Instruments and methods of detecting intermittent noise in a cable network system

The invention claimed is: 1. A test instrument for locating intermittent noise in a cable network system, the test instrument comprising: a port configured to be coupled to a node of the cable network system; and a controller electrically connected to the port, the controller being configured to access data on the cable network system via the port, the controller being configured to: collect signal data from the cable network system; generate a plurality of signal traces based on the collected signal data; isolate a number of signal traces in the plurality of signal traces based on a carrier reference profile and an upper boundary of a background noise floor of a predetermined frequency range; generate an output signal based on the number of isolated signal traces; and determine, based on the output signal, whether intermittent noise is present. 2. The test instrument of claim 1 , the controller being further configured to: generate a histogram of signal amplitudes based on the collected signal data; separate the predetermined frequency range into a plurality of frequency bins, said each frequency bin including a portion of the predetermined frequency range; identify, for said each frequency bin, a minimum peak signal amplitude having a highest probability in the histogram; follow a slope of bars of the histogram from the identified minimum peak signal amplitude to a minimum signal amplitude for said each frequency bin; and identify the minimum signal amplitudes for the frequency bins as the upper boundary of the background noise floor for the predetermined frequency range. 3. The test instrument of claim 1 , the controller being further configured to: compare a plurality of signal amplitudes in each signal trace of the plurality of signal traces to the upper boundary of the background noise floor; calculate a plurality of average signal amplitudes across the predetermined frequency range based on the signal traces having signal amplitudes above the upper boundary of the background noise floor; and identify the plurality of average signal amplitudes as the carrier reference profile. 4. The test instrument of claim 1 , the controller being configured to isolate the number of signal traces in the plurality of signal by: cross-correlating each signal trace of the plurality of signal traces with the carrier reference profile; comparing each cross-correlation to a predetermined threshold; and identifying said each signal trace as including a carrier when the cross-correlation associated exceeds the predetermined threshold. 5. The test instrument of claim 4 , the controller being configured to isolate the number of signal traces in the plurality of signal traces by identifying a plurality of signal amplitudes present in the plurality of signal traces that are less than the upper boundary of the background noise floor. 6. The test instrument of claim 1 , the controller being configured to collect the signal data from the cable network system by: identifying at least one time period in which no carriers are present in an upstream band; and collecting, at the node, the signal data from the cable network system during the at least one identified time period. 7. The test instrument of claim 1 , the controller being configured to collect signal data from the cable network system by: locating configuration messages related to an upstream band in signal data received from the cable network system; identifying at least one time period in which no carriers are present in the upstream band based on at least one configuration message; and collecting the signal data from the cable network system during at least one identified time period. 8. The test instrument of claim 7 , the controller being configured to collect signal data from the cable network system by: requesting an extended modem register period from the cable network system; and collecting signal data from the cable network system during the extended modem register period. 9. The test instrument of claim 1 , further comprising a display operable to visually indicate intermittent noise present at the node. 10. The test instrument of claim 9 , the controller being further configured to operate the display to provide a visual indication of a location of the intermittent noise. 11. The test instrument of claim 9 , the controller being configured to operate the display to provide a first visual indicator when the location of the intermittent noise is downstream from the node and to provide a second visual indicator when the location of the intermittent noise is upstream from the node. 12. The test instrument of claim 1 , the controller being further configured to: identify an upper boundary of a background noise floor in the collected signal data across a predetermined frequency range of the cable network system; and isolate the number of signal traces in the plurality of signal traces based on the upper boundary of the background noise floor. 13. A cable network test instrument comprising: a port configured to be coupled to a node of a cable network system, and a controller electrically connected to the port and being configured to communicate with the cable network system via the port, the controller including circuitry configured to: request an extended modem register period from the cable network system; collect signal data from the cable network system during the extended modem register period; and analyze the collected data to determine whether intermittent noise is present at the node. 14. The cable network test instrument of claim 13 , wherein the port comprises a wireless transceiver operable to communicate wirelessly with the node of the cable network system. 15. The cable network test instrument of claim 13 , wherein the controller further comprises circuitry configured to: identify an upper boundary of a background noise floor in the collected signal data across a predetermined frequency range of the cable network system; generate a plurality of signal traces based on the collected signal data; isolate a number of signal traces in the plurality of signal traces based on the upper boundary of the background noise floor; and identify the intermittent noise present at the node based on the number of isolated signal traces. 16. The test instrument of claim 15 , the controller further comprising circuitry configured to: generate a histogram of signal amplitudes based on the collected signal data; separate the predetermined frequency range into a plurality of frequency bins, said each frequency bin including a portion of the predetermined frequency range; identify, for said each frequency bin, a minimum peak signal amplitude having a highest probability in the histogram; follow a slope of bars of the histogram from the identified minimum peak signal amplitude to a minimum signal amplitude for said each frequency bin; and identify the minimum signal amplitudes for the frequency bins as the upper boundary of the background noise floor for the predetermined frequency range. 17. The test instrument of claim 15 , the controller further comprising circuitry configured to: compare a plurality of signal amplitudes in each signal trace of the plurality of signal traces to the upper boundary of the background noise floor; calculate a plurality of average signal amplitudes across the predetermined frequency range based on the signal traces having signal amplitudes above the upper boundary of the background noise floor; and identify the plurality of average signal amplitudes as