论文信息 - Accelerometer Data Analysis and Presentation Techniques

Accelerometer Data Analysis and Presentation Techniques

The NASA Lewis Research Center's Principal Investigator Microgravity Services project analyzes Orbital Acceleration Research Experiment and Space Acceleration Measurement System data for principal investigators of microgravity experiments. Principal investigators need a thorough understanding of data analysis techniques so that they can request appropriate analyses to best interpret accelerometer data. Accelerometer data sampling and filtering is introduced along with the related topics of resolution and aliasing. Specific information about the Orbital Acceleration Research Experiment and Space Acceleration Measurement System data sampling and filtering is given. Time domain data analysis techniques are discussed and example environment interpretations are made using plots of acceleration versus time, interval average acceleration versus time, interval root-mean-square acceleration versus time, trimmean acceleration versus time, quasi-steady three dimensional histograms, and prediction of quasi-steady levels at different locations. An introduction to Fourier transform theory and windowing is provided along with specific analysis techniques and data interpretations. The frequency domain analyses discussed are power spectral density versus frequency, cumulative root-mean-square acceleration versus frequency, root-mean-square acceleration versus frequency, one-third octave band root-mean-square acceleration versus frequency, and power spectral density versus frequency versus time (spectrogram). Instructions for accessing NASA Lewis Research Center accelerometer data and related information using the internet are provided.

[1] Stephen A. Dyer,et al. Digital signal processing , 2018, 8th International Multitopic Conference, 2004. Proceedings of INMIC 2004..

[2] Emmanuel Ifeachor,et al. Digital Signal Processing: A Practical Approach , 1993 .

[3] Kenneth Hrovat,et al. Summary Report of Mission Acceleration Measurements for STS-89 , 1999 .

[4] Milton E. Moskowitz,et al. Comparison tools for assessing the microgravity environment of space missions, carriers, and conditions , 1998, Defense, Security, and Sensing.

[5] J. Alexander,et al. Analysis techniques for residual acceleration data , 1990 .

[6] R. DeLombard,et al. Comparison tools for assessing the microgravity environment of orbital missions, carriers and conditions , 1999, IMTC/99. Proceedings of the 16th IEEE Instrumentation and Measurement Technology Conference (Cat. No.99CH36309).

[7] Roshanak Hakimzadeh,et al. Summary Report of Mission Acceleration Measurements for STS-78. Launched June 20, 1996 , 1997 .

[8] Roman Kuc,et al. Introduction to Digital Signal Processing , 1988 .

[9] R. Blanchard,et al. Orbiter Rarefied-Flow Reentry Measurements From the OARE on STS-62 , 1995 .

[10] R. Blanchard,et al. Absolute acceleration measurements on STS-50 from the Orbital Acceleration Research Experiment (OARE) , 1994 .

[11] R. DeLombard,et al. Summary Report of Mission Acceleration Measurements for STS-65, Launched 8 July 1994 , 1995 .