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- Nachgewiesen in: USPTO Patent Applications
- Sprachen: English
- Document Number: 20200221148
- Publication Date: July 9, 2020
- Appl. No: 16/819048
- Application Filed: March 14, 2020
- Assignees: ARCOM DIGITAL PATENT, LLC (Syracuse, NY, US)
- Claim: 1. An apparatus for enabling synchronous capture of forward and return signals at a remote physical layer (PHY) device for the purpose of detecting common path distortion (CPD), the remote PHY device being coupled between a headend and a coaxial cable plant of a hybrid-fiber coax (HFC) network and providing the forward signal to and receiving the return signal from the coaxial cable plant, the return signal containing an actual CPD signal generated by an interaction between the forward signal and a CPD source in the coaxial cable plant, the forward signal propagating from the remote PHY device to the CPD source and the actual CPD signal propagating from the CPD source to the remote PHY device all within a round-trip interval, the remote PHY device capturing the return signal, from a return channel, over a capture duration of at least the round-trip interval, said apparatus comprising: (a) a coupling element, coupleable to the remote PHY device, for capturing the forward signal from the remote PHY device; (b) a CPD simulator circuit, coupled to said coupling element, for generating from the forward signal a simulated CPD signal having frequencies in the return channel; and (c) a filter, coupled to said CPD simulator circuit, for substantially band-limiting the simulated CPD signal to the return channel, to produce a reference CPD signal, said filter being further coupled to said coupling element to supply the reference CPD signal to the remote PHY device, such that the reference CPD signal is received by the remote PHY device in the return channel, whereby the reference CPD signal is available for use in detecting the actual CPD signal from the captured return signal.
- Claim: 2. The apparatus as recited in claim 1, wherein the return channel is an out-of-band return channel.
- Claim: 3. The apparatus as recited in claim 2, wherein the out-of-band return channel is a narrowband digital return (NDR) channel.
- Claim: 4. The apparatus as recited in claim 1, further comprising a highpass filter, coupled between said coupling element and said CPD simulator circuit, having a passband and a reject band separated by a cutoff frequency, the passband being configured to substantially pass the forward signal to said CPD simulator circuit and the reject band being configured to substantially reject frequencies of the simulated CPD signal lower than the cutoff frequency.
- Claim: 5. The apparatus as recited in claim 4, further comprising an attenuator circuit, coupled between said highpass filter and said CPD simulator circuit, for attenuating the level of the forward signal as it passes to said CPD simulator circuit.
- Claim: 6. The apparatus as recited in claim 1, further comprising a housing containing said coupling element, said CPD simulator circuit, and said filter, said coupling element including a cable connector associated with said housing and configured to physically and electrically connect to a complementary connector associated with the remote PHY device.
- Claim: 7. The apparatus as recited in claim 1, further comprising (d) a pulse modulation circuit, coupled to said filter, for shaping the reference CPD signal into a pulse; and (e) a time delay line, coupled to said pulse modulation circuit, for delaying the pulse-shaped reference CPD signal such that the return signal is captured in the remote PHY device without substantial interference from the received pulse-shaped reference CPD signal.
- Claim: 8. The apparatus as recited in claim 7, wherein said time delay line is configured to delay the pulse-shaped reference CPD signal longer than the round-trip interval.
- Claim: 9. The apparatus as recited in claim 1, further comprising (d) a pulse modulation circuit, coupled to said filter, for shaping the reference CPD signal into a first pulse and shaping a second reference CPD signal produced by said filter into a second pulse; and (e) a phase inverter circuit, coupled to said pulse modulation circuit, for shifting the phase of the second pulse by about 180 degrees, whereby interference caused by an autocorrelation of the first pulse, in detecting the actual CPD signal, is substantially cancelable by interference caused by an autocorrelation of the second pulse.
- Claim: 10. The apparatus as recited in claim 1, wherein the reference CPD signal, as received by the remote PHY device, has a signal level in a range of about 0 dB to about 5 dB relative to an expected maximum level of the actual CPD signal contained in the captured return signal.
- Claim: 11. A method of enabling synchronous capture of forward and return signals at a remote physical layer (PHY) device for the purpose of detecting common path distortion (CPD), the remote PHY device being coupled between a headend and a coaxial cable plant of a hybrid-fiber coax (HFC) network and providing the forward signal to and receiving the return signal from the coaxial cable plant, the return signal containing an actual CPD signal generated by an interaction between the forward signal and a CPD source in the coaxial cable plant, the forward signal propagating from the remote PHY device to the CPD source and the actual CPD signal propagating from the CPD source to the remote PHY device all within a round-trip interval, said method comprising the steps of: (a) capturing the forward signal from an output associated with the remote PHY device; (b) generating from the forward signal captured in step (a) a simulated CPD signal having frequencies in a return channel; (c) substantially band-limiting the simulated CPD signal to the return channel, to produce a reference CPD signal; (d) supplying the reference CPD signal to the remote PHY device; (e) in the remote PHY device, receiving the reference CPD signal in the return channel; and (f) in the remote PHY device, capturing the return signal from the return channel over a capture duration of at least the round-trip interval, whereby the reference CPD signal is available for use in detecting the actual CPD signal from the captured return signal.
- Claim: 12. The method as recited in claim 11, further comprising the step of: (g) detecting the actual CPD signal from the captured return signal using the reference CPD signal.
- Claim: 13. The method as recited in claim 11, wherein step (d) includes supplying the reference CPD signal to the remote PHY device via the output associated with the remote PHY device.
- Claim: 14. The method as recited in claim 11, further comprising the steps of: (g) transmitting the reference CPD signal and the captured return signal from the remote PHY device to the headend of the HFC network; (h) at the headend or a device communicating with the headend, performing a cross-correlation of the reference CPD signal and the captured return signal, to produce a correlation peak associated with the actual CPD signal; and (i) detecting the actual CPD signal from the correlation peak.
- Claim: 15. The method as recited in claim 14, wherein the reference CPD signal and the captured return signal are processed as a combined signal, and wherein step (h) includes performing an autocorrelation of the combined signal to obtain the cross-correlation of the reference CPD signal and the captured return signal.
- Claim: 16. The method as recited in claim 15, wherein the autocorrelation of the combined signal includes an autocorrelation of the reference CPD signal, and wherein step (h) further includes substantially subtracting the autocorrelation of the reference CPD signal from the autocorrelation of the combined signal.
- Claim: 17. The method as recited in claim 15, wherein the combined signal has a duration of about 100 milliseconds or greater; and wherein step (h) includes performing the autocorrelation of the combined signal substantially over the duration of the combined signal.
- Claim: 18. The method as recited in claim 11, further comprising the steps of: (g) performing a cross-correlation of the reference CPD signal and the captured return signal, to produce a correlation peak associated with the actual CPD signal; and (h) detecting the actual CPD signal from the correlation peak.
- Claim: 19. The method as recited in claim 11, wherein the reference CPD signal and the captured return signal are processed as a combined signal, said method further comprising the steps of (g) performing a first combined autocorrelation of the combined signal, which includes a first reference autocorrelation of the reference CPD signal and a first cross-correlation of the reference CPD signal and the captured return signal; (h) repeating steps (a), (b), and (c) to generate a second reference CPD signal; (i) shifting the phase of the second reference CPD signal by about 180 degrees; (j) repeating steps (d) through (e) with respect to the phase-shifted second reference CPD signal, and repeating step (f) to capture a second return signal, the phase-shifted second reference CPD signal and the second return signal being processed as a second combined signal; (k) performing a second combined autocorrelation of the second combined signal, which includes a second reference autocorrelation of the second reference CPD signal and a second cross-correlation of the second reference CPD signal and the second return signal; (l) subtracting the second combined autocorrelation from the first combined autocorrelation, such that the first and the second reference autocorrelations substantially cancel each other out, and the first and the second cross-correlations substantially add together to produce an accumulated cross-correlation function having a correlation peak; and (m) detecting the actual CPD signal from the correlation peak.
- Claim: 20. The method as recited in claim 19, wherein step (c) includes shaping the reference CPD signal into a pulse, and wherein step (h) includes shaping the second reference CPD signal into a pulse.
- Claim: 21. The method as recited in claim 11, further comprising the steps of (g) shaping the reference CPD signal into a pulse; and (h) delaying the pulse-shaped reference CPD signal such that the return signal is captured in step (f) without substantial interference from the pulse-shaped reference CPD signal.
- Claim: 22. The method as recited in claim 21 wherein step (h) includes delaying the pulse-shaped reference CPD signal longer than the round-trip interval.
- Claim: 23. The method as recited in claim 11, wherein the return channel has a noise floor, and wherein step (e) includes receiving the reference CPD signal in the remote PHY device at a level of about 10 dB to about 20 dB above the noise floor.
- Current International Class: 04; 04; 04
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