Temperature detection circuitry is selectively coupled to a thermistor and one of two sources representing the impedance at respective ends of the expected range of temperature to which the thermistor is to be exposed. The offset of an amplifier and a scale factor to account for gain set of the ampl
Temperature detection circuitry is selectively coupled to a thermistor and one of two sources representing the impedance at respective ends of the expected range of temperature to which the thermistor is to be exposed. The offset of an amplifier and a scale factor to account for gain set of the amplifier are determined in an automatic calibration process while coupled to the source(s), and thereafter temperature readings are taken from the thermistor. During the calibration process, if the gain or scale factor are outside of expected ranges, a failure is determined and an alarm given and/or a heater is disabled.
대표청구항▼
1. An automatically calibrating thermistor circuit comprising: a port coupleable to a thermistor exposed to a heated location over which a range of temperatures is expected, and configured to obtain a temperature reading representative of a temperature of said heated location;a first source, the fir
1. An automatically calibrating thermistor circuit comprising: a port coupleable to a thermistor exposed to a heated location over which a range of temperatures is expected, and configured to obtain a temperature reading representative of a temperature of said heated location;a first source, the first source providing a temperature reading associated with one end of said expected range of temperatures; anddetection circuitry having an input selectively coupleable to the port and the first source and having an output, the detection circuitry including an amplifier coupled to the input and having a generally preset gain and a variable offset, the variable offset being set in response to an adjustable offset signal coupled thereto, and an A/D converter coupled to the amplifier and the output by which to provide a digital temperature signal correlated to a temperature reading at the input, the amplifier outputting amplified temperature reading signals across an expected operating range in relation to said expected temperature range of said heated location, the amplifier outputting a minimum value in response to the first source; anda processor coupled to the detection circuitry output, the processor selectively causing the first source to be coupled to the input of the detection circuitry in a calibration mode and the port to be coupled to the input of the detection circuitry in a normal operation mode, in the calibration mode the processor determining the adjustable offset signal based on the digital temperature signals obtained from the first source, the adjustable offset signal being operatively coupled to the variable offset of the amplifier such that the variable offset of the amplifier is set in response to the adjustable offset signal from the processor so that the variable offset of the amplifier is based on digital temperature signals obtained from the first source whereby to obtain the temperature reading representative of said temperature of said heated location in the normal operation mode. 2. The automatically calibrating thermistor circuit of claim 1, the first source being a precision resistor having an impedance associated with a high end of said expected temperature range. 3. The automatically calibrating thermistor circuit of claim 1 further comprising a multiplexer responsive to the processor to selectively couple the port or the first source to the detection circuitry. 4. The automatically calibrating thermistor circuit of claim 1 further comprising a D/A converter coupling the offset signal from the processor to the amplifier. 5. The automatically calibrating thermistor circuit of claim 1, the processor further iteratively adjusting the offset signal until the digital temperature signal from the detection circuitry correlates to an expected digital signal. 6. The automatically calibrating thermistor circuit of claim 5, the processor further iteratively outputting as an offset signal an average of upper and lower boundary values and varying the boundary values in relation to the digital temperature signal from the detection circuitry until the boundary values satisfy a predetermined criterion. 7. The automatically calibrating thermistor circuit of claim 1, the processor further indicating failure in response to determining an offset signal that is outside of an acceptable range. 8. The automatically calibrating thermistor circuit of claim 1 further comprising a second source providing a temperature reading related to a second temperature associated with another end of said expected range of temperatures to cause the amplifier to output a maximum value, the detection circuitry input further selectively coupleable to the second source, the processor further selectively causing one of the first source and the second source to be coupled to the input of the detection circuitry in the calibration mode, the processor determining a scale factor based on a relationship between the digital temperature signal obtained from the second source and a desired maximum output of the amplifier, the processor adjusting the digital temperature signals obtained from the port in relation to the scale factor in the normal operation mode. 9. The automatically calibrating thermistor circuit of claim 8, the second source being a precision resistor having an impedance associated with a low end of said expected temperature range. 10. The automatically calibrating thermistor circuit of claim 8 further comprising a multiplexer responsive to the processor to selectively couple the port, the first source, or the second source to the detection circuitry. 11. The automatically calibrating thermistor circuit of claim 8, the gain of the amplifier being preset to provide a maximum output of the amplifier below the upper end of the expected operating range of the amplifier. 12. The automatically calibrating thermistor circuit of claim 8, the processor indicating failure in response to determining the scale factor is outside a permissible range. 13. An automatically calibrating thermistor circuit comprising: a port coupleable to a thermistor exposed to a heated location over which a range of temperatures is expected, and configured to obtain a temperature reading representative of a temperature of said heated location;a first source, the first source providing a temperature reading associated with one end of said expected range of temperatures; anddetection circuitry having an input selectively coupleable to the port and the first source and having an output, the detection circuitry including an amplifier coupled to the input and having a generally preset gain and a variable offset, the variable offset being set in response to an adjustable offset signal coupled thereto, and an A/D converter coupled to the amplifier and the output by which to provide a digital temperature signal correlated to a temperature reading at the input, the amplifier outputting amplified temperature reading signals across an expected operating range in relation to said expected temperature range of said heated location, the amplifier outputting a minimum value in response to the first source; anda processor coupled to the detection circuitry output, the processor selectively causing the first source to be coupled the input of the detection circuitry in a calibration mode and the port to be coupled to the input of the detection circuitry in a normal operation mode, in the calibration mode the processor determining the adjustable offset signal based on the digital temperature signals obtained from the first source, the processor further indicating failure if the adjustable offset signal determined by the processor is outside of an acceptable range. 14. The automatically calibrating thermistor circuit of claim 13 further comprising a second source providing a temperature reading related to a second temperature associated with another end of said expected range of temperatures to cause the amplifier to output a maximum value, the detection circuitry input further selectively coupleable to the second source, the processor further selectively causing one of the first source and the second source to be coupled to the input of the detection circuitry in the calibration mode, the processor determining a scale factor based on a relationship between the digital temperature signal obtained from the second source and a desired maximum output of the amplifier and indicating a failure in response to determining the scale factor exceeds a permissible value. 15. A method of automatically calibrating a thermistor circuit in which a thermistor is to be exposed to heat from a heated location, the temperature of which is expected to vary over a range of temperatures comprising: operating a processor to selectively couple temperature readings from a first source providing a temperature reading associated with one end of said expected range of temperatures, through an amplifier having a generally preset gain and a variable offset, the variable offset being set in response to an adjustable offset signal coupled thereto, and an A/D converter to generate digital temperature signals corresponding to the temperature readings, the amplifier outputting amplified temperature reading signals across an expected operating range in relation to the expected temperature range, the temperature reading provided by the first source corresponding to a minimum value output of the amplifier;determining with the processor the adjustable offset signal based on digital temperature signals obtained from the first source;automatically setting the variable offset of the amplifier in response to the adjustable offset signal determined by the processor so that the variable offset of the amplifier is based on the digital temperature signals obtained from the first source;thereafter, with the variable offset of the amplifier set in response to the adjustable offset signal determined by the processor, operating the processor to selectively couple temperature readings from the thermistor through the amplifier and the A/D converter to generate digital temperature signals corresponding the temperature readings from the thermistor; anddetermining with the processor a temperature of said heated location based on the digital temperature signals obtained from the thermistor. 16. The method of claim 15 further comprising determining the adjustable offset signal by iteratively adjusting the offset signal until the digital temperature signal obtained from the first source correlates to an expected digital signal. 17. The method of claim 16 further comprising iteratively determining the offset signal as an average of upper and lower boundary values and varying the boundary values in relation to the digital temperature signal from the A/D converter until the boundary values satisfy a predetermined criterion. 18. The method of claim 17 further comprising initially setting the boundary values to respective minimum and maximum values. 19. The method of claim 15 further comprising indicating failure if the offset signal determined is outside of an acceptable range. 20. The method of claim 15 further comprising: coupling a temperature reading from a second source providing a temperature reading associated with another end of said expected range of temperatures through the amplifier and the A/D converter to generate a digital temperature signal corresponding to the temperature reading from the second source, the temperature reading provided by the second source corresponding to a maximum value output of the amplifier;determining with the processor a scale factor based on a relationship between the digital temperature signal corresponding to the temperature reading from the second source and a desired maximum output of the amplifier; andadjusting the digital temperature signals corresponding to the temperature readings from the thermistor in relation to the scale factor. 21. The method of claim 20 further comprising setting gain of the amplifier to provide a maximum value output below the desired maximum output. 22. The method of claim 20 further comprising indicating failure if the scale factor is outside a permissible range.
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