storing the monitoring order, and the signal switching means 110 are selected according to the node group and the monitoring order stored in the storage means 124. And designation control means 123 for designating a node which is a transmission destination of the high frequency signal.
[0011]
Therefore, according to the first aspect of the present invention, the signal switching unit 110 that selects one of a plurality of high frequency signals transmitted from a plurality of nodes is monitored by the operation unit 122, and the node group By registering the group monitoring order in the storage unit 124 in advance, the designation control unit 123 designates the node group and the node that is the transmission destination of the high-frequency signal to be selected by the signal switching unit 110 according to the monitoring order. It is possible to monitor the inflow noise of the node group in the order in which only the node group to be monitored is desired, and the monitoring operation can be performed smoothly and efficiently. Further, by registering in advance, handling during monitoring work is not necessary, and handling and operability can be improved.
[0012]
According to a second aspect of the present invention, in the first aspect of the invention, the operation unit 122 further inputs a monitoring time of each node to be selected by the signal switching unit 110 according to the monitoring order of the node group by a user operation. The storage unit 124 further stores the monitoring time input from the operation unit 122, and the designation control unit 123 designates a node which is a transmission destination of the high frequency signal to be selected by the signal switching unit 110. In addition, the monitoring time is further designated, and the signal switching means 110 selects a high-frequency signal from the node designated by the designation control means 123 according to the monitoring time designated by the designation control means 123. It is said.
[0013]
Therefore, according to the second aspect of the present invention, the monitoring time of each node is registered in the storage unit 124 from the operation unit 122, and the node which is the transmission destination of the high frequency signal that the designation control unit 123 selects is selected. By specifying the monitoring time as well as specifying the user, the user can monitor the inflow noise of the node group in the order in which he or she only wants to monitor the node group and the monitoring time (switching time). It can be carried out smoothly and efficiently. For example, it is possible to set such that the monitoring time of a node to be focused on is long and the monitoring time of other nodes is short.
[0014]
The invention according to claim 3 is the invention according to claim 1 or 2, wherein the signal switching control means 120 is a frequency spectrum image of the high-frequency signal observed by the observation means 130 and a transmission destination of the high-frequency signal. An image superimposing unit 121 that superimposes the node name of the node, further including a display unit 140 that displays the frequency spectrum image with the node name superimposed by the image superimposing unit 121; The node name is input corresponding to the node input by the user operation, the storage unit 124 further stores the node name input from the operation unit 122, and the designation control unit 123 includes the signal switching unit. 110 designates a node which is a transmission destination of the high-frequency signal to be selected, and the node corresponding to the node. Further, the signal switching means 110 transmits the node name passed from the designation control means 123 to the image superimposing means 121 when selecting the high frequency signal from the node designated by the designation control means 123. It is characterized by that.
[0015]
Therefore, according to the third aspect of the present invention, the node name is registered in the storage unit 124 from the operation unit 122, and the node which is the transmission destination of the high frequency signal that the designation control unit 123 causes the signal switching unit 110 to select is designated. When the node name corresponding to the node is passed and the signal switching means 110 selects a high frequency signal from the designated node, the passed node name is transmitted to the image superimposing means 121, and the image superimposing means 121 By superimposing the image and the received node name and displaying the frequency spectrum image with the node name by the display means 140, the user can monitor any node in real time when monitoring the infusion noise with the frequency spectrum image. Therefore, it is possible to provide a device having an excellent user interface.
[0016]
As shown in FIG. 1, the invention according to claim 4 is a wired communication network that is provided on the head end side and monitors inflow noise included in a plurality of high-frequency signals transmitted from a plurality of nodes on the wired communication network. An ingress noise monitoring device 100; and a remote control device 200 that is provided on the node side and remotely controls the ingress communication noise monitoring device 100. The signal switching means 110 for selecting one of a plurality of high frequency signals transmitted from the plurality of nodes, the observation means 130 for observing the high frequency signal selected by the signal switching means 110, and the observation means 130 An image transmission means 150 for transmitting a frequency spectrum image of the high-frequency signal to the remote control device 200 using the first line of the wired communication network; 110 designates a node which is a transmission destination of a high frequency signal to be selected, and controls signal switching control means 120 for controlling the signal switching means 110, the wired communication network inflow noise monitoring apparatus 100, and the remote monitoring apparatus 200. A first communication means 160 for communicating control signals between them using a second line of the wired communication network, wherein the remote control device 200 monitors one or more of the plurality of nodes. A node group and an operation unit 202 in which a monitoring order of the node group is input by a user operation; the node group input by the operation unit 202; and the monitoring order included in the control signal; Second communication means 201 communicating with the signal switching control means 120 via the second line and the first communication means 160 and the image transmission means 150. An image receiving means 203 for receiving the wave number spectrum image; and a display means 204 for displaying the frequency spectrum image received by the first image receiving means 203, wherein the signal switching control means 120 is the first communication means. 160. The storage unit 124 that stores the node group and the monitoring order included in the control signal received via 160, and the signal switching unit 110 according to the node group and the monitoring order stored in the storage unit 124. And designation control means 123 for designating a node that is a transmission destination of the high-frequency signal to be selected.
[0017]
Therefore, according to the fourth aspect of the present invention, the wired communication network joint noise that is provided on the head end side and monitors the joint noise included in the plurality of high frequency signals transmitted from the plurality of nodes on the wired communication network. One or more node groups to be monitored from a plurality of nodes by using the second line of the wired communication network provided from the remote control device 200 in the storage unit 124 of the monitoring device 100 and the monitoring order of the node groups Is received and displayed using the first line of the wired communication network to display the frequency spectrum image that is the result of the observation, and the inflow noise from the remote (node side) instead of the headend side. Monitoring and inflow noise monitoring work can be set.
[0018]
The invention according to claim 5 is the invention according to claim 4, wherein the operation means 202 further inputs a monitoring time of each node to be selected by the signal switching means 110 according to the monitoring order of the node group by a user operation. The storage unit 124 further stores the monitoring time input from the operation unit 202, and the designation control unit 123 designates a node that is a transmission destination of the high-frequency signal to be selected by the signal switching unit 110. In addition, the monitoring time is further designated, and the signal switching means 110 selects a high-frequency signal from the node designated by the designation control means 123 according to the monitoring time designated by the designation control means 123. It is said.
[0019]
Therefore, according to the fifth aspect of the present invention, the monitoring time of each node is registered in the storage unit 124 from the operation unit 202, and the node that is the transmission destination of the high-frequency signal that the designation control unit 123 causes the signal switching unit 110 to select is selected. By specifying the monitoring time as well as specifying the user, the user can monitor the inflow noise of the node group in the desired order and the monitoring time (switching time) of the node group to be monitored. Monitoring work can be performed smoothly and efficiently.
[0020]
The invention according to claim 6 is the invention according to claim 4 or 5, wherein the signal switching control means 120 is a frequency spectrum image of the high frequency signal observed by the observation means 130 and a transmission destination of the high frequency signal. An image superimposing unit 121 that superimposes the node name of the node is further included, and the image transmitting unit 150 transmits the frequency spectrum image with the node name superimposed by the image superimposing unit 121 to the image receiving unit 203. The display means 204 displays the node name-added frequency spectrum image received by the image receiving means 203, and the operation means 202 inputs the node name by the user operation. The storage means 124 stores the node name input from the operation means 202. The designation control means 123 designates a node that is a transmission destination of the high-frequency signal to be selected by the signal switching means 110, and further passes the node name corresponding to the node, so that the signal switching means 110 Is characterized in that, when selecting a high-frequency signal from the node designated by the designation control means 123, the node name passed from the designation control means 123 is transmitted to the image superimposing means 121.
[0021]
Therefore, according to the sixth aspect of the present invention, the node name is registered in the storage unit 124 from the operation unit 202, and the node that is the transmission destination of the high frequency signal that the designation control unit 123 causes the signal switching unit 110 to select is designated. When the node name corresponding to the node is passed and the signal switching means 110 selects a high frequency signal from the designated node, the passed node name is transmitted to the image superimposing means 121, and the image superimposing means 121 By superimposing the image and the received node name, the display unit 204 displays the frequency spectrum image with the node name received via the image transmission unit 150, the first line, and the image reception unit 203, so that the user Can recognize which node it is in real time when monitoring inflow noise with frequency spectrum image, It is possible to provide an excellent device over THE interface.
[0022]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.
FIG. 1 is a block diagram showing a configuration of a wired communication network inflow noise monitoring system in an embodiment of the present invention. The following description will be made on the assumption that the wired communication network is a CATV (Cable Television) network. The wired communication network ingress noise monitoring apparatus 100 provided on the head end side of the CATV network includes a signal switch 110, a signal switch controller 120, a spectrum analyzer 130, a monitor 140, a modulator 150, and a modem 160. Prepare.
[0023]
The signal switcher 110 includes an RF signal switching relay 111, a CPU 112, a storage unit 113, and a communication IF circuit 114. The RF signal switching relay 111 selects one of a plurality of RF signals input from the uplink from each node of the CATV network to the head end according to an instruction from the CPU 112 and outputs the selected signal to the spectrum analyzer 130.
[0024]
The CPU 112 transmits the node name of the node selected by the RF signal switching relay 111 to the screen superimposing circuit 121 via the communication IF circuit 114 and the communication IF circuit 128 of the signal switching controller 120. Further, the CPU 112 receives node information such as a node name from the CPU 123 via the communication IF circuit 114 and the communication IF circuit 127 of the signal switching controller 120.
[0025]
When the CPU 112 receives an instruction to monitor the RF signal of a predetermined node from the CPU 123 of the signal switching controller 120 for a predetermined time, the CPU 112 instructs the RF signal switching relay 111 to select the node for a specified time. At the same time, the node name of the node is transmitted to the screen superimposing circuit 121.
[0026]
Alternatively, a node group group registered in advance in a predetermined monitoring order is received as node information from the CPU 123 and stored in the storage unit 113. This node information includes the name of each node, the name of the group, and the monitoring time of each node. When the CPU 112 receives the monitoring instruction for the group from the CPU 123 of the signal switching controller 120, the CPU 112 reads out the node and the monitoring time of the node in the monitoring order of the group from the storage unit 113, and selects the node for the designated time. Instruct the RF signal switching relay 111 as follows. At the same time, the node name of the node is transmitted to the screen superimposing circuit 121.
[0027]
The storage unit 113 stores a program for operating the CPU 112, node information received from the signal switching controller 120, and the like. The communication IF circuit 114 is connected to the communication IF circuit 127 and the communication IF circuit 128 of the signal switching controller 120 and transmits / receives data.
[0028]
The signal switching controller 120 includes a screen superimposing circuit 121, a touch panel operation unit 122, a CPU 123, a storage unit 124, a communication IF circuit 125, a communication IF circuit 126, a communication IF circuit 127, and a communication IF circuit 128. To control.
[0029]
The screen superimposing circuit 121 receives the frequency spectrum image data received from the spectrum analyzer 130, and receives the node name of the node currently selected by the RF signal switching relay 111 from the CPU 112 of the signal switcher 110. Then, the received node name is superimposed on a predetermined position of the received frequency spectrum image. The frequency spectrum image data with the node name after superposition is output to the monitor 140 and the modulator 150.
[0030]
The touch panel operation unit 122 is a device that performs pointing by directly touching a display on which a menu or the like is displayed with a finger or a pen. In this embodiment, a user who is an administrator of the CATV network uses the touch panel operation unit 122 to perform operations such as node information setting registration, node information change, and ingress noise monitoring start instruction. The node information set and registered by the touch panel operation unit 122 is input to the CPU 123 and stored in the storage unit 124.
[0031]
The CPU 123 stores the node information input from the touch panel operation unit 122 in the storage unit 124. In addition, when a command to start monitoring of infusion noise by designating a group name is input from the touch panel operation unit 122, a node group belonging to the group is read from the storage unit 124. Then, the node identification information, the node name, and the monitoring time of the node are transmitted from the node group belonging to the group to the CPU 112 via the communication IF circuit 127 and the communication IF circuit 114 of the signal switch 110 in the monitoring order. . When these node information is stored in the storage unit 113 of the signal switcher 110, a monitoring group is designated and a command to start monitoring of infusion noise is transmitted to the CPU 112 of the signal switcher 110.
[0032]
The CPU 123 controls the remote touch panel operation unit 202 via the communication IF circuit 126, the modem 160, the CATV line, and the modem 201. Similarly to the touch panel operation unit 122, the remote touch panel operation unit 202 also receives a command for registering node information settings and starting monitoring of inflow noise. The CPU 123 is connected to the spectrum analyzer 130 via the communication IF circuit 125 and exchanges various setting information and status information.
[0033]
The storage unit 124 stores programs for operating the CPU 123, node information input from the touch panel operation unit 122 or the remote touch panel operation unit 202, and the like. The communication IF circuit 125 is an interface for communicating with the spectrum analyzer 130, and may use a serial port such as GPIB (General Purpose Interface Bus), or an Ethernet (registered trademark) port using an Ethernet (registered trademark) port. Signals may be sent and received.
[0034]
The communication IF circuit 126 is an interface for communicating with the modem 160, and uses a serial port such as RS232c. The communication IF circuit 127 is a transmission interface for transmitting node information to the signal switcher 110. The communication IF circuit 128 is a reception interface that receives a screen superimposition command including the node name of the node currently selected by the RF signal switching relay 111 from the signal switch 110.
[0035]
The spectrum analyzer 130 is a measuring instrument that divides and displays a high-frequency signal into frequency components. The vertical axis represents intensity and the horizontal axis represents frequency. In this embodiment, a spectrum analyzer that can display in real time is used. The spectrum analyzer 130 calculates the frequency spectrum of the RF signal by performing, for example, fast Fourier transform on the waveform data of the RF signal input from the RF signal switching relay 111 of the signal switcher 110. The calculated frequency spectrum is displayed as an image, and at the same time, the spectrum image of the RF signal is output to the screen superimposing circuit 121. The spectrum analyzer 130 may receive the waveform data of the RF signal input from the RF signal switching relay 111 via a serial port such as GPIB, or use an Ethernet (registered trademark) port to provide an Ethernet (registered trademark) signal. You may receive by. The same applies to the output to the screen superimposing circuit 121.
[0036]
The monitor 140 displays the frequency spectrum image data with the node name generated by the screen superimposing circuit 121. The modulator 150 modulates the frequency spectrum image data with the node name generated by the screen superimposing circuit 121 and transmits it to the demodulator 203 of the node 200 via the downlink of the CATV network.
[0037]
The modem 160 is for performing communication between the CPU 123 of the signal switching controller 120 and the remote touch panel operation unit 202 of the node 200 using the upper and lower lines of the CATV network. The modem 160 outputs a control signal output from the CPU 123. Modulate. Further, a signal such as node information input to the CPU 123 is demodulated.
[0038]
The remote control device 200 provided on the head end side includes a modem 201, a remote touch panel operation unit 202, a demodulator 203, and a monitor 204. The modem 201 is for performing communication between the CPU 123 of the signal switching controller 120 and the remote touch panel operation unit 202 using the upper and lower lines of the CATV network, and node information output from the remote touch panel operation unit 202. And so on. Further, the control signal output to the remote touch panel operation unit 202 is demodulated.
[0039]
The remote touch panel operation unit 202 has the same function as the touch panel operation unit 122 of the signal switching controller 120. A user who is an administrator of the CATV network can also perform operations such as setting registration of node information, changing node information, and instructing start of monitoring of inflow noise from the remote touch panel operation unit 202.
[0040]
The demodulator 203 demodulates the frequency spectrum image data with the node name received from the modulator 150 of the signal switching controller 120 via the downlink of the CATV network, and outputs it to the monitor 204. The monitor 204 displays the frequency spectrum image data with the node name input from the demodulator 203.
[0041]
Next, usage examples of the wired communication network inflow noise monitoring apparatus and system according to the embodiment of the present invention will be described. A user who is an administrator of the CATV network calls a node list editing screen as shown in FIG. 2, for example, on the touch panel operation unit 122 or the remote touch panel operation unit 202, and registers the name of each node by keyboard input. The registered node name is stored in the storage unit 124.
[0042]
Next, for example, an automatic screen as shown in FIG. 3 is called to select and register a plurality of nodes to be monitored from the node group in the node list. At this time, the monitoring time of each node, the node monitoring order, and whether or not a node name is added can be set. These settings are also stored in the storage unit 124. Next, a memory name registration screen as shown in FIG. 4 is called to register the group name (memory name) in which the node group to be monitored is stored. The registered group name is also stored in the storage unit 124.
[0043]
Thereafter, when the user selects a group name from the screen of the touch panel operation unit 122 or the remote touch panel operation unit 202, the node group belonging to the group and the monitoring time can be reproduced and displayed. Then, the node belonging to the group can be changed (including increase / decrease), the node monitoring order can be changed, the node monitoring time can be changed, and the setting of the node name can be changed. For example, the node monitoring time may be set such that a node having a high probability of occurrence of joint noise in the past is lengthened and a node having a low probability of occurrence of joint noise is shortened. It is also conceivable to set the node monitoring time according to the monitoring purpose. For example, it is possible to shorten the node monitoring time in the case of normal inspection and to increase the node monitoring time in the case of investigation.
[0044]
When the user wants to perform automatic node monitoring, the user calls the automatic screen as shown in FIG. 3 on the touch panel operation unit 122 or the remote touch panel operation unit 202, specifies the group name, and presses the start button. As a result, automatic sequential monitoring of the nodes belonging to the group can be executed. At this time, the frequency spectrum image of each node displayed on the monitor 140 or the monitor 204 is switched during the monitoring time designated in advance. This spectrum image is given the node name of the node being displayed. Note that when the frequency spectrum image is set not to have a node name, the node name is not added. In the case of a monitoring device that does not have the screen superimposing circuit 121, the node name cannot be added to the frequency spectrum image.
[0045]
FIG. 5 shows an example of a table of node groups registered as a group in the storage unit 124. The group name and node name can be arbitrarily assigned on the user side. In FIG. 5, for example, groups named “inspection”, “investigation”, and “understanding” are registered as group names. For example, “A town”, “B town” and the like are registered as node names. For example, the “inspection” group is registered in the monitoring order of nodes “A town” → “P town” → “R town” → “U town” → “Z town”. The nodes belonging to each group can be increased or decreased as necessary.
[0046]
The above-described embodiment shows an example of a preferred embodiment of the present invention, and the present invention is not limited thereto, and various modifications can be made without departing from the scope of the invention.
[0047]
In the above description, an example of the operation using the touch panel has been described. In this regard, a personal computer PC may be used instead of the touch panel. In this case, the user performs an operation using the display and keyboard of the personal computer.
[0048]
In addition, the monitor for observing the spectrum image in the above description need not be provided when a touch panel having a capture function is used because the frequency spectrum image can be observed from the touch panel screen. Further, when a PC on which a capture card is mounted is used, it may not be provided.
[0049]
In the above description, an example in which a head end and a node are connected by serial communication using a modem, a modulator, and a demodulator has been described. In this regard, when the transmission path is Ethernet (registered trademark), a media converter or the like is used instead of the modem, the modulator, and the demodulator. By setting the transmission line to Ethernet (registered trademark), it becomes possible to control the spectrum analyzer, save spectrum image data, and the like. When the storage is possible, an alarm signal can be output and notified to a user (security officer) by comparison with a preset data value.
[0050]
【The invention's effect】
As is apparent from the above description, according to the first aspect of the present invention, the signal switching means for selecting one from a plurality of high-frequency signals transmitted from a plurality of nodes is monitored by the operation means. By registering the node group and the monitoring order of the node group in the storage means in advance, the designation control means designates the node group and the node that is the transmission destination of the high-frequency signal that is selected by the signal switching means according to the monitoring order. Can monitor the inflow noise of the node groups in the order in which only the node groups to be monitored are desired, and can perform the monitoring work smoothly and efficiently. Further, by registering in advance, handling during monitoring work is not necessary, and handling and operability can be improved.
[0051]
According to the invention described in claim 2, in addition to the effect of the invention described in claim 1, the monitoring time of each node is registered in the storage means from the operation means, and the high-frequency signal to be selected by the designation control means by the signal switching means By specifying the destination node and also specifying the monitoring time, the user can monitor the ingress noise of the node group in the order in which only the node group to be monitored is desired and the monitoring time (switching time). Therefore, monitoring work can be performed smoothly and efficiently. For example, it is possible to set such that the monitoring time of a node to be focused on is long and the monitoring time of other nodes is short.
[0052]
According to the invention described in claim 3, in addition to the effect of the invention described in claim 1 or 2, the node name is registered in the storage means from the operation means, and the high frequency signal is transmitted by the designation control means to be selected by the signal switching means. When specifying the node that is the destination, the node name corresponding to the node is passed, and when the signal switching means selects the high-frequency signal from the designated node, the passed node name is transmitted to the image superimposing means, and the image superimposing means The means superimposes the frequency spectrum image and the received node name, and the display means displays the frequency spectrum image with the node name, so that the user can monitor the infusion noise in the frequency spectrum image in real time. It is possible to recognize which node the node belongs to, and to provide a device having an excellent user interface.
[0053]
According to the fourth aspect of the present invention, the wired communication network inflow noise monitoring device is provided on the head end side and monitors the inflow noise included in the plurality of high frequency signals transmitted from the plurality of nodes on the wired communication network. In the storage means, one or more node groups to be monitored from a plurality of nodes using a second line of a wired communication network from a remote control device provided on the node side, and the monitoring order of the node groups are registered. By receiving and displaying the frequency spectrum image, which is the observation result obtained according to, using the first line of the wired communication network, monitoring the inflow noise from the remote (node side) instead of the headend side Noise monitoring work can be set.
[0054]
According to the invention described in claim 5, in addition to the effect of the invention described in claim 4, the monitoring time of each node is registered in the storage means from the operation means, and the high frequency signal to be selected by the designation control means is selected by the signal switching means. By specifying the destination node and also specifying the monitoring time, the user can monitor the ingress noise of the node group in the order in which only the node group to be monitored is desired and the monitoring time (switching time). Monitoring can be performed smoothly and efficiently from a remote location.
[0055]
According to the invention described in claim 6, in addition to the effect of the invention described in claim 4 or 5, the node name is registered in the storage means from the operation means, and the high frequency signal is transmitted by the designation control means to be selected by the signal switching means. When specifying the node that is the destination, the node name corresponding to the node is passed, and when the signal switching means selects the high-frequency signal from the designated node, the passed node name is transmitted to the image superimposing means, and the image superimposing means The means superimposes the frequency spectrum image and the received node name, and the display means displays the frequency spectrum image with the node name received via the image transmitting means, the first line, and the image receiving means. The user can recognize in real time which node the inflow noise is monitored with the frequency spectrum image, and the user interface is excellent. It is possible to provide a.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of a wired communication network inflow noise monitoring system according to an embodiment of the present invention.
FIG. 2 is a diagram showing a node list editing screen.
FIG. 3 is a diagram showing an automatic screen.
FIG. 4 is a diagram showing a memory name registration screen.
FIG. 5 is a diagram illustrating an example of a node group table;
[Explanation of symbols]
100 Wired network communication noise monitoring device
110 Signal switching device (signal switching means)
111 RF signal switching relay
112 CPU
113 storage unit
114 Communication IF circuit
120 signal switching controller (signal switching control means)
121 Screen superimposing circuit (image superimposing means)
122 Touch panel operation unit (operation means)
123 CPU (designated control means)
124 storage unit (storage means)
125-128 communication IF circuit
130 Spectrum analyzer (observation means)
140 Monitor (display means)
150 modulator (image transmission means)
160 Modem (first communication means)
200 Remote control device
201 Modem (second communication means)
202 Remote touch panel operation unit (operation means)
203 Demodulator (image receiving means)
204 Monitor (display means)

Claims (6)

A wired communication network inflow noise monitoring device that is provided on the head end side and monitors inflow noise included in a plurality of high frequency signals transmitted from a plurality of nodes on the wired communication network,
Signal switching means for selecting one of a plurality of high-frequency signals transmitted from the plurality of nodes;
Observation means for observing the high-frequency signal selected by the signal switching means;
A signal switching control means for controlling the signal switching means by designating a node which is a transmission destination of the high-frequency signal to be selected by the signal switching means,
The signal switching control means includes
One or more node groups monitored from the plurality of nodes, and an operation means for inputting a monitoring order of the node groups by a user operation;
Storage means for storing the node group input by the operation means and the monitoring order;
Designation control means for designating a node that is a transmission destination of the high-frequency signal to be selected by the signal switching means in accordance with the node group stored in the storage means and the monitoring order;
A wired communication network inflow noise monitoring apparatus, comprising: The operation means is further input by a user operation with a monitoring time of each node to be selected by the signal switching means according to the monitoring order of the node group,
The storage means further stores the monitoring time input from the operation means,
The designation control means designates a node which is a transmission destination of a high frequency signal to be selected by the signal switching means, further designates the monitoring time,
2. The wired communication network joint noise according to claim 1, wherein the signal switching unit selects a high-frequency signal from a node designated by the designation control unit according to a monitoring time designated by the designation control unit. Monitoring device. The signal switching control means includes
Image superimposing means for superimposing the frequency spectrum image of the high-frequency signal observed by the observation means and the node name of the node to which the high-frequency signal is transmitted;
A display means for displaying the node-named frequency spectrum image superimposed by the image superimposing means;
The operation means inputs the node name corresponding to the node input by the user operation,
The storage means further stores a node name input from the operation means,
The designation control means designates a node which is a transmission destination of a high frequency signal to be selected by the signal switching means, and further passes the node name corresponding to the node,
2. The signal switching means, when selecting a high-frequency signal from a node designated by the designation control means, transmits the node name passed from the designation control means to an image superimposing means. The wired communication network inflow noise monitoring device according to 2. A wired communication network inflow noise monitoring device that is provided on the head end side and monitors inflow noise included in a plurality of high-frequency signals transmitted from a plurality of nodes on the wired communication network;
A remote control device that is provided on the node side and remotely controls the wired communication network inflow noise monitoring device;
The wired communication network inflow noise monitoring device is
Signal switching means for selecting one of a plurality of high-frequency signals transmitted from the plurality of nodes;
Observation means for observing the high-frequency signal selected by the signal switching means;
An image transmission means for transmitting a frequency spectrum image of the high-frequency signal observed by the observation means to the remote control device using a first line of the wired communication network;
A signal switching control means for controlling the signal switching means by designating a node which is a transmission destination of the high-frequency signal to be selected by the signal switching means;
First communication means for communicating a control signal between the wired communication network inflow noise monitoring apparatus and the remote monitoring apparatus using a second line of the wired communication network;
The remote control device is:
One or more node groups monitored from the plurality of nodes, and an operation means for inputting a monitoring order of the node groups by a user operation;
The node group inputted by the operation means and the monitoring order are included in the control signal and communicated to the signal switching control means via the second line of the wired communication network and the first communication means. A second communication means;
Image receiving means for receiving the frequency spectrum image transmitted by the image transmitting means;
Display means for displaying a frequency spectrum image received by the image receiving means,
The signal switching control means includes
Storage means for storing the node group included in the control signal received via the first communication means, and the monitoring order;
A wired communication network comprising: the node group stored in the storage unit; and a designation control unit that designates a node that is a transmission destination of a high-frequency signal to be selected by the signal switching unit in accordance with the monitoring order. Ingot noise monitoring system. The operation means is further input by a user operation with a monitoring time of each node to be selected by the signal switching means according to the monitoring order of the node group,
The storage means further stores the monitoring time input from the operation means,
The designation control means designates a node which is a transmission destination of a high frequency signal to be selected by the signal switching means, further designates the monitoring time,
5. The wired communication network joint noise according to claim 4, wherein the signal switching means selects a high frequency signal from a node designated by the designation control means according to a monitoring time designated by the designation control means. Monitoring system. The signal switching control means includes
Image superimposing means for superimposing the frequency spectrum image of the high-frequency signal observed by the observation means and the node name of the node to which the high-frequency signal is transmitted;
The image transmitting means transmits the node-named frequency spectrum image superimposed by the image superimposing means to the image receiving means using the first line,
The display means displays the frequency spectrum image with the node name received by the image receiving means,
The operation means inputs the node name corresponding to the node input by the user operation,
The storage means further stores a node name input from the operation means,
The designation control means designates a node which is a transmission destination of a high frequency signal to be selected by the signal switching means, and further passes the node name corresponding to the node,
5. The signal switching means, when selecting a high frequency signal from a node designated by the designation control means, transmits a node name passed from the designation control means to an image superimposing means. 5. The in-line noise monitoring system for wired communication networks according to 5.

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