Resistive temperature sensors for improved asperity, head-media spacing, and/or head-media contact detection

1 - 25 . (canceled) 26 . An apparatus, comprising: a plurality of head transducers configured to interact with magnetic recording media; a plurality of sensors having a temperature of coefficient of resistance, wherein at least one sensor is provided on each head transducer and is responsive to changes in spacing between the sensor and the media; and a power source configured to supply bias power to each sensor of each head transducer and to adjust the bias power to maintain each sensor at a fixed temperature above an ambient temperature in the presence of heat transfer changes impacting the sensors. 27 . The apparatus of claim 26 , wherein the fixed temperature is a temperature above an ambient temperature. 28 . The apparatus of claim 26 , further comprising: a heater provided at each of the head transducers and configured to actuate the head transducers; wherein the power source is configured to adjust the bias power to maintain each sensor at the fixed temperature in the presence of heat transfer changes impacting the sensors including those due to power supplied to the heater. 29 . The apparatus of claim 26 , wherein maintaining each sensor at the fixed temperature eliminates transducer-to-transducer variance in detection signals produced by the plurality of sensors. 30 . The apparatus of claim 26 , wherein the at least one sensor is provided at a close point of each head transducer. 31 . The apparatus of claim 26 , further comprising a detector configured to detect one or both of an asperity of the recording media and head-to-media contact in response to detection signals produced by the plurality of sensors. 32 . An apparatus, comprising: a plurality of head transducers configured to interact with magnetic recording media; a plurality of sensors having a temperature of coefficient of resistance, wherein at least one sensor is provided on each head transducer and is responsive to changes in spacing between the sensor and the media; and a power source configured to supply bias power to each sensor of each head transducer and to adjust the bias power to maintain a fixed overheat ratio (OHR) across all sensors in the presence of heat transfer changes impacting the sensors. 33 . The apparatus of claim 32 , wherein the fixed OHR is fixed at different values for different radii of the media. 34 . The apparatus of claim 32 , wherein the fixed OHR is fixed at different values as a function of time for sensors having a response that decays with time. 35 . The apparatus of claim 32 , further comprising: a heater provided at each of the head transducers and configured to actuate the head transducers; wherein the power source is configured to adjust the bias power to maintain each sensor at the fixed OHR in the presence of heat transfer changes impacting the sensors including those due to power supplied to the heater. 36 . The apparatus of claim 32 , wherein maintaining each sensor at the fixed OHR eliminates transducer-to-transducer variance in detection signals produced by the plurality of sensors. 37 . The apparatus of claim 32 , wherein the at least one sensor is provided at a close point of each head transducer. 38 . The apparatus of claim 37 , further comprising a detector configured to detect one or both of an asperity of the recording media and head-to-media contact in response to detection signals produced by the plurality of sensors. 39 . A method, comprising: with magnetic recording media moving relative to a plurality of head transducers: sensing for changes in spacing between the head transducers and the media using sensors having a temperature of coefficient of resistance; supplying bias power to the sensors; and adjusting the bias power to maintain each sensor at a fixed temperature above an ambient temperature in the presence of heat transfer changes impacting the sensors. 40 . The method of claim 39 , further comprising: thermally actuating the head transducers to cause the head transducers to move toward the media; and adjusting the bias power to maintain each sensor at the fixed temperature in the presence of heat transfer changes impacting the sensors including those due to thermally actuating the head transducers. 41 . The method of claim 39 , further comprising detecting one or both of an asperity of the recording media and head-to-media contact in response to detection signals produced by the plurality of sensors. 42 . A method, comprising: with magnetic recording media moving relative to a plurality of head transducers: sensing for changes in spacing between the head transducers and the media using sensors having a temperature of coefficient of resistance; supplying bias power to the sensors; and adjusting the bias power to maintain each sensor at a fixed overheat ratio (OHR) in the presence of heat transfer changes impacting the sensors. 43 . The method of claim 42 , further comprising: thermally actuating the head transducers to cause the head transducers to move toward the media; and adjusting the bias power to maintain each sensor at the fixed OHR in the presence of heat transfer changes impacting the sensors including those due to thermally actuating the head transducers. 44 . The method of claim 42 , further comprising: measuring a cold or ambient resistance, R 0 , of each sensor; increasing the bias power supplied to each sensor while measuring changes in hot resistance, R W , of each sensor; calculating OHR using the measured cold and hot sensor resistances, R 0 and R W ; and adjusting the bias power to maintain each sensor at the calculated OHR. 45 . The method of claim 42 , further comprising detecting one or both of an asperity of the recording media and head-to-media contact in response to detection signals produced by the plurality of sensors. 46 . An apparatus, comprising: a head transducer configured to interact with a magnetic recording medium having a plurality of tracks; and a sensor having a temperature coefficient of resistance and arranged at the head transducer so that a longitudinal axis of the sensor is oriented substantially parallel relative to the tracks, the sensor responsive to one or both of asperities of the medium and changes in spacing between the sensor and the medium.