Environmental sensor system and signal processor

Having thus described various embodiments of the invention, what is claimed as new and desired to be protected by Letters Patent includes the following: 1. A sensor system comprising: a first sensor configured to sense an environmental parameter and output a first electronic signal with a response to the environmental parameter, the response having a first time constant; a second sensor configured to sense the environmental parameter and output a second electronic signal with a response to the environmental parameter, the response having a second time constant greater than the first time constant; a high pass filter having a first filter time constant roughly equal to the second time constant, the high pass filter receiving the first electronic signal and outputting a filtered first electronic signal in which changes in a level or value of the first electronic signal with transition times that are less than the first filter time constant are passed, while first electronic signal changes with transition times greater than the first filter time constant are cut off or attenuated; and a summation unit receiving the filtered first electronic signal and the second electronic signal and outputting a third electronic signal which is the sum of the filtered first electronic signal and the second electronic signal. 2. The sensor system of claim 1 , further comprising a first scaler receiving the filtered first electronic signal and outputting a filtered, scaled first electronic signal whose levels or values are adjusted to correspond to those of the environmental parameter, and a second scaler receiving the second electronic signal and outputting a scaled second electronic signal whose levels or values are adjusted to correspond to those of the environmental parameter, wherein the summation unit receives the filtered, scaled first electronic signal and the scaled second electronic signal and outputs the third electronic signal being the sum of the filtered, scaled first electronic signal and the scaled second electronic signal. 3. The sensor system of claim 2 , wherein the first and second scalers each include a multiplier electronically coupled to an adder, wherein the scaled output electronic signal is a sum of an offset value and a product of an input electronic signal and a proportionality constant. 4. The sensor system of claim 2 , further comprising a low pass filter having a second filter time constant roughly equal to the second time constant, the low pass filter receiving the second electronic signal and outputting a filtered second electronic signal in which changes in a level or value of the second electronic signal with transition times that are greater than the second filter time constant are passed, while second electronic signal changes with transition times less than the second filter time constant are cut off or attenuated, wherein the second scaler receives the filtered second electronic signal. 5. The sensor system of claim 1 , wherein the first sensor includes a thin-film printed transducer and the second sensor includes a transducer having a bulk sensing area. 6. The sensor system of claim 1 , wherein the high pass filter includes a discrete time filter in which the first electronic signal is filtered with an exponential function that varies according to a sampling rate of the first electronic signal and the second time constant. 7. The sensor system of claim 6 , wherein the exponential function is e −sn , wherein n is the sample number and s is equivalent to one divided by a product of the sampling rate of the first electronic signal and the second time constant. 8. A method of processing signals from environmental sensors, the method comprising the steps of: receiving a first electronic signal from a first environmental sensor with a response having a first time constant, the first environmental sensor sensing an environmental parameter; receiving a second electronic signal from a second environmental sensor with a response having a second time constant greater than the first time constant, the second environmental sensor sensing the environmental parameter; high pass filtering the first electronic signal with a first filter time constant is roughly equal to the second time constant, the high pass filtering producing a filtered first electronic signal; and adding the filtered first electronic signal and the second electronic signal. 9. The method of claim 8 , further comprising the steps of scaling the filtered first electronic signal and the second electronic signal such that the levels or values of each signal are adjusted to correspond to those of the environmental parameter, the scaling producing a filtered, scaled first electronic signal and a scaled second electronic signal, and adding the filtered, scaled first electronic signal and the scaled second electronic signal. 10. The method of claim 9 , wherein the scaling includes multiplying an input electronic signal by a proportionality constant and adding the product to an offset value. 11. The method of claim 8 , wherein the high pass filtering further includes passing changes in a level or value of the first electronic signal with transition times that are less than the filter time constant and cutting off or attenuating first electronic signal changes with transition times greater than the filter time constant. 12. The method of claim 8 , further comprising the steps of low pass filtering the second electronic signal with a second filter time constant is roughly equal to the second time constant, the low pass filtering producing a filtered second electronic signal, and adding the filtered first electronic signal and the second electronic signal. 13. The method of claim 12 , wherein the low pass filtering further includes passing changes in a level or value of the second electronic signal with transition times that are greater than the second filter time constant and cutting off or attenuating second electronic signal changes with transition times less than the second filter time constant. 14. The method of claim 8 , wherein the high pass filtering further includes sampling the first electronic signal during a plurality of time periods to create a stream of first electronic signal samples, one first electronic signal sample per time period, subtracting a current time period first electronic signal sample from a next time period first electronic signal sample to create a first electronic signal sample difference for each time period, and generating a current time period filtered first electronic signal sample by multiplying a previous time period filtered first electronic signal sample by an exponential function and adding the product to the first electronic signal sample difference for each time period. 15. The method of claim 14 , wherein the exponential function is e −sn , wherein n is the sample number and s is equivalent to one divided by a product of the sampling rate of the first electronic signal and the second time constant. 16. The method of claim 8 , further comprising the steps of transforming the first electronic signal and the second electronic signal to the frequency domain to produce a frequency domain first electronic signal and a frequency domain second electronic signal, high pass filtering the first electronic signal with the first filter time constant to produce a frequency domain filtered first electronic signal, scaling the frequency domain filtered first electronic signal and the frequency domain second electronic signal to produce a frequency domain scaled, filtered first electronic sig