Contact patch measurements during hydroplaning events

What is claimed is: 1. A method of analyzing a contact patch of a tire during a hydroplaning event, comprising: obtaining a piezoelectric sensor output signal from at least one piezoelectric sensor mounted in a tire, the piezoelectric sensor output signal being generated at least in part during a hydroplaning event; analyzing, with one or more processing devices, the piezoelectric sensor output signal to determine a contact patch entry and a contact patch exit for the tire; detecting, with the one or more processing devices, a signal perturbation in the piezoelectric sensor output signal, the signal perturbation corresponding to the hydroplaning event and occurring at a time between a time associated with the contact patch entry and a time associated with the contact patch exit; and assessing a quantitative degree of hydroplaning for the tire during the hydroplaning event based at least in part on the signal perturbation, wherein the quantitative degree of hydroplaning indicates how much of the contact patch was separated from a static surface by a fluid during the hydroplaning event. 2. The method of claim 1 , wherein the contact patch entry is determined by identifying a maximum slope in a first direction of the piezoelectric sensor output signal and the contact patch exit is determined by identifying a maximum slope in a second direction of the piezoelectric sensor output signal. 3. The method of claim 1 , wherein detecting, with the one or more processing devices, a signal perturbation in the piezoelectric sensor output signal comprises analyzing, with one or more processing devices, the piezoelectric sensor output signal to identify an inflection point in the piezoelectric sensor output signal occurring between the contact patch entry and the contact patch exit. 4. The method of claim 1 , wherein detecting, with the one or more processing devices, a signal perturbation in the piezoelectric sensor output signal comprises analyzing, with the one or more processing devices, the piezoelectric sensor output signal to identify a first inflection point in the piezoelectric sensor output signal and a second inflection point in the piezoelectric sensor output signal, the first inflection point and the second inflection point occurring between the contact patch entry and the contact patch exit. 5. The method of claim 4 , wherein the signal perturbation is detected based at least in part on the first inflection point and the second inflection point. 6. The method of claim 5 , wherein the time associated with the signal perturbation is determined as an average of a time associated with the first inflection point and a time associated with the second inflection point. 7. The method of claim 1 , wherein the quantitative degree of hydroplaning is determined as follows: H = t event - t cpentry t cpexit - t cpentry where H is the quantitative degree of hydroplaning, t event is a time associated with the signal perturbation, t cpentry is a time associated with the contact patch entry, t cpexit is a time associated with the contact patch exit. 8. The method of claim 1 , wherein the method comprises detecting the hydroplaning event based at least in part on a rate of change of the piezoelectric sensor output signal at the contact patch entry. 9. The method of claim 1 , wherein obtaining a piezoelectric sensor output signal comprises obtaining a plurality of piezoelectric sensor output signals, each piezoelectric output sensor signal generated from one of a plurality of piezoelectric sensors mounted in the tire. 10. The method of claim 9 , wherein the plurality of piezoelectric sensors are mounted across a lateral width of the tire. 11. The method of claim 9 , wherein detecting, with the one or more processing devices, a signal perturbation corresponding to the hydroplaning event in the piezoelectric sensor output signal comprises detecting a plurality of signal perturbations, each signal perturbation associated with one of the plurality of piezoelectric sensor output signals. 12. The method of claim 11 , wherein assessing a parameter indicative of a deformation of the contact patch related to the hydroplaning event based at least in part on the signal perturbation comprises determining one or more parameters indicative of a shape of the contact patch based at least in part on the plurality of signal perturbations. 13. A system for analyzing a contact patch of a tire during a hydroplaning event, comprising: at least one piezoelectric sensor configured to generate a piezoelectric sensor output signal representative of a time varying curvature of a tire during tire rotation; one or more processing devices, the one or more processing devices configured to execute computer-readable instructions stored in one or more computer readable media that when executed by the one or more processing devices cause the one or more processing devices to perform operations comprising: obtaining a piezoelectric sensor output signal from at least one piezoelectric sensor mounted in a tire, the piezoelectric sensor output signal being generated at least in part during a hydroplaning event; analyzing, with one or more processing devices, the piezoelectric sensor output signal to determine a contact patch entry and a contact patch exit for the tire; detecting, with the one or more processing devices, a signal perturbation corresponding to the hydroplaning event in the piezoelectric sensor output signal, the signal perturbation occurring at a time between a time associated with the contact patch entry and a time associated with the contact patch exit; and assessing a quantitative degree of hydroplaning for the tire during the hydroplaning event based at least in part on the signal perturbation, wherein the quantitative degree of hydroplaning indicates how much of the contact patch was separated from a static surface by a fluid during the hydroplaning event.