Corrosion monitor

What is claimed is: 1 . A corrosion detection system for detecting corrosion on a chassis of a device, comprising: a memory configured to store reference data; a corrosion monitor comprising: a printed circuit board; a corrosion sensor coupled to the printed circuit board, the corrosion sensor comprising a first input and a second input, the corrosion sensor configured to output a signal proportional to a resistance of the chassis of the device; a first standoff coupled between the printed circuit board and the chassis of the device; a second standoff coupled between the printed circuit board and the chassis of the device; a third standoff coupled between the printed circuit board and the chassis of the device; a fourth standoff coupled between the printed circuit board and the chassis of the device; a constant current circuit coupled to the first standoff and configured to output a constant current; a first trace coupled between the third standoff and the first input of the corrosion sensor; and a second trace coupled between the fourth standoff and the second input of the corrosion sensor, wherein the corrosion sensor is configured to output the signal proportional to the resistance of the chassis of the device based upon a voltage induced by the constant current circuit at the first input and the second input; and a processor communicatively coupled to the memory and the corrosion monitor, the processor configured to receive the signal proportional to the resistance of the chassis of the device from the corrosion monitor and determine a corrosion level of the chassis of the device by comparing the signal proportional to the resistance of the chassis from the corrosion monitor to the reference data stored in the memory. 2 . The corrosion detection system of claim 1 , further comprising: a passive near field communication circuit galvanically coupled to the memory, the corrosion monitor and the processor, the passive near field communication circuit configured to power the memory, the corrosion monitor and the processor when the passive near field communication circuit is exposed to a radio frequency field by an active near field communication system. 3 . The corrosion detection system of claim 2 , wherein the passive near field communication circuit is further configured to transmit the determined corrosion level to the active near field communication system. 4 . The corrosion detection system of claim 1 , further comprising: a radio frequency identification communication circuit galvanically coupled to the memory, the corrosion monitor and the processor, the radio frequency identification communication circuit configured to power the memory, the corrosion monitor and the processor when the radio frequency identification communication circuit is exposed to a radio frequency field by an active radio frequency identification communication system. 5 . The corrosion detection system of claim 4 , wherein the radio frequency identification communication circuit is further configured to transmit the determined corrosion level to the active near field communication system. 6 . The corrosion detection system of claim 1 , wherein the reference data is a reference voltage. 7 . The corrosion detection system of claim 1 , further comprising a current regulator coupled between the second standoff and the processor. 8 . A method for detecting corrosion on a chassis of a device, comprising: receiving, by a constant current source mounted on a printed circuit board, a power supply; outputting, by the constant current source, a substantially constant current to a first standoff, the first standoff separating the printed circuit board from the chassis; receiving, by a corrosion sensor mounted on the printed circuit board, a first input voltage from a second standoff, the second standoff separating the printed circuit board from the chassis; receiving, by the corrosion sensor, a second input voltage from a third standoff, the third standoff separating the printed circuit board from the chassis; outputting, by the corrosion sensor, a signal proportional to a resistance of the chassis based upon the first input voltage and the second input voltage to a processor mounted on the printed circuit board; and determining, by the processor, a corrosion level of the chassis by comparing the signal proportional to the resistance of the chassis to reference data stored in a memory communicatively coupled to the processor. 9 . The method of claim 8 , further comprising transmitting, by a passive near field communication circuit, the power supply to the constant current source when the passive near field communication circuit is exposed to a radio frequency field by an active near field communication system. 10 . The method of claim 9 , further comprising transmitting, by the passive near field communication circuit, the determined corrosion level to the active near field communication system. 11 . The method of claim 8 , further comprising transmitting, by a radio frequency identification communication circuit, the power supply to the constant current source when the radio frequency identification communication circuit is exposed to a radio frequency field by an active radio frequency identification communication system. 12 . The method of claim 11 , further comprising transmitting, by the radio frequency identification communication circuit, the determined corrosion level to the active radio frequency identification communication system. 13 . The method of claim 8 , wherein the reference data is a reference voltage. 14 . A corrosion detection system for an electronics assembly comprising: a metal chassis configured to support an electronics device; a corrosion monitor including: an insulated substrate; a plurality of standoffs extending between the insulated substrate and the metal chassis; a constant current circuit supported on the insulated substrate and electrically coupled to a first standoff for outputting a constant current to the metal chassis; a corrosion sensor supported on the insulated substrate and having a first input electrically coupled to a second standoff, a second input electrically coupled to a third standoff, and an output configured to output a signal proportional to a resistance of the metal chassis based upon a voltage induced by the constant current circuit at the first input and the second input; and a processor in communication with the corrosion monitor and configured to receive the signal proportional to the resistance of the chassis of the device from the corrosion monitor, determine a corrosion level of the chassis of the device by comparing the signal proportional to the resistance of the chassis from the corrosion monitor to the reference data stored in a memory associated with the processor, and output a signal based on the corrosion level. 15 . The corrosion detection system of claim 14 further comprising a power/ground source galvanically coupled to the corrosion monitor and the processor for selectively powering the corrosion monitor and the processor when a corrosion detection query is initiated. 16 . The corrosion detection system of claim 15 further comprising a current regulator operably coupled between the power/ground source and at least one of the processor and a fourth standoff. 17 . The corrosion detection system of claim 15 wherein the power/ground source further comprises a near field circuit configured to power the corrosion monitor and the processor when the near field circuit is exposed t