JP2004072477A - Upward streamed noise detection system in catv equipment - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To quickly and effectively detect a GSW (gate switch) being a mixing source of streamed noise mixed in an up line in a CATV broadcasting system Psys. <P>SOLUTION: In an examination system, it is automatically discriminated whether streamed noise exists or not while switching GSWs, and a result is displayed and recorded at each time when a GSW which makes streamed noise disappear when opened is found, and thus the mixing source of streamed noise is specified. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an ingress noise detection system for quickly and effectively detecting ingress noise mixed in an uplink in a CATV facility.
[0002]
[Prior art]
FIG. 10 shows the configuration of the entire system of a conventional CATV (cable television broadcast). The CATV broadcasting system Csys basically includes a CATV content transmission device 10, a transmission network connector 11, and a CATV transmission network group 12. The CATV transmission line network group 12 is composed of a group of n smaller (n is an arbitrary natural number) CATV transmission line networks which are smaller units. In FIG. The network group 12 includes a first CATV transmission network 12_1, a second CATV transmission network 12_2, a third CATV transmission network 12_3, and an m-th CATV transmission network 12_m (any of 3 ≦ m <n , And only the n-th CATV transmission line network 12_n are illustrated.
[0003]
The CATV content transmitting apparatus 10 distributes content mainly composed of video signals (hereinafter, “CATV content”) to the CATV transmission line network group 12. That is, the transmission path network connector 11 is connected so as to transmit the content signal from the normal CATV transmission apparatus 10 to all the CATV transmission path networks 12_1 to 12_n constituting the CATV transmission path network group 12. However, the transmission line network connector 11 cannot specify any one of the n connected CATV transmission line networks 12_1 to 12_n and control so as to pass or block the upstream band thereof.
[0004]
FIG. 11 shows an example of the configuration of an arbitrary CATV transmission line network 12 — m that constitutes the above-mentioned CATV transmission line network group 12. The CATV transmission line network 12_m mainly includes a coaxial cable network and a relay amplifier. In the figure, a straight line represents a coaxial cable, and a horizontal triangle represents a relay amplifier. The number shown in the horizontal triangle is a sign for identifying each of the relay amplifiers. Therefore, when it is necessary to identify individual relay amplifiers, a mark is added as a suffix of the relay amplifier in this specification. Hereinafter, in the present specification, the m-th CATV transmission line network 12_m generically represents all the CATV transmission line networks constituting the CATV transmission line network group 12. That is, in this case, m is an arbitrary natural number of 1 or more and n or less.
[0005]
Among these relay amplifiers, an amplifier for transmitting a signal from the CATV content transmitting apparatus 10 in the terminal direction of the trunk line or the branch line (this direction is referred to as “downward direction”), and an amplifier for transmitting the signal in the upward direction from the terminal direction. An amplifier for transmitting a signal to the signal receiving device (this direction is referred to as “up direction”) is included. Further, the upstream amplifier further includes a GSW (Gate Switch) for passing and blocking a signal. In the figure, a trunk GSW arranged on a trunk line and a branch GSW arranged on a branch line are shown.
[0006]
The relay amplifier can transmit the signal transmitted from the CATV content transmitting apparatus 10 to the end direction of the trunk line of the CATV transmission line network 12_m, that is, to the downstream method, and can connect the branch line branched from the trunk line. FIG. 11 shows an example in which four branch lines emerge from one trunk line. In other words, a trunk line LM is laid between the relay amplifier 1 and the relay amplifier 10, two branch lines LB1 and LB2 extend from the relay amplifier 1 and the relay amplifier 10, and two branch lines LB3 and LB4 extend from the relay amplifier 10. Is out. In this example, the tip of the relay amplifier 10 is the end of the main line LM, and is referred to as the main line end Tlm. Here, the branch line LB1 and the like are described as two branch lines, but it is needless to say that the number of branch lines is not limited to two.
[0007]
The relay amplifier 2 and the relay amplifier 5 are connected to the terminating end of the branch line LB1, respectively. A branch line LB11 further exits from the relay amplifier 2, and a relay amplifier 6 and a relay amplifier 7 are connected to the end portions thereof, respectively. The branch line LB111 and the branch line LB112 exit from the relay amplifier 6 and the relay amplifier 7, respectively. Similarly, from the relay amplifier 5, a branch line LB12 to which the relay amplifier 8 and the relay amplifier 9 are connected at the end is provided. From the relay amplifier 8 and the relay amplifier 9, a branch line LB121 and a branch line LB122 respectively emerge.
[0008]
The relay amplifier 3 and the relay amplifier 4 are connected to the terminating end of the branch line LB2, respectively. Then, a branch line LB21 emerges from the relay amplifier 3, and a branch line LB22 emerges from the relay amplifier 4.
[0009]
Also, as for the relay amplifier 10, similarly to the relay amplifier 1, the branch line LB3, the relay amplifier 11, the branch line LB31, the relay amplifier 15, the branch line LB311, the relay amplifier 16, the branch line LB312, the relay amplifier 14, and the branch line LB32 , The relay amplifier 17, the branch line LB321, the relay amplifier 18, the branch line LB322, the branch line LB4, the relay amplifier 12, the branch line LB41, the relay amplifier 13, and the branch line LB42. In addition, each branch line transmits a signal in the terminal direction of the branch line, and further, a branch line can be installed. The number of relay amplifiers is not particularly limited.
[0010]
FIG. 12 shows an example of the state of the terminal transmission line. The relay amplifier 18 of the m-th CATV transmission line network 12_m shown in FIG. 11 will be described as an example. In the figure, U1 to U5 each represent a CATV broadcast user's house. The user's house U1 is an apartment house such as a condominium (condominium), and the user's houses U2 to U5 are independent houses. As exemplified in the user's home U5, a monitor such as a CATV terminal HT and a TV is installed in the user's home.
Usually, 4 to 5 branch / distributors BD1 to BD5 are installed on the branch line LB322 coming out of the relay amplifier 18, and 2 to 8 cables are connected to each of the branch / distributor BD. Is done. The individual cables coming out of the branch / distributor BD2 are connected to CATV terminals HT installed in the user's doors U1 to U5, and the content is distributed using a television or the like as a monitor DM. The cable may be connected not only to one house but also to an apartment house U1 such as an apartment (condominium).
[0011]
As described above, the main service of the CATV broadcasting system Csys is to transmit the content from the CATV content transmitting apparatus 10 installed on the station side to the user's home U, but not only that, but also from the user's home to the station side. Service (corresponding to the "upward direction" described above) is also provided.
[0012]
FIG. 13 shows an outline of a frequency use band of a cable used in the CATV broadcast system Csys. The content transmitted from the station to the user is transmitted in the downward direction in a band of 70 MHz to 770 MHz, and the band of 10 MHz to 55 MHz is used for the so-called upward direction from the user to the station side. The former is called a downlink band BSd, and the latter is called an uplink band BSu. Further, communication in the downlink direction using the downlink band BSd is referred to as “downlink”, and communication in the uplink direction using the uplink band BSu is referred to as “uplink”.
[0013]
By the way, with the recent electronic use of home electric appliances, various household noises are mixed in a band up to 55 MHz used for uplink communication (uplink). That is, there is an environment in which noise is more likely to be mixed in the uplink direction (uplink) than in the downlink direction (downlink). Therefore, by incorporating a trunk GSW and a branch GSW in the upstream band in the relay amplifier on the CATV transmission network and controlling the passing and blocking of the upstream band, it is possible to control the mixing of noise from the terminal direction into the upstream line. Both the trunk GSW and the branch GSW are collectively called GSW.
[0014]
All GSWs are assigned unique numbers or addresses, and can individually and manually control the passage and cutoff of the upstream band of a signal by an external command. In this specification, a marker for identifying each of the relay amplifiers between 1 and 18 described with reference to FIG. 11 is a GSW address for convenience. That is, GSW1 to GSW18 are the addresses of each of the 18 GSWs.
[0015]
As shown in FIG. 10, the CATV broadcasting system Csys includes an upstream signal receiving device 13, a noise detecting device 14, and a GSW switching device 15 in addition to the above-described configuration. The uplink signal receiving device 13 is a device that receives a signal directed from a user to a station. This device receives a signal from a CATV terminal HT installed in a user's home and provides a user with a connection service to the Internet network 16 outside the station.
[0016]
In uplink communication of the CATV broadcasting system Csys, one uplink signal receiving device 13 receives signals from all users at the end via a number of GSWs. Therefore, when viewed from the station where the uplink signal receiving device 13 is installed, noise is superimposed on the entire uplink of the CATV broadcast system Csys due to noise from some GSW. This is called ingress noise and causes a decrease in service due to all uplinks of the CATV broadcasting system Csys.
[0017]
The system administrator needs to keep track of the state of the ingress noise. Therefore, a CATV broadcast system Csys is provided with a noise detection device 14 and a GSW switching device 15. The noise detector 14 detects all noises and signals flowing into the band used in the uplink, but cannot determine the distinction between noises and signals.
[0018]
As described above, the GSWs each have a unique address, and can switch between passing and blocking the upstream band according to an external command. In particular, the trunk GSW can manually and independently pass and block the upstream band only for the trunk line and the branch GSW can independently pass and block the upstream band only for the branch line. The GSW switching device 15 can specify an individual GSW on the CATV transmission line network (12_m) and transmit a command to pass or block an upstream band.
[0019]
Therefore, when the occurrence of ingress noise is detected by the noise detection device 14, the system administrator manually checks the GSW on the CATV transmission line network in order by the GSW switching device 15 while checking the state of the noise. It is possible to identify from which GSW on the CATV transmission line network 12_m the inflow noise is mixed while passing or blocking, thereby preventing the noise from being mixed.
[0020]
[Problems to be solved by the invention]
However, the number of GSWs on one CATV transmission line network is several hundred or more. In other words, there are thousands of GSWs in all systems having a plurality of CATV transmission path networks. It takes a very long time to specify the GSW from which noise is mixed while manually switching these GSWs one by one. Therefore, before the GSW of the mixing source is specified, the noise is eliminated and it is difficult to find the mixing source. In addition, for occasional noise, it is necessary to stand by and find the source of contamination in a short time. In addition, due to human errors such as mistakes in recording, duplicate investigation, and forgetting to investigate, the work leading to the discovery of the source of the ingress noise was extremely difficult.
Accordingly, an object of the present invention is to provide an upstream ingress noise detection system in a CATV facility that specifies a GSW that is a source of noise while automatically switching a large number of GSWs of thousands.
[0021]
[Means for Solving the Problems]
In order to solve the above-mentioned problem, the present invention provides a CATV broadcasting system with a means for quantitatively measuring noise on the uplink signal receiving device 13 side and determining the presence or absence of ingress noise, and a GSW on a CATV transmission line network. By incorporating means for automatically and quickly passing and blocking the upstream band, and means for displaying only the GSW that eliminates noise when cut off, the source of ingress noise from the thousands of GSWs Can be detected and displayed.
[0022]
BEST MODE FOR CARRYING OUT THE INVENTION
FIG. 1 shows a configuration of a CATV broadcasting system Psys incorporating the ingress noise detection system of the present invention. The CATV broadcasting system Psys is different from the conventional CATV broadcasting system Csys shown in FIG. network The connection device 11 and the noise detection device 14 are replaced with a transmission line network switch 11r and an ingress noise detection system RNT, respectively, according to the present invention. As mentioned above , Biography The transmission network connector 11 can connect the content signal from the normal CATV content transmission device 10 to all of the CATV transmission network 12_1 to 12_n constituting the CATV transmission network group 12, but the n CATV transmissions. It is not possible to specify any one of the road networks 12_1 to 12_n and control to pass or block the upstream band thereof. On the other hand, the transmission line network switch 11r can specify any one of the n CATV transmission line networks 12_1 to 12_n, and control to switch the connection that passes or blocks the upstream band. Therefore, the description of the configuration, operation, and features common to the CATV broadcasting system Csys is omitted unless it is particularly necessary.
[0023]
In the CATV broadcasting system Psys, as in the CATV broadcasting system Csys, the uplink signal receiving device 13 receives a service for a transmission signal from a user. Similarly, the GSW of the relay amplifier constituting the CATV transmission line network group 12 is controlled to remotely pass or block the upstream band. The ingress noise detection system RNT includes a control device 110, a storage device 122, and a display device 120.
[0024]
The control device 110 receives the signal from the input terminal of the upstream signal receiving device 13, determines the presence or absence of noise, and controls the passing / blocking of the upstream band of the CATV transmission line network and the GSW. It has a function of detecting a certain GSW, displaying the results thereof, and notifying a system administrator. Therefore, control device 110 further includes a signal state detection unit 112, an ingress noise determination unit 114, an up band pass cutoff control unit 116, and a display control unit 118. The storage device 122 includes a GSW list 126 that records the connection state of the GSWs on each CATV transmission path network and a survey result list 124 that records the survey results.
[0025]
In the control device 110, the signal state detection unit 112 can observe the signal at the input terminal of the uplink signal receiving device 13 on the frequency axis, and can measure the energy state of the signal or noise at a specific frequency. For example, a spectrum analyzer, an FFT (Fast Fury Transducer) analyzer, or the like can be used. The ingress noise determination unit 114 sets a certain threshold value for the state of system noise in a state where no ingress noise is mixed, and when there is noise exceeding the threshold value, there is ingress noise, If there is no ingress noise, it is determined that there is no ingress noise.
[0026]
The up-band-pass cutoff control unit 116 can individually control the transmission line network switch 11r and the GSW on the m-th CATV transmission line network 12_m, and can switch and control the passage and cutoff of the upstream band. The display control unit 118 controls the display device, and displays the GSW determined by the ingress noise determination unit 114 to have no ingress noise each time the upstream band pass cutoff control unit 116 controls the pass / block of the upstream band. I do. Also, by displaying the connection history from the first relay amplifier in the CATV transmission line network, it is possible to easily recognize the source of the ingress noise.
[0027]
Next, the operation of the ingress noise detection system RNT will be briefly described. When the ingress noise detection system RNT is started, first, the ingress noise determination unit 114 in the control device 110 is initialized. Next, the signal state when all the GSWs are turned off is recorded. At this time, since no upstream signal is input from any GSW, there is no ingress noise at all, and the initial value is used for ingress noise detection. Check at least the band to be used as the uplink.
[0028]
Next, a threshold value for noise detection is set. The threshold value is a reference for determining that noise is present when noise exceeding this value is detected. The system noise at the time of the initial setting may include a noise band inherent to the CATV broadcasting system Psys, and an initial value of flat noise cannot be obtained for all bands used as uplink. Also, since many CATV transmission line networks 12_m have a certain level of noise just by being connected, it is desirable to set the threshold value for each frequency with a certain margin with respect to the noise initial value.
[0029]
Further, since a signal used for operation (hereinafter, referred to as an “operation signal”) is generated in a band used as an uplink signal, if there is an uplink signal from a user, it is naturally higher than this threshold. High energy states occur. Since correct information from the user is superimposed on this operation signal, it is not appropriate to determine that there is noise even in such a case. Therefore, it is more desirable that the threshold is not set for the band in which the operation signal is generated in advance.
[0030]
FIG. 2 shows the relationship between the output from the signal state detection unit 112 and the threshold set value of the ingress noise determination unit 114. In the figure, the vertical axis represents energy intensity, and the horizontal axis represents frequency. The measurement bandwidth BWm is set to a range that covers at least the uplink band. The initial system noise NSi is a noise state when all the GSWs are turned off. As the threshold value TH, a margin setting amount is set in consideration of a margin with respect to the initial system noise NSi. In FIG. 2, the initial system noise NSi is shown with a certain width because the noise value at a certain frequency always changes.
[0031]
At this time, the initial system noise NSi rarely has a flat characteristic over the entire measurement bandwidth, and high and low noise portions are generated. Therefore, it is called a margin setting band. For the initial system noise NSi, an average value of noise is obtained for each fixed band, and the threshold value in that band is obtained by adding a certain margin to the average value.
[0032]
Therefore, the threshold value TH is not a constant value over the measurement bandwidth BWm, but has a shape having the threshold level difference THs. By doing so, it is possible to uniformly evaluate the presence / absence of ingress noise over the measurement bandwidth BWm while covering the unevenness of the initial system noise NSi.
[0033]
Symbols Mg1, Mg2, and Mg3 each show an example of a margin added when setting the threshold value TH. The symbols Bmg1, Bmg2, and Bmg3 indicate the respective margin setting bands. The system administrator can freely set the margin setting amount and the margin setting band.
[0034]
Although only one operation signal SCr is illustrated in FIG. 2, a plurality of operation signals SCr may actually exist depending on the design of the uplink. Since the band near this operation signal Scr shows a high energy state when an upstream signal is present, it is not appropriate to judge this as ingress noise. Therefore, the non-judgment area Rne is set near the operation signal SCr as the threshold value TH, and the ingress noise judgment is not performed in this band.
[0035]
The actually measured noise is represented by the noise at the time of measurement Nm. The measurement noise Nm has a peak P in the margin setting band Bmg3. Since this peak P exceeds the threshold value TH, it is determined that there is ingress noise. The measurement noise Nm is higher than the initial system noise NSi, but if there is at least one portion in the measurement bandwidth BWm that exceeds the threshold value TH set as described above, it is determined that there is ingress noise. Note that the measurement noise Nm has a width similar to the initial system noise NSi.
[0036]
Returning to FIG. 1, description of the operation of the ingress noise detection system RNT will be continued. The start of the noise detection may be started by a start command of the system administrator, or may be started when the ingress noise determination unit 114 in the control device 110 detects the noise. The time when the ingress noise determination unit 114 detects the noise is when the in-measurement noise Nm exceeds the threshold value TH and the ingress noise is detected, as shown in FIG.
[0037]
The control device 110 that has started the noise detection controls the transmission line network switch 11r to connect the CATV transmission line network 12_m connected to the upstream signal reception device 13 (that is, also connected to the signal state detection unit 112). The blocking / upward band pass is repeated in order to determine the presence or absence of ingress noise. Specifically, the first CATV transmission line network is cut off, and the presence or absence of ingress noise is determined. Alternatively, when it is determined that the ingress noise has disappeared due to the interruption of the first CATV transmission line network, it is determined that the source of the ingress noise is in the first CATV transmission line network 12_1 (m = 1). Then, it is displayed on the display device, and the operation proceeds to the first CATV transmission line network noise investigation. Alternatively, if the noise is not eliminated by the cutoff of the first CATV transmission line network, the first CATV transmission line network is returned to the connected state, and the second CATV transmission line network 12_2 (m = 2) is cut off. The same operation is repeated.
[0038]
The ingress noise detection operation described above will be described in detail with reference to the flowchart shown in FIG. In the CATV broadcasting system Psys, when the occurrence of ingress noise is detected and the noise detection operation of the ingress noise detection system RNT starts, first,
In step S310, measurement of the measurement noise Nm is started. Then, control proceeds to the next step S312.
[0039]
In step S312, an initial value of the variable j is set. This variable j is for counting the number of CATV transmission line networks 12_m connected to the CATV broadcasting system Psys. In the case shown in FIG. 1, j is counted up to n since n CATV transmission line networks 12_1 to 12_n are connected. Then, control proceeds to the next step S314.
[0040]
In step S314, the upstream band-pass cutoff control unit 116 controls the transmission line network switch 11r to cut off the j-th CATV transmission line network. Then, control proceeds to the next step S316.
[0041]
In step S316, the ingress noise determination unit 114 compares the measurement noise Nm output from the signal state detection unit 112 with a preset threshold TH, and determines the ingress noise within the measurement bandwidth BWm. The presence or absence is determined. If it is determined that there is ingress noise, control proceeds to the next step S318.
[0042]
In step S318, it is considered that the CATV transmission line network 12_j is involved in the ingress noise, and the value of the variable j at this time is displayed on the display device 120 and set to the variable Dnn. The variable Dnn indicates 12_j, which is the identifier of the CATV transmission line network for which all GSWs are to be checked later. Then, control proceeds to the next step S320.
[0043]
On the other hand, if it is determined in step S316 that there is no ingress noise, it is determined that the CATV transmission line network 12_j is not involved in the occurrence of ingress noise. Then, the control skips step S318 described above and proceeds to step S320.
[0044]
In step S320, the result of the determination of the presence / absence of the ingress noise is recorded together with the identifier (Dnn) of the CATV transmission line network 12_j as the determination target in the investigation result list 124 held in the storage device 122. Then, control proceeds to the next step S322.
[0045]
In step S322, the cut-off CATV transmission line network 12_j is returned to the state of passing the upstream band. Then, control proceeds to the next step S324.
In S324, it is determined whether j = n. j = n indicates that the CATV transmission network 12_j that is the current ingress noise detection target is the n-th CATV transmission network 12_n, that is, the last CATV transmission network in the CATV transmission network group 12. Is shown. Therefore, when j is not n, the CATV transmission line network group 12 includes the CATV transmission line network 12_j for which the presence / absence of the ingress noise has not yet been determined, and the control proceeds to step S326.
[0046]
In step S326, the variable j is incremented by one. Then, control returns to step S314 described above. Then, after the processing of steps S316 to S322 described above, control proceeds to step S328 only when it is determined in step S324 that j = n.
[0047]
In step S328, it is determined in step S316 that it is related to the ingress noise, and a subroutine is executed to check the total number of GSWs constituting the CATV transmission line network 12_j having the identifier (Dnn) detected in step S318. When this is completed, the entire detection system ends. The processing in the subroutine of step S328 will be described later in detail with reference to FIG.
[0048]
Returning to FIG. 1 again, the operation of the ingress noise detection system RNT will be continuously described. When the CATV transmission line network 12_j that is the cause of noise generation is specified, the CATV transmission line network noise investigation subroutine of step S328 in FIG. 3 is executed. The control device 110 controls the transmission line network switch 11r to cut off and puts the CATV transmission line network 12_j, which is determined to be the source of the ingress noise, into the passing state.
Next, the upstream band pass cutoff control unit 116 sequentially repeats the upstream band pass / block according to the GSW list 126 indicating the connection state of the GSWs on the CATV transmission line network, and the ingress noise determination unit 114 Check for the presence of
[0049]
FIG. 4 shows an example of the GSW list 126. This corresponds to the m-th CATV transmission line network 12_m shown in FIG. Each GSW is assigned a number (which may be an address) that is unique on at least the CATV transmission line network, and whether or not it is a trunk GSW, and whether or not the branch GSW is connected. The number is recorded. Such a list is prepared for all CATV transmission line networks 12_j.
[0050]
In this list, “N” is an abbreviation for Null, and indicates that there is no GSW connected to this GSW. Terminate indicates the end of the trunk line. For example, since the first relay amplifier has the trunk GSW, it is known that the relay amplifier itself is also the trunk GSW, and that the relay amplifier connected to the trunk amplifier is the tenth trunk GSW. Further, the first relay amplifier has a branch line connection, and the respective relay amplifier numbers are 2, 3, 4, and 5.
Since all the relay amplifiers of the corresponding CATV transmission line network are recorded in the GSW list 126, all the GSWs can be checked sequentially according to this list.
[0051]
Returning to FIG. 1, description of the ingress noise detection system RNT will be continued. According to the GSW list 126 indicating the GSW connection state of the relay amplifiers on the CATV transmission network, the individual GSWs of the individual GSWs are basically processed in the same manner as that for specifying the CATV transmission network 12_j having the ingress noise as described above. The presence / absence of noise is checked while passing and blocking the up band repeatedly.
[0052]
Specifically, the GSW of the first relay amplifier is cut off by the upstream bandpass cutoff control unit 116, and the output of the signal state detection unit 112 is judged by the ingress noise judgment unit 114 whether or not there is ingress noise. If the ingress noise determination unit 114 determines that there is no ingress noise, the relay amplifier is considered to be related to the occurrence of ingress noise. A signal indicating that the installation location (main line, branch) and the ingress noise has disappeared is sent. The display control unit 118 causes the display device 120 to display the received signal. Thereafter, the upstream band-pass cutoff control unit 116 returns the GSW to the pass state, then cuts off the GSW of the second-generation relay amplifier, and repeats the same operation.
[0053]
With reference to the flowchart shown in FIG. 5, the details of the subroutine for checking the total number of GSWs constituting the above CATV transmission line network 12_j will be described. The processing of this subroutine is started when Yes in step S324 described above, that is, when the CATV transmission line network 12_j having the ingress noise is specified.
First, in step S512, a variable k is set to an initial value. The variable k is used to count the number of GSWs on the CATV transmission line network 12_j to be examined. Therefore, in this step, k = 1 is set. Then, control proceeds to the next step S513.
[0054]
In step S513, it is determined whether the kth GSW is a branch GSW. If it is a branch GSW, it is determined as Yes and the control proceeds to the next Step S514.
[0055]
In step S514, the branch line is cut off by cutting off the k-th GSW that is the branch GSW. Then, control proceeds to the next step S516.
[0056]
In step S516, the presence or absence of ingress noise is determined in the same manner as in step S316 described above. If Yes, that is, if it is determined that there is ingress noise, the process proceeds to the next step S518.
[0057]
In step S518, the display device 120 is caused to display the number of the relay amplifier and the fact that the branch amplifier has been interrupted. Then, control proceeds to the next step S520.
[0058]
On the other hand, if No in step S516, that is, if there is no ingress noise, the control skips step S518 described above and proceeds to step S520.
[0059]
In step S520, the determination result in step S524 is recorded in the investigation result list 124. Then, control proceeds to the next step S522.
[0060]
In step S522, the branch line cut off in step S514 is returned to the upstream band pass state. Then, control proceeds to the next step S524.
[0061]
In step S524, it is determined whether the k-th GSW is a trunk GSW. This can be checked by referring to the GSW list 126 in FIG. If Yes, that is, if it is the trunk GSW, the control proceeds to the next step S526.
[0062]
In step S526, the k-th GSW, which is the trunk GSW, is shut off, so that the trunk is shut off. Then, control proceeds to the next step S528.
[0063]
In step S528, the presence or absence of ingress noise is determined. If there is ingress noise, control proceeds to the next step S530.
[0064]
In step S530, as in step S518, the display device 120 displays the number of the relay amplifier and the fact that the trunk amplifier has been disconnected. Then, control proceeds to the next step S532. ,
[0065]
On the other hand, if it is determined in step S528 that there is no ingress noise, the control skips step S530 and proceeds to step S532.
[0066]
In step S532, the determination result in step S528 is recorded in the investigation result list 124, as in step S520 described above. Then, control proceeds to the next step S534.
[0067]
In step S534, by passing the kth GSW, which is the trunk GSW, the trunk is passed and the upstream band is returned to the passing state. Then, control proceeds to the next step S536.
[0068]
On the other hand, when it is determined in step S524 that the k-th GSW is not the trunk GSW, the control skips steps S526 to S534 and proceeds to step S536.
[0069]
In step S536, it is determined whether the k-th GSW is the last GSW included in the CATV transmission line network 12_k. If not, control proceeds to step S538.
[0070]
In step S538, the variable k is incremented by 1, and control returns to step S512 described above. Then, the processes in steps S513 to S534 are repeated, and the process in this subroutine ends when it is determined as Yes in step S536.
[0071]
By the operation described above, the display device 120 displays the identifier j of the CATV transmission line network 12_j that eliminates the ingress noise when cut off, the identifier k of the relay amplifier, and the GSW installation location (main line, branch). Therefore, it is possible to specify a path from the terminal GSW that causes the ingress of noise to the upstream signal receiving device 13. Further, since all the survey results are recorded in the survey result list 124, the review of the survey results can be surely performed.
[0072]
FIG. 6 shows a display example of the display device 120 when the 18th GSW in the m-th CATV transmission line network 12_m shown in FIG. 12 is a source of ingress noise. FIG. 7 shows an example of the contents recorded in the survey result list 124 at this time.
[0073]
Note that, in the present embodiment, the signal state detection unit 112, the ingress noise determination unit 114, the upstream bandpass cutoff control unit, and the display control unit 118 installed in the control device 110 are each configured as a separate device or The same function and operation as those of the present invention can be realized by configuring a device combining some of these devices and connecting them by communication means.
[0074]
Further, in the operation shown in the flowchart of FIG. 5, all the GSWs constituting the CATV transmission line network are checked in total, but the GSW list 126 is used from the GSW determined to have no ingress noise to determine the branch line. , The GSW that is the mixing source may be specified.
[0075]
Next, with reference to FIG. 8, the display of the result shown in FIG. 6 will be described in that the path of the upstream ingress noise on the CATV transmission path network is displayed. As illustrated in FIG. 6, even if only the installation location (main line, branch) of the relay amplifier relating to the ingress noise is displayed, the GSW relating to the ingress noise consisting of thousands of GSWs is displayed. It is effective enough. However, if the route of the ingress noise can be displayed in the CATV transmission path network 12_m, an effect is obtained that the system administrator can more intuitively grasp the source of the ingress noise.
[0076]
The route display of the survey result can be displayed based on the survey result list 124 illustrated in FIG. The operation will be briefly described with reference to the flowchart shown in FIG. When the route display subroutine is started according to an instruction from a system administrator or the like, one line of the survey result list 124 shown in FIG. 7 is read in step S912.
[0077]
Then, in step S914, it is determined whether reading of the survey result list 124 has been completed. Since the reading has not been completed at the beginning, it is checked whether or not the ingress noise has been determined in step S916. This can be easily understood by examining the survey result list 124 read in step S912.
[0078]
If it is determined in step S916 that there is an ingress noise, in step S924, it is determined whether the GSW installation location is a trunk or a branch. If it is a trunk line, in step S926, a straight line is drawn from the last displayed portion, and a triangle mark representing the relay amplifier and the number of the relay amplifier are displayed therein. This corresponds to the portion 812 in FIG.
[0079]
If it is not a trunk line, in step S928, an L-shaped broken line is displayed from the last displayed portion, and then a triangular mark representing the relay amplifier and the number of the relay amplifier are displayed therein. This corresponds to the portion 814 in FIG. When the reading is completed, Yes is determined in step S914, and the route display illustrated in FIG. 8 is realized based on the survey result list 124 in step S930.
[0080]
Note that, based on the flowchart shown in FIG. 9, the branch line of the relay amplifier is always displayed by an L-shaped line, but depending on the contents recorded in the GSW list 126, the branch line is displayed on the display screen upward or downward. The display may be distinguished. Specifically, in the example shown in FIG. 11, when the branch line gate 18 is used as the mixing source, as shown in FIG. If it is determined that the ingress noise is mixed, the display is made above the relay amplifier 10.
[0081]
【The invention's effect】
The ingress noise detection system RNT can automatically detect the ingress noise source coming from any of the thousands of GSWs constituting the CATV broadcast system Psys, so that the upstream direction of the CATV broadcast system Psys This is effective in promptly detecting and repairing the service degradation.
[Brief description of the drawings]
FIG. 1 is a diagram showing the overall configuration of a CATV broadcasting system incorporating an ingress noise detection system according to the present invention.
FIG. 2 is a diagram showing a relationship between parameters set by an ingress noise determination unit shown in FIG. 1 and noise in a CATV broadcasting system.
FIG. 3 is a flowchart showing an entire ingress noise detection process by the ingress noise detection system shown in FIG. 1;
FIG. 4 is a diagram showing an example of a GSW list 126 shown in FIG.
FIG. 5 is a flowchart showing details of an operation in a Dnn-th CATV transmission path network investigation subroutine shown in FIG. 3;
6 is a diagram showing a display example on the display device shown in FIG.
FIG. 7 is a diagram showing an example of the contents of a survey result list shown in FIG. 1;
FIG. 8 is a diagram showing a route display example of a survey result.
FIG. 9 is a flowchart showing an operation of drawing a route display of the survey result shown in FIG. 9;
FIG. 10 is a diagram showing a configuration of a conventional CATV broadcasting system.
11 is a diagram showing a configuration of a CATV transmission line network shown in FIG.
FIG. 12 is a diagram illustrating a state of an end transmission path in a CATV broadcast system.
FIG. 13 is a diagram illustrating an uplink frequency use state (Frequency Allocation).
[Explanation of symbols]
Psys, Csys CATV broadcasting system
10 CATV content transmission device
11 Transmission line network connector
11r transmission line network switch
12 CATV transmission network
12_1, 12_2, 12_m, 12_n CATV transmission line network 1
13 Up signal receiver
14 Noise detection device
15 GSW switching device
16 Internet Network
RNT ingress noise detection system
110 control device
112 signal state detector
114 Ingress noise judgment unit
116 Up band pass cutoff control unit
118 Display control unit
120 Display device
122 storage device
124 Survey Result List
126 GSW list
HT CATV terminal
DM monitor
U1, U2, U3, U4, U5 User home
BD1, BD2, BD3, BD4, BD5 Splitter / Distributor

Claims (5)

A CATV transmission network comprising a connection of a relay amplifier having a GSW capable of controlling passing and blocking of an upstream band;
A transmission network switch for switching the CATV transmission network;
A signal state detection unit that detects a signal output from the transmission line network switch,
An ingress noise determination unit that determines the presence or absence of ingress noise from the signal state detected by the signal state detection unit,
A display control unit that outputs a determination result of the ingress noise determination unit,
An ingress noise detection system comprising a CATV transmission line network having the GSW and a control device having a passage cutoff control unit of a transmission line network switch. The CATV transmission line network includes a relay amplifier having a main line GSW provided on a main line and a branch GSW provided on a branch, and a transmission line switch having an upstream band connection switching function of the CATV transmission line network. The ingress noise detection system according to claim 1, wherein: The control device further includes, for each of the CATV transmission line networks, a GSW list in which connection information between GSWs of relay amplifiers configuring the transmission line network is recorded. 3. The ingress noise detection system according to claim 1 or 2, wherein the control unit controls the passage and cutoff of the upstream band of the GSW according to the information in the list. The display control unit includes a device number of a relay amplifier having a built-in GSW and a GSW setting, wherein the ingress noise determination unit determines that there is no ingress noise when the upstream band pass cutoff control unit sets the GSW to the cutoff state. The ingress noise detection system according to any one of claims 1 to 3, wherein a location (main line, branch) is displayed. When the GSW that the ingress noise determination unit determines that there is no ingress noise cuts off the main line, the display control unit draws a mark representing the GSW on the display device following the straight line, and displays a branch line on the display device. The ingress noise detection system according to claim 4, wherein, when interrupted, a mark indicating the GSW is drawn on the display device following the L-shaped line.

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