BE1012674A6 - Method for the tracking of interruptions on signals of a subscriber to adistributor in a cable distribution network - Google Patents

Abstract

The current invention pertains to a method for discovering cable errors in acable distribution network, characterized by the fact that the methodcontains the following steps: The connection of a fixed receiver for signalswith a frequency between 5 and 48 MHz to the cable network. Transmitting witha mobile transmitter of a signal with a frequency between 5 and 48 MHz with aadjustable capacity from a mobile unit. The conversion of the strength of thereceived signal into an indicator signal, whereby the indicator signal isrelative to the strength of the signal, and the localization of the cableerror by bringing the transmitter as close to the cable error as possible,and whereby the distance of the sender to the cable error is determined basedon the indicator signal.<IMAGE>

Description

       

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   METHOD FOR DETECTING INGRESS ON SIGNALS FROM
SUBSCRIPTION TO DISTRIBUTOR OF A CABLE DISTRIBUTION NETWORK Object of the invention
The object of the invention is a method for detecting ingress on signals from subscriber to distributor in a cable distribution network.



  State of the art
A cable distribution network is mainly constructed with coaxial cables, amplifiers and taps. This whole is connected to each other by means of connectors.



  The net is partly laid underground and above ground. A cable network 'lives', which means that it is subject to varying factors such as weather, urbanization, aging of materials, etc. under various circumstances. As a result, in the long term connections will oxidize or cables will be damaged by contractors. etc ....



   As a result, signal will come out at certain places in the cable network. These signals can interfere with other frequencies (such as the police, the police, police, etc.). Larger signal loss can lead to reflections (ghost images) or problems with teletext, Nicam etc ...



   In the past, frequenries were only used on the way from 48 MHz to 450 MHz (in some

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 areas up to 800 MHz) - for signals from antenna station to the subscriber (so-called Broadcast network).



   With the arrival of Telenet, the signals must now also return from the subscriber to the antenna station to enable two-way communication, which means that the networks must be converted for two-way traffic. To make this way back possible, the frequencies below 48 MHz are used. (currently from 5 to 25 MHz). All kinds of side effects, which were not bothering the cable companies in the past, are now emerging. In this low band, mainly between 5 and 15 MHz, there is contamination of the spectrum, caused by household appliances, computers, video recorders, TV sets, electronic power controls, etc. In this frequency band there are also all kinds of transmission frequencies in the air.

   Because the accumulation of all these signals now returns upstream to the antenna station, it is obvious that it is now difficult to distinguish the useful signals from the disturbances.



   In the first instance, it is possible to place a blocking filter with each subscriber that stops this low band. This is an emergency solution, because as soon as a customer wishes to connect to Telenet, this filter must be removed.



   It must therefore be ensured that the interior installation of the customer is optimally arranged. Self-installed connections that do not conform to the regulations of the cable company must be removed. Poor connection cables between the TV junction box and the TV set / video recorder must be replaced by approved types that offer sufficient protection against strange external signals. The outside connection (on the facade or in a footpath cupboard)

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 must be thoroughly checked. Loose-fitting connectors must be screwed in, and if they show oxidation they must be replaced. Visually one can already detect many errors.

   However, if a cable break occurs, or if you are dealing with errors that cannot be detected immediately (eg underground cables, etc.), you must rely on measuring equipment. A reflectometer can in some cases locate an error, but in the case of an error where water has penetrated the cable, this measurement method is unreliable.



   From experience it is known that a 'leak' on the cable network radiates signals, but also lets in strange signals (the so-called ingress). Based on that principle, a device was developed that offers the possibility of detecting such errors.



  Object of the invention
The object of the present invention is to develop an ingress detection method that can be used without interrupting the continuity of the network and for which only one technician is required.



  Main features of the invention
A first main feature of the present invention is a method for detecting cable faults in a cable distribution network, characterized in that the method comprises the following steps: o Connecting a fixed receiver for signals with frequency between 5 and 48 MHz to the cable network, * The transmitting to a mobile transmitter a signal with a frequency between 5 and 48 MHz with a controllable power from a mobile unit, * Converting the strength of the signal from the receiver

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 received signal in an indicator signal, the indicator signal being relative to the strength of the signal, and Locating the cable error by bringing the transmitter as close as possible to the cable error,

   wherein the distance from the transmitter to the cable fault is determined on the basis of the indicator signal.



   Preferably the indicator signal is sent from the fixed receiver to the mobile unit, most preferably d. m. for a 150 MHz transmitter and is received in the mobile unit with a 150 MHz receiver.



   Preferably, the indicator signal is a whistle, the pitch being relative to the distance from the transmitter to the cable error.



   The indicator signal can also be a pulsed signal with a pulse frequency between 0 and 20 KHz, the pulse frequency being relative to the distance from the transmitter to the cable fault.



   The indicator signal can be converted into a visual signal in the mobile unit.



   The mobile channel is preferably a 27 MHz channel.



   A further main feature of the present invention is a method for detecting cable faults in a cable distribution network, characterized in that the method comprises the following steps: * Connecting a fixed transmitter for signals with frequency between 50 and 800 MHz to the cable network, * The transmitting with the fixed transmitter a signal modulated with a first indicator signal around a fixed frequency, * Receiving the signal emitted from a cable error with a first indicator signal modulated signal having

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 a suitable receiver, and * converting the strength of the signal received by the receiver into a second indicator signal, the second indicator signal being relative to the strength of the signal,

   and locating the cable fault by bringing the receiver as close as possible to the cable fault, the distance from the receiver to the cable fault being determined on the basis of the second indicator signal.



   The fixed frequency is preferably 150 MHz.



   Preferably, the second indicator signal is a whistle, the pitch being relative to the distance from the transmitter to the cable error.



   The second indicator signal can also be a pulsed signal with a pulse frequency between 0 and 20 KHz, the pulse frequency being relative to the distance from the transmitter to the cable fault.



   The second indicator signal can be converted into a visual signal in the mobile unit.



  Detailed description of the invention
The present invention relates to a method for detecting ingress that can be used without interrupting the continuity of the network and for which only one technician is required.



   The present invention will be described with reference to figures and examples, which are not restrictive of the scope of the patent.

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  Brief description of the figures
Figure 1 describes the principle of the method according to a specific embodiment of the present invention.



   Figure 2 describes the measurement arrangement according to a specific embodiment of the present invention.



  Example: use of 27 and 150 MHz frequencies for detecting ingress according to the method of the present invention.



   The technician is equipped with a mobile 'irradiation station' (1), with which he drives along the cable network (3). On the way, or in an optical node, he places a fixed installation (5) that can receive a signal via the return route. It transmits with the mobile unit (7) a signal of 27 MHz from the irradiating station (1) which is power adjustable.



   If it comes into the vicinity of a break or an infiltration site (9) on the cable network, then this 27 MHz penetrates the cable network and goes upstream towards the antenna station (11). (In a node (eg 13) the 27 MHz standard is blocked by a filter, so that it cannot end up in the antenna station (11)).



   The fixed installation (5) does receive that signal and measures its strength. Depending on this strength (which is an indication of the magnitude of the leak and the distance of the transmitter / cable fault), an audible signal is generated that is proportional to the strength of the received signal. (With a weakly received signal: low tone - this tone increases in height as the received signal becomes stronger, and is therefore an indication of the location of the signal). To convert the strength of the signal to

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 the audible signal uses a VCO (15).



   The audible signal is now sent back to the mobile unit via a 2 meter band (150 MHz) transmitter (TX) (17) and made audible via a decoder (19) and via a loudspeaker through which the feedback is realized.



   So the technician drives around until he hears a whistle. If this tone increases in height, it is approaching an error. If the pitch decreases again, then it has passed the error.



   By manipulating the power of the transmitter, he can locate errors more accurately, or detect errors that he cannot easily reach with the car.



   Once the error is located, the technician can start the repair and immediately hear "online" if the error disappears.



   The transmission frequency of 27 MHz should be retained because of the blocking filter in the nodes.



  Other frequencies would end up in the antenna station through which optical receivers could be transmitted.



   An overview of the installation used is visible in Figure 2. The mobile unit 7 contains a transmitter with a frequency of 27 MHz (21), connected to a suitable antenna (23) (a 27 MHz transmission antenna). Furthermore, the mobile unit includes a 150 MHz receiver (25) connected to a suitable antenna (27) (150 MHz receiving antenna). The signal received via the 150 MHz receiver is converted into a visual and / or auditory signal via a decoder. The visual signal can be made visible on a display (29). Such a display can improve the strength of the signal in different ways

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 view. For example, the display can consist of an electromagnetic voltmeter (as shown), an LED indicator system or a digital readout.

   The auditory signal is made audible via a loudspeaker (31), possibly with the aid of a suitable amplifier (not shown). The mobile unit can be powered m. B. v. the car battery (12 V DC).



   The fixed unit (5) is connected to the cable network via a connection point (33), along which the 27 MHz signal from the cable network and a cable error from the 27 MHz transmitter (21) is routed to a 27 MHz receiver (35) . The signal is converted via a VCO into a measurement signal modulated to the strength of the received 27 MHz signal, which signal is transmitted via a 150 MHz transmitter (37) and a suitable antenna (39) (150 MHz transmitting antenna) to the receiver (25) of the mobile unit (7) can be sent. The fixed unit (5) is preferably supplied via the mains supply.



  The abbreviations used in the figures represent: TP: Test point TX: Transmitter (transmitter) RX: Receiver (receiver) OTX: Optical Transmitter (Optical transmitter) ORX: Optical receiver (Optical receiver) VCO: Voltage Controlled Oscillator DPX: Demultiplexer ATT: Attenuator (attenuator)
Another possibility for the feedback, instead of a 2 meter airborne transmitter / receiver, is a whistle modulated frequency around 150 MHz directly in the way of the node on the cable. At the location of the defect, this frequency will be

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 blasted outside. With the help of the already available 'Sniffer' measuring devices, one can now receive that signal and read the signal strength from it.



   This method therefore follows a reverse path compared to what was described above.


    

Claims (12)

 CONCLUSIONS Method for detecting cable faults in a cable distribution network, characterized in that the method comprises the following steps: Connecting a fixed receiver for signals with frequencies between 5 and 48 MHz to the cable network, * Broadcasting a signal with a mobile transmitter with a frequency between 5 and 48 MHz with a controllable power from a mobile unit, * Converting the strength of the signal received by the receiver into an indicator signal, the indicator signal being relative to the strength of the signal, and Locating the cable fault by bringing the transmitter as close as possible to the cable fault, whereby the distance from the transmitter to the cable fault is determined on the basis of the indicator signal.  A method as in claim 1, wherein the indicator signal is sent from the fixed receiver to the mobile unit.  Method as in claim 2, characterized in that the indicator signal is sent d. m. for a 150 MHz transmitter and is received in the mobile unit with a 150 MHz receiver.  Method as in any one of claims 1 to 3, characterized in that the indicator signal is a whistle, the pitch being relative to the distance from the transmitter to the cable error.  A method as claimed in any one of claims 1 to 3, characterized in that the indicator signal is a pulsed signal with a pulse frequency between 0 and 20 KHz, the pulse frequency being relative to the distance of the transmitter from the cable fault.  <Desc / Clms Page number 11>    Method as in any one of claims 1 to 5, characterized in that the indicator signal in the mobile unit is converted into a visual signal.  Method as in any one of claims 1 to 6, characterized in that the mobile transmitter is a 27 MHz transmitter  EMI11.1  is.  Method for detecting cable faults in a cable distribution network, characterized in that the method comprises the following steps: * Connecting a fixed transmitter for signals with a frequency between 50 and 800 MHz to the cable network, * Transmitting with the fixed transmitter of a cable signal with a first indicator signal modulated around a fixed frequency, * Receiving the signal emitted from a cable error with a first indicator signal with a suitable receiver, and converting the strength of the signal received by the receiver into a second indicator signal, wherein the second indicator signal is relative to the strength of the signal, and * locating the cable fault by bringing the receiver as close as possible to the cable fault,  wherein the distance from the receiver to the cable fault is determined on the basis of the second indicator signal.  Method as in claim 8, characterized in that the fixed frequency is 150 MHz.  A method as claimed in any one of claims 8 or 9, characterized in that the second indicator signal is a whistle, the pitch being relative to the distance from the receiver to the cable error.  A method as in any one of claims 8 or 9, characterized in that the second indicator signal is a  <Desc / Clms Page number 12>  is a pulsed signal with a pulse frequency between 0 and 20 KHz, the pulse frequency being relative to the distance from the receiver to the cable fault.  Method as in any of claims 8 to 11, characterized in that the second indicator signal is converted into a visual signal.