Network traffic-compatible time domain reflectometer

US 9,960,842 B2
Filed: 10/03/2016
Issued: 05/01/2018
Est. Priority Date: 10/12/2015
Status: Active Grant

First Claim

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1. A time domain reflectometer for locating an impairment in a coaxial cable portion of a hybrid fiber-coax (HFC) network, the coaxial cable portion being characterized by a velocity of propagation and carrying a plurality of burst signals in an upstream frequency band during a plurality of burst intervals, respectively, said time domain reflectometer comprising:

(a) a transmitter, to be coupled to the HFC network at a distance from the impairment, for transmitting over the distance to the impairment a plurality of low-level probe signals in the upstream frequency band during a plurality of receiving intervals, respectively, the impairment causing a reflection of the plurality of probe signals in the form of a plurality of reflected probe signals, which travel back over the distance towards said transmitter;

(b) a receiver, to be coupled to the HFC network, for receiving the plurality of reflected probe signals during the plurality of receiving intervals, respectively, and for receiving the plurality of burst signals during a number of the plurality of receiving intervals that overlap in time with the plurality of burst intervals;

(c) a level detector, coupled to said receiver, for measuring a level of the signal or signals received by said receiver during each of the receiving intervals, such that a plurality of level measurements are made for the plurality of receiving intervals, respectively;

(d) a controller, coupled to said level detector, for determining which of the plurality of receiving intervals are substantially free of the burst signals based on the plurality of level measurements;

(e) an accumulator, coupled to said receiver and to said controller, for accumulating substantially only the reflected probe signals received during the receiving intervals that have been determined to be substantially free of the burst signals; and

(f) an impairment detector, coupled to said accumulator, for detecting the impairment from the accumulated reflected probe signals and estimating from the detection a time delay between the transmission of the probe signals by said transmitter and the reception of the reflected probe signals by said receiver,whereby a value of the distance to the impairment is estimated from the time delay and the velocity of propagation of the coaxial cable portion of the HFC network.

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Abstract

A TDR for locating impairments in an HFC network is claimed. The network carries burst signals in an upstream band during burst intervals. The TDR comprises a transmitter, receiver, level detector, controller, accumulator, and probe detector. The transmitter transmits probe signals to the impairment, causing a reflection of the probe signals. Each probe signal is in the upstream band and has a bandwidth extending the width of the upstream band. The receiver receives the reflected probe signals during receiving intervals, and receives the burst signals during receiving intervals that overlap burst intervals. The level detector measures a level of the signals received during each receiving interval. The controller determines which of the receiving intervals are free of burst signals, based on the level measurement. The accumulator accumulates reflected probe signals received during intervals free of burst signals. The probe detector detects the impairment from the accumulated probe signals and estimates a time delay for the impairment. A distance to the impairment is estimated from the time delay.

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29 Claims

1. A time domain reflectometer for locating an impairment in a coaxial cable portion of a hybrid fiber-coax (HFC) network, the coaxial cable portion being characterized by a velocity of propagation and carrying a plurality of burst signals in an upstream frequency band during a plurality of burst intervals, respectively, said time domain reflectometer comprising:
- (a) a transmitter, to be coupled to the HFC network at a distance from the impairment, for transmitting over the distance to the impairment a plurality of low-level probe signals in the upstream frequency band during a plurality of receiving intervals, respectively, the impairment causing a reflection of the plurality of probe signals in the form of a plurality of reflected probe signals, which travel back over the distance towards said transmitter;
  
  (b) a receiver, to be coupled to the HFC network, for receiving the plurality of reflected probe signals during the plurality of receiving intervals, respectively, and for receiving the plurality of burst signals during a number of the plurality of receiving intervals that overlap in time with the plurality of burst intervals;
  
  (c) a level detector, coupled to said receiver, for measuring a level of the signal or signals received by said receiver during each of the receiving intervals, such that a plurality of level measurements are made for the plurality of receiving intervals, respectively;
  
  (d) a controller, coupled to said level detector, for determining which of the plurality of receiving intervals are substantially free of the burst signals based on the plurality of level measurements;
  
  (e) an accumulator, coupled to said receiver and to said controller, for accumulating substantially only the reflected probe signals received during the receiving intervals that have been determined to be substantially free of the burst signals; and
  
  (f) an impairment detector, coupled to said accumulator, for detecting the impairment from the accumulated reflected probe signals and estimating from the detection a time delay between the transmission of the probe signals by said transmitter and the reception of the reflected probe signals by said receiver,whereby a value of the distance to the impairment is estimated from the time delay and the velocity of propagation of the coaxial cable portion of the HFC network.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15)
- - 2. The time domain reflectometer of claim 1, wherein each of the plurality of low-level probe signals has a band of frequencies extending substantially over the width of the upstream frequency band.
  - 3. The time domain reflectometer of claim 2, wherein the plurality of low-level probe signals are a plurality of chirp pulses, respectively, the reflection of the plurality of low-level probe signals being in the form of a plurality of reflected chirp pulses.
  - 4. The time domain reflectometer of claim 3, wherein the upstream frequency band is from about 5 MHz to about 42 MHz, and wherein each of the plurality of chirp pulses is defined by a band of frequencies from about 5 MHz to about 42 MHz.
  - 5. The time domain reflectometer of claim 3, wherein each of the plurality of chirp pulses is an up-chirp pulse.
  - 6. The time domain reflectometer of claim 3, wherein each of the plurality of chirp pulses is defined by a pulse duration, and wherein the pulse duration of each chirp pulse is in a range of about 7 microseconds to about 12 microseconds.
  - 7. The time domain reflectometer of claim 1, wherein the plurality of receiving intervals together span a total time period of at least one second.
  - 8. The time domain reflectometer of claim 1, wherein each of the plurality of receiving intervals is in a range of about 10 microseconds to about 15 microseconds.
  - 9. The time domain reflectometer of claim 1, wherein the impairment is a linear impairment.
  - 10. The time domain reflectometer of claim 1, wherein said controller is adapted to determine which of the plurality of receiving intervals are substantially free of the burst signals based on a comparison of the level measurements made for the receiving intervals with a predetermined threshold.
  - 11. The time domain reflectometer of claim 10, wherein said level detector is adapted to measure a level of an initial number of burst signals, carried by the coaxial cable portion of the HFC network in the upstream frequency band, to determine the predetermined threshold.
  - 12. The time domain reflectometer of claim 1, wherein the coaxial cable portion of the HFC network includes a bi-directional amplifier located upstream of the impairment, the bi-directional amplifier having an upstream leg, the upstream leg having a return amplifier, an input tap at an input of the return amplifier, and an output tap at an output of the return amplifier, the input tap having an input test port and the output tap having an output test port,and wherein said transmitter is to be coupled to the input test port of the input tap and said receiver is to be coupled to the output test port of the output tap, such that, once coupled, said transmitter transmits the plurality of probe signals through the input tap to the impairment and said receiver receives the plurality of reflected probe signals from the output tap.
  - 13. The time domain reflectometer of claim 1, wherein said impairment detector is adapted to produce an output response from the accumulated reflected probe signals, the output response having an amplitude peak from which the impairment is detected.
  - 14. The time domain reflectometer of claim 13, wherein said controller is coupled to said impairment detector and is adapted to determine a return loss value of the impairment from the amplitude peak of the output response.
  - 15. The time domain reflectometer of claim 1, wherein said impairment detector includes a matched filter configured to detect the impairment from the accumulated reflected probe pulses.

16. A method of locating an impairment in a coaxial cable portion of a hybrid fiber-coax (HFC) network, the coaxial cable portion being characterized by a velocity of propagation and carrying a plurality of burst signals in an upstream frequency band during a plurality of burst intervals, respectively, said method comprising the steps of:
- (a) transmitting in the coaxial cable portion of the HFC network, over a distance to the impairment, a plurality of low-level probe signals in the upstream frequency band during a plurality of receiving intervals, respectively, the impairment causing a reflection of the plurality of probe signals in the form of a plurality of reflected probe signals, which travel back over the distance;
  
  (b) receiving the plurality of reflected probe signals during the plurality of receiving intervals, respectively, and receiving the plurality of burst signals during a number of the plurality of receiving intervals that overlap in time with the plurality of burst intervals;
  
  (c) measuring a level of the signal or signals received in step (b) during each of the receiving intervals, such that a plurality of level measurements are made for the plurality of receiving intervals, respectively;
  
  (d) determining which of the plurality of receiving intervals are substantially free of the burst signals based on the plurality of level measurements;
  
  (e) accumulating substantially only the reflected probe signals received during the receiving intervals that have been determined to be substantially free of the burst signals;
  
  (f) detecting the impairment from the accumulated reflected probe signals and estimating from the detection a time delay between the transmission of the probe signals in step (a) and the reception of the reflected probe signals in step (b); and
  
  (g) estimating a value of the distance to the impairment from the time delay and the velocity of propagation of the coaxial cable portion of the HFC network.
- View Dependent Claims (17, 18, 19, 20, 21, 22, 23, 24, 25, 26)
- - 17. The method of claim 16, wherein the coaxial cable portion of the HFC network contains first and second test ports located upstream from the impairment, and wherein:
    - step (a) includes transmitting the plurality of low-level probe signals through the first test port at a probe signal transmit level; and
      
      step (b) includes receiving the plurality of reflected probe signals and the burst signals through the second test port.
  - 18. The method of claim 17, wherein the coaxial cable portion of the HFC network operates using a frequency spectrum including the upstream frequency band and a guard band, and wherein the first test port leaks a portion of the plurality of low-level probe signals transmitted in step (a) to create a corresponding plurality of leak probe signals, the leak probe signals substantially interfering with reception of the burst signals, upstream of the first and the second test ports, unless a level of the leak probe signals is less than a level of the burst signals by at least a predetermined threshold, the method of claim 16 further comprising the steps of:
    - (h) through the first test port, transmitting a narrowband test signal at a test level into the coaxial cable portion of the HFC network, the test signal being located in the guard band to substantially avoid interference with the burst signals in the upstream frequency band, the first test port leaking a portion of the test signal to create a leak test signal;
      
      (i) through the second test port, receiving the leak test signal and the burst signals from the coaxial cable portion of the HFC network;
      
      (j) measuring a level of the leak test signal and a level of the burst signals received in step (i), to produce a leak test level and a burst signal level, respectively;
      
      (k) determining whether a condition is met that the leak test level is less than the burst signal level by at least the predetermined threshold;
      
      (l) if the condition in step (k) is not met, adjusting the test level in step (h) and repeating steps (h) through (k) until the condition in step (k) is met; and
      
      (m) if the condition in step (k) is met, adjusting the probe signal transmit level in step (a) based on the test level that resulted in the condition being met,whereby interference by the leak probe signals with reception of the burst signals upstream of the first and the second test ports is substantially avoided.
  - 19. The method of claim 16, wherein step (d) is performed by comparing each of the level measurements with a predetermined threshold, and if a particular level measurement of the level measurements is below the predetermined threshold, it is determined that the receiving interval associated with the particular level measurement is substantially free of the burst signals.
  - 20. The method of claim 19, further comprising the steps of:
    - (h) receiving, in the upstream frequency band, an initial number of burst signals from the coaxial cable portion of the HFC network; and
      
      (i) measuring a level of the initial number of burst signals to determine the predetermined threshold.
  - 21. The method of claim 16, wherein step (f) includes producing an output response from the accumulated reflected probe signals, the output response having an amplitude peak from which the impairment is detected.
  - 22. The method of claim 21, further comprising the step of determining a return loss value of the impairment from the amplitude peak of the output response.
  - 23. The method of claim 16, wherein each of the plurality of low-level probe signals has a band of frequencies extending substantially over the width of the upstream frequency band.
  - 24. The method of claim 23, wherein the plurality of low-level probe signals are a plurality of chirp pulses, respectively, the reflection of the plurality of low-level probe signals being in the form of a plurality of reflected chirp pulses.
  - 25. The method of claim 24, wherein each of the plurality of chirp pulses is defined by a pulse duration, and wherein the pulse duration of each chirp pulse is in a range of about 7 microseconds to about 12 microseconds.
  - 26. The method of claim 16, wherein each of the plurality of receiving intervals is in a range of about 10 microseconds to about 15 microseconds.

27. A method of locating an impairment in a coaxial cable portion of a hybrid fiber-coax (HFC) network, the coaxial cable portion being characterized by a velocity of propagation and carrying a plurality of burst signals in an upstream frequency band during a plurality of burst intervals, respectively, said method comprising the steps of:
- (a) generating a plurality of low-level probe pulses, each with a bandwidth that extends substantially over the entire upstream frequency band and that is substantially limited to the upstream frequency band;
  
  (b) transmitting in the coaxial cable portion of the HFC network, over a distance to the impairment, the plurality of low-level probe pulses during a plurality of receiving intervals, respectively, the impairment causing a reflection of the plurality of probe pulses in the form of a plurality of reflected probe pulses, which travel back over the distance;
  
  (c) receiving the plurality of reflected probe pulses during the plurality of receiving intervals, respectively, and receiving the plurality of burst signals during a number of the receiving intervals that overlap in time with the plurality of burst intervals;
  
  (d) measuring a signal level of what is received in step (c) during each of the receiving intervals, such that a plurality of signal level measurements is made for the plurality of receiving intervals, respectively;
  
  (e) determining which of the plurality of receiving intervals are substantially free of the burst signals based on the plurality of signal level measurements;
  
  (f) accumulating substantially only the reflected probe pulses received during the receiving intervals that have been determined to be substantially free of the burst signals;
  
  (g) detecting the impairment by processing the accumulated reflected probe pulses in a matched filter that is configured for the probe pulses;
  
  (h) estimating, from the detection in step (g), a time delay between the transmission of the plurality of probe pulses and the reception of the plurality of reflected probe pulses, respectively; and
  
  (i) estimating a value of the distance to the impairment from the time delay and the velocity of propagation of the coaxial cable portion of the HFC network.
- View Dependent Claims (28, 29)
- - 28. The method of claim 27, wherein step (e) includes comparing each of the plurality of signal level measurements to a predetermined threshold.
  - 29. The method of claim 28, wherein each of the plurality of low-level probe pulses is a chirp pulse.

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Current Assignee
Arcom Digital Patent, LLC
Original Assignee
Arcom Digital, LLC
Inventors
Zinevich, Victor M.
Primary Examiner(s)
Phan, Hanh

Application Number

US15/283,510
Publication Number

US 20170104522A1
Time in Patent Office

575 Days
Field of Search

398 16, 398 21, 398 33, 398 34, 398 38, 398 10, 398 13, 398 17, 398 20, 398 24, 398 25, 398 30, 398 31, 398 72, 398 66, 398 68, 398 71, 398100, 398 67, 398 69, 398 70, 356 731, 725121, 725124, 725125, 725127, 725129
US Class Current
CPC Class Codes

H04B 10/071   using a reflected signal, e...

H04B 10/0771   Fault location on the trans...

H04B 10/0793   Network aspects, e.g. centr...

H04B 10/25751   Optical arrangements for CA...

H04J 14/08   Time-division multiplex sys...

H04L 5/0048   Allocation of pilot signals...

Network traffic-compatible time domain reflectometer

First Claim

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Abstract

72 Citations

29 Claims

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Network traffic-compatible time domain reflectometer

First Claim

2 Assignments

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Abstract

72 Citations

29 Claims

Specification

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