Verification of a meter sensor for a vibratory meter

What is claimed is: 1. A vibrating element meter ( 5 ) for meter health verification, the vibrating element meter ( 5 ) comprising: a sensor assembly ( 10 ) including a vibrating member ( 12 ), a pickoff/detection sensor ( 17 ), and a driver ( 16 ) configured to vibrate the vibrating member ( 12 ); at least one temperature sensor ( 112 ) coupled to the sensor assembly; and meter electronics ( 20 ) coupled to the pickoff/detection sensor ( 17 ), the driver ( 16 ), and the at least one temperature sensor ( 112 ), with the meter electronics ( 20 ) being configured to measure a plurality of temperatures using the at least one temperature sensor ( 112 ) and to measure a sequence of driver generated sensor signal periods detected by the pickoff/detection sensor ( 17 ), wherein the meter electronics determine an average temperature from the plurality of temperatures, determine an average sensor signal period using the average temperature to generate a compensated sensor signal period, compare the compensated sensor signal period to a reference sensor signal period, and indicate whether the compensated sensor signal period is within a sensor signal period error limit of the reference sensor signal period. 2. The vibrating element meter ( 5 ) of claim 1 , wherein measuring the plurality of temperatures ( 206 ) using the temperature sensor ( 112 ) and the sequence of sensor signal periods ( 207 ) using the sensor assembly ( 10 ) further comprises filling the sensor assembly ( 10 ) with ambient air. 3. The vibrating element meter ( 5 ) of claim 1 , wherein measuring the plurality of temperatures ( 206 ) using the temperature sensor ( 112 ) and the sequence of sensor signal periods ( 207 ) using the sensor assembly ( 10 ) further comprises placing the sensor assembly ( 10 ) under a vacuum. 4. The vibrating element meter ( 5 ) of claim 1 , wherein measuring the plurality of temperatures ( 206 ) using the temperature sensor ( 112 ) and the sequence of sensor signal periods ( 207 ) using the sensor assembly ( 10 ) further comprises filling the sensor assembly ( 10 ) with or inserting the sensor assembly into a fluid having an accurately known density. 5. The vibrating element meter ( 5 ) of claim 1 , wherein the meter electronics ( 20 ) is further configured to calculate a standard deviation using one of the plurality of temperatures ( 206 ) and the sequence of sensor signal periods ( 207 ), compare the standard deviation to a limit, and indicate whether the standard deviation is greater than the limit. 6. The vibrating element meter ( 5 ) of claim 1 , wherein the meter electronics ( 20 ) is further configured to receive an altitude ( 218 ), and compensate the compensated sensor time period ( 210 ) using the altitude ( 218 ). 7. The vibrating element meter ( 5 ) of claim 6 , wherein the meter electronics ( 20 ) is further configured to measure a density of a fluid using the sensor assembly ( 10 ), and compensate the compensated sensor time period ( 210 ) for a difference in density between the reference density ( 220 ) and the measured density ( 219 ) using the altitude ( 218 ) and the average temperature ( 208 ). 8. A method for health verification of a sensor, the method comprising the steps of: measuring a plurality of temperatures ( 206 ) of a fluid flow using at least one temperature sensor ( 112 ) coupled to a sensor assembly and to measure a sequence of driver generated sensor signal periods ( 207 ) detected by a pickoff/detection sensor ( 17 ) of the sensor assembly ( 10 ), the sensor assembly ( 10 ) further including a vibrating member ( 12 ), and a driver ( 16 ) configured to vibrate the vibrating member ( 12 ); determining an average temperature ( 208 ) from the plurality of temperatures ( 206 ); determining an average sensor signal period ( 209 ) using the average temperature ( 208 ) to generate a compensated sensor signal period ( 210 ); comparing the compensated sensor signal period ( 210 ) to a reference sensor signal period ( 211 ); and indicating whether the compensated sensor time period ( 210 ) is within a sensor time error limit ( 212 ) of the reference sensor signal period ( 211 ). 9. The method of claim 8 , further comprising: cleaning the sensor assembly ( 10 ). 10. The method of claim 8 , wherein measuring the plurality of temperatures ( 206 ) and the sequence of sensor signal periods ( 207 ) using the sensor assembly ( 10 ) further comprises filling the sensor assembly ( 10 ) with ambient air. 11. The method of claim 8 , wherein measuring the plurality of temperatures ( 206 ) and the sequence of sensor signal periods ( 207 ) using the sensor assembly ( 10 ) further comprises placing the sensor assembly ( 10 ) under a vacuum. 12. The method of claim 8 , wherein measuring the plurality of temperatures ( 206 ) and the sequence of sensor signal periods ( 207 ) using the sensor assembly ( 10 ) further comprises filling the sensor assembly ( 10 ) with or inserting the sensor assembly ( 10 ) into a fluid having an accurately known density. 13. The method of claim 8 , further comprising the steps of: calculating a standard deviation using one of the plurality of temperatures ( 206 ) and the sequence of sensor signal periods ( 207 ); comparing the standard deviation to a limit; and indicating whether the standard deviation is greater than the limit. 14. The method of claim 8 , further comprising the steps of: receiving an altitude ( 218 ); and compensating the compensated sensor time period ( 210 ) using the altitude ( 218 ). 15. The method of claim 14 , wherein compensating the compensated sensor time period ( 210 ) using the altitude ( 218 ) further includes: measuring a density of a fluid using the sensor assembly ( 10 ); and compensating the compensated sensor time period ( 210 ) for a difference in density between the reference density ( 220 ) and the measured density ( 219 ) using the altitude ( 218 ) and the average temperature ( 208 ). 16. A method for health verification of a sensor, the method comprising the steps of: measuring a plurality of temperatures ( 206 ) using at least one temperature sensor ( 112 ) coupled to a sensor assembly and a sequence of driver generated sensor signal periods ( 207 ) detected by a pickoff/detection sensor ( 17 ) of the sensor assembly ( 10 ), the sensor assembly ( 10 ) further-including a vibrating member ( 12 ), and a driver ( 16 ) configured to vibrate the vibrating member ( 12 ); calculating a first standard deviation using both a first data set comprising a plurality of temperatures ( 206 ) and a second standard deviation using a sequence of sensor signal periods ( 207 ); comparing the first and second standard deviation ( 213 , 214 ) to a respective first and second limit ( 215 , 216 ); and indicating whether the respective first and second standard deviation ( 213 , 214 ) is greater than the respective first and second limit ( 215 , 216 ). 17. The method of claim 16 , further comprising the steps of: calculating a second standard deviation ( 213 , 214 ) using a second data set comprising one of the plurality of temperatures ( 206 ) or the sequence of sensor signal periods ( 207 ), wherein the first data set is different from the second data set; comparing the second standard deviation ( 213 , 214 ) to a second limit ( 215 , 216 ); and indicating whether the second standard deviation ( 213 , 214 ) is greater than the second limit ( 215 , 216 ).