초록 ▼

A pair of identical humidity sensors (S1) and (S2) are in the same environment, so that they identically react to humidity effects; a sensing circuit includes an operational amplifier (10), its input (15) receiving from the first sensor (Si) a signal changing with humidity according to a logarithmic

A pair of identical humidity sensors (S1) and (S2) are in the same environment, so that they identically react to humidity effects; a sensing circuit includes an operational amplifier (10), its input (15) receiving from the first sensor (Si) a signal changing with humidity according to a logarithmic law, while the second sensor (S2), inserted in the amplifier feedback, reacts to humidity changes in the same way as the first sensor (Si) and consistently modifies the gain. The output signal (V0) is compensated, and has a substantially linear progression with humidity.

대표청구항 ▼

The invention claimed is: 1. A physical quantity detection device, including a sensor, sensitive to said physical quantity and exposed thereto, and an amplifier, connected to the output of said sensor with a first input and having a second reference input, characterized in that it comprises a secon

The invention claimed is: 1. A physical quantity detection device, including a sensor, sensitive to said physical quantity and exposed thereto, and an amplifier, connected to the output of said sensor with a first input and having a second reference input, characterized in that it comprises a second sensor, sensitive to said physical quantity and exposed thereto, connected to the amplifier output and connected also to said reference input. 2. A detection device, according to claim 1, characterized in that said amplifier is an operational amplifier, wherein said first sensor is connected between a noninverting input and a source of a reference voltage, and wherein said second sensor is arranged in the feedback line of said amplifier, being connected between said output and an inverting input of said amplifier. 3. A detection device, according to claim 1, characterized in that said first and second sensors are made with the same sensitive material. 4. A detection device, according to claim 3, characterized in that the curves representing the resistance change of said first sensor and of said second sensor as a function of the physical quantity to be detected have the same sign of the first derivative and second derivative. 5. A detection device, according to claim 4, characterized in that said particular physical quantity is the relative humidity present in the environment where said sensors are arranged. 6. A detection device, according to claim 2, characterized in that it further comprises a resistance connected in parallel to said first sensor, to limit the resistance applied to said first input, when said first sensor has a very high resistance at low humidity values. 7. A detection device, according to claim 2, characterized in that it comprises a second resistance connected in series to said second sensor and a third resistance connected in parallel to both said second sensor and said second resistance, to limit the minimum and maximum gain of said amplifier, respectively, when said second sensor is plunged in an environment with very high or very low humidity, respectively. 8. A detection device, according to claim 6, characterized in that said first sensor is connected between a generator of driving signals and said reference voltage generator, said driving signals activating said first sensor to generate said response signal, variable as humidity changes. 9. A detection device, according to claim 8, characterized in that said driving signals are comprised of a direct voltage, referred to said reference voltage. 10. A detection device, according to claim 8, characterized in that said driving signals are comprised of at least two homopolar square waves, having a predetermined duration. 11. A detection device, according to claim 8, characterized in that said driving signals are comprised of at least two square waves of opposed polarity, and having a null average value, coinciding with said reference voltage. 12. A detection device, according to claim 10, characterized in that said at least two square waves have the same amplitude. 13. A detection device, according to claim 9, characterized in that said driving signals are referred to said reference voltage. 14. A detection device, according to one of the preceding claims, characterized in that each of said sensors includes a double array of electric conductors separated from one another, deposited on an insulating support and respectively connected to said pair of electric terminals, said electric conductors being covered with a layer of a material sensitive to one of said particular physical quantities, and with a permeable layer laid upon said sensitive layer. 15. A detection device, according to claim 14, characterized in that said particular physical quantity is the relative humidity present in the environment where said sensors are arranged. 16. Method for detecting physical quantities, providing the following steps: a) driving a first sensor of a physical quantity with a predetermined driving signal in order to obtain a first output signal, function of the physical quantity; b) amplifying the first output signal and obtaining an amplified signal in response to said first output signal; c) driving a second sensor, arranged in the same environment as the first sensor, with a driving signal comprised of the amplified signal and obtaining a second output signal; d) continuously adjusting the amplification gain of said first signal as an inverse function of the value of said second output signal. 17. A method for detecting physical quantities according to claim 16, characterized in that the curves representing the resistance change of said first sensor and of said second sensor as a function of the physical quantity to be detected have the same sign of first derivative and second derivative. 18. A method for detecting physical quantities according to claim 16, characterized in that the said amplification step is carried out in a variable gain amplifier, having a noninverting input, and step b) includes applying said first output signal to said noninverting input. 19. A method for detecting physical quantities according to claim 16, characterized in that said amplification step is carried out in a variable gain amplifier, having an inverting input, and step d) includes: applying said second output signal to said inverting input. 20. A method for detecting, according to claim 16, further comprising: e) converting said output signal into digital form and sending it to an electronic processor to carry out a linearity correction as a function of the temperature changes of said sensors based on predetermined data.