Abstract. 

The paper describes algorithms for automatic calculation of the values of risk factors for diseases on the base of data received from bracelets, smart watches, scales and other Internet of Thingsdevices. At the present time such devices allow us to measure different parameters of a person's health and lifestyle. It is possible to calculate the values of risk factors for various diseases, on the base of these parameters. The article describes an algorithm to calculate the average heart rate at rest values as one of risk factors using data received from wearable devices.

DOI 10.14357/20718632210109

 

References

1. Grigoriev O. G., Molodchenkov A. I. Technology of Personalized Preventive Recommendation Formation Based on Disease Risk Assessment // 17th Russian Conference on Artificial Intelligence, RCAI 2019 (Ulyanovsk; Russian Federation; 21-25 October).2019. Springer, Communications in Computer and Information Science, Vol.1093. P. 298-309. DOI: 10.1007/978-3-030-30763-9_25

2. E. Tapia, “Using machine learning for real-time activity recognition and estimation of energy expenditure” Ph.D. dissertation, Massachusetts Inst. Technol., Cambridge, MA, USA, 2008.

3. G. K. Reddy and K. L. Achari A non invasive method for calculating calories burned during exercise using heartbeat // IEEE 9th International Conference on Intelligent Systems and Control (ISCO), Coimbatore, 2015, pp. 1-5.

4. Y. Jain, D. Chowdhury and M. Chattopadhyay Machine Learning Based Fitness Tracker Platform Using MEMS Accelerometer // International Conference on Computer, Electrical & Communication Engineering (ICCECE), Kolkata, 2017, pp. 1-5.

5. R. Choi, W. Kang and C. Son, Explainable sleep quality evaluation model using machine learning approach // 2017 IEEE International Conference on Multisensor Fusion and Integration for Intelligent Systems (MFI), Daegu, 2017, pp. 542-546.

6. Grzymala-Busse J. W. LERS-a system for learning from examples based on rough sets //Intelligent decision support. – Springer, Dordrecht, 1992. – pp. 3-18.

7. de Arriba-Pérez, F., Caeiro-Rodríguez, M. & Santos-Gago, J.M. How do you sleep? Using off the shelf wrist wearables to estimate sleep quality, sleepiness level, chronotype and sleep regularity indicators. // J Ambient Intell Human Comput 9, 897–917 (2018). https://doi.org/10.1007/s12652-017-0477-5

8. Cleary JG, Cleary JG, Trigg LE (1995) K*: An Instancebased Learner Using an Entropic Distance Measure. In: Proc 12th Int Conf Mach Learn, pp 108–114

9. Shevade SK, Keerthi SS, Bhattacharyya C, Murthy KRK (2000) Improvements to the SMO algorithm for SVM regression. IEEE Trans Neural Netw 11:1188–1193

10. MacKay D (1998) Introduction to Gaussian processes. NATO ASI Ser F Comput Sys Sci 168:133–166

11. Ruck DW, Rogers SK, Kabrisky M et al (1990) The multilayer perceptron as an approximation to a Bayes optimal discriminant function. IEEE Trans Neural Netw 1:296–298.

12. Frank E, Hall M, Pfahringer B (2003) Locally weighted naive bayes. In: Proc Ninet Conf Uncertain Artif Intell, pp 249–256.

13. Welch, P. D. (1967), "The use of Fast Fourier Transform for the estimation of power spectra: A method based on time averaging over short, modified periodograms" (PDF), IEEE Transactions on Audio and Electroacoustics, AU-15 (2): 70–73, Bibcode:1967ITAE...15...70W, doi:10.1109/TAU.1967.1161901

14. Orfanidis, S. J. Introduction to Signal Processing. Englewood Cliffs, NJ: Prentice-Hall, 1995.

15. Fitbase https://www.fitabase.com/resources/knowledgebase/exporting-data/example-data-sets/