Method and system associated with a sensing roll and a mating roll for collecting data including first and second sensor arrays

The invention claimed is: 1. A system associated with a sensing roll and a mating roll for collecting roll data comprising: a first array of sensors located at axially spaced-apart locations of the sensing roll, wherein each sensor of the first array enters a region of a nip between the sensing roll and the mating roll during each rotation of the sensing roll to generate a first respective sensor signal; a second array of sensors located at axially spaced-apart locations of the mating roll, wherein each sensor of the second array enters a region of the nip between the sensing roll and the mating roll during each rotation of the mating roll to generate a second respective sensor signal, a periodically occurring first time reference associated with each rotation of the mating roll; a periodically occurring second time reference associated with each rotation of the sensing roll and a processor to receive a received sensor signal, the received sensor signal comprising one of the first respective sensor signal and the second respective sensor signal, and, upon receiving the received sensor signal, the processor operates to: determine a particular one of the sensors of the first array or second array which generated the received sensor signal, when the particular one sensor is from the first array, then based upon a first amount of time that has elapsed since a most recent first time reference, determine a detected tracking segment based on which one of a plurality of first tracking segments associated with the mating roll enters the region of the nip substantially concurrently with the particular one sensor from the first array, when the particular one sensor is from the second array, then based upon a second amount of time that has elapsed since a most recent second time reference, determine a detected tracking segment based on which one of a plurality of second tracking segments associated with the sensing roll enters the region of the nip substantially concurrently with the particular one sensor from the second array; and store the received sensor signal using the detected tracking segment. 2. The system of claim 1 , wherein each of the plurality of first tracking segments are of substantially equal size and each of the plurality of second tracking segments are of substantially equal size. 3. The system of claim 1 , wherein the received sensor signal comprises a pressure value. 4. The system of claim 1 , wherein the processor receives: the first respective sensor signal for each of the sensors of the first array during each rotation of the sensing roll, the second respective sensor signal for each of the sensors of the second array during each rotation of the mating roll; and a plurality of sensor signals comprising: a plurality of first respective sensor signals occurring during a plurality of rotations of the sensing roll, and a plurality of second respective sensor signals occurring during a plurality of rotations of the mating roll. 5. The system of claim 4 , wherein, for each one of the plurality of sensor signals, the processor identifies: its detected tracking segment, an associated axial segment, and whether said particular one of the plurality of sensor signals is generated from the first array of sensors or from the second array of sensors. 6. The system of claim 5 , wherein: the mating roll and the sensing roll each, respectively, comprises n axial segments, having respective index values: 1, 2, . . . , n; the mating roll and the sensing roll each, respectively has associated therewith, m tracking segments, having respective index values: 1, 2, . . . , m, and wherein, for the first array of sensors, there are (n times m) unique permutations, respectively, that are identifiable by a two-element first set comprising a respective first axial segment index value and a respective first tracking segment index value and for the second array of sensors, there are (n times m) unique permutations, respectively, that are identifiable by a two-element second set comprising a respective second axial segment index value and a respective second tracking segment index value. 7. The system of claim 6 , wherein, for the plurality of first respective sensor signals and for a first plurality of the possible (n times m) permutations, the processor determines an average of all the plurality of respective first sensor signals associated with a mating roll axial segment and first tracking segment matching each of the first plurality of permutations, and for the plurality of second respective sensor signals and for a second plurality of the possible (n times m) permutations, the processor determines an average of all the plurality of respective second sensor signals associated with a sensing roll axial segment and detected second tracking segment matching each of the second plurality of permutations. 8. The system of claim 6 , wherein, for the plurality of first respective sensor signals and each of a first plurality of the possible (n times m) permutations, the processor determines: a number of times one or more of the plurality of first respective sensor signals are associated with a mating roll axial segment and first tracking segment matching that permutation; and a summation of all of the plurality of first respective sensor signals associated with the mating roll axial segment and first tracking segment matching that permutation, and for the plurality of second respective sensor signals and each of a second plurality of the possible (n times m) permutations, the processor determines: a number of times one or more of the plurality of second respective sensor signals are associated with a sensing roll axial segment and second tracking segment matching that permutation; and a summation of all of the plurality of second respective sensor signals associated with the sensing roll axial segment and second tracking segment matching that permutation. 9. The system of claim 1 , wherein: the plurality of first tracking segments associated with the mating roll comprise one of: a plurality of circumferential segments on the mating roll, and a plurality of time segments of a period of the mating roll, and the plurality of second tracking segments associated with the sensing roll comprise one of: a plurality of circumferential segments on the sensing roll, and a plurality of time segments of a period of the sensing roll. 10. The system of claim 6 , wherein: a respective average pressure value is associated with each of the (n times m) unique permutations of each of the first and second sets, each of the respective average pressure values based on previously collected pressure readings related to the nip. 11. The system of claim 10 , wherein: a first respective column average value is associated with each first axial segment index value, each first respective column average value comprising an average of the m respective average pressure values, from the first set, associated with that first axial segment index value, and a second respective column average value is associated with each second axial segment index value, each second respective column average value comprising an average of the m respective average pressure values, from the second set, associated with that second axial segment index value. 12. The system of claim 11 , wherein the processor operates to: for each one of the received sensor signals which defines a pressure reading: determine a particular first or second axial segment index value and a particular first or second tracking segment index value based on that signal's associated axial segment, its detected tracking segment, a