Victoria López, Pavel Llamocca, Diego Urgelés, Yury Jiménez, César Guevara, C. Viñals, Maria Espinosa
{"title":"验证心理健康应用的算法和传感器数据的集成过程","authors":"Victoria López, Pavel Llamocca, Diego Urgelés, Yury Jiménez, César Guevara, C. Viñals, Maria Espinosa","doi":"10.54941/ahfe1004158","DOIUrl":null,"url":null,"abstract":"Mood disorders are becoming more frequent and, especially after the\n pandemic years, the importance of analysing and preventing such disorders\n has become clear. In the worst cases, people can suffer from depression or\n bipolar disorder leading to hospitalization or sick leave with serious\n economic and social consequences for the individual and their environment.\n Thanks to the development of technology, there are increasingly useful\n portable devices for monitoring individual daily activity. The data\n collected is very useful for understanding not only the individual's\n environment but also for characterizing their emotional profile. However,\n good monitoring requires the use of a diverse set of information sources.\n Medical consultations are the traditional source of information but in many\n cases this information is lacking or insufficient. The new sources of\n information are diverse: smart devices such as smart watches or even the\n mobile phone itself, portable sensors of various types and even activity\n records on social networks. All these data can be integrated and processed\n in such a way that a characterization profile of behaviour related to the\n emotional state of the individual is determined. However, the manufacturers\n of these devices apply aggregation algorithms to the monitored data to\n provide the client with a friendlier and easier to interpret version, but\n they do not usually provide the raw data collected by the sensors\n (accelerometer, gyroscope, temperature, etc.). There is still no regulated\n standardization that obliges the manufacturer to provide the data to the\n owners of the devices. Both raw data and aggregation algorithms work like a\n black box in most cases. The information presented by the device\n applications (generally apps) is very relevant and the interpretation of the\n users has direct consequences on their behaviour (behaviour modification,\n medication administration, etc.). For this reason, it is essential to verify\n the algorithms used in the previous process, guaranteeing that the\n information integrated (and presented) really corresponds to the information\n collected by the sensors. In this paper we present a suitable system for the\n verification of aggregated data from personal activity monitoring sensors.\n The system includes a parsing algorithm that makes the data structure and\n relates it to the output. The effectiveness of the algorithm has been tested\n with real data over a period of two years and for both daytime activity and\n sleep quality monitoring. The algorithm is perfectly scalable to be used on\n any device, so the computer system presented can be useful for future\n computer auditing of this type of process.","PeriodicalId":231376,"journal":{"name":"Human Systems Engineering and Design (IHSED 2023): Future Trends\n and Applications","volume":"1 1","pages":"0"},"PeriodicalIF":0.0000,"publicationDate":"1900-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Verification of the integration process of algorithms and sensor data for\\n mental health applications\",\"authors\":\"Victoria López, Pavel Llamocca, Diego Urgelés, Yury Jiménez, César Guevara, C. Viñals, Maria Espinosa\",\"doi\":\"10.54941/ahfe1004158\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"Mood disorders are becoming more frequent and, especially after the\\n pandemic years, the importance of analysing and preventing such disorders\\n has become clear. In the worst cases, people can suffer from depression or\\n bipolar disorder leading to hospitalization or sick leave with serious\\n economic and social consequences for the individual and their environment.\\n Thanks to the development of technology, there are increasingly useful\\n portable devices for monitoring individual daily activity. The data\\n collected is very useful for understanding not only the individual's\\n environment but also for characterizing their emotional profile. However,\\n good monitoring requires the use of a diverse set of information sources.\\n Medical consultations are the traditional source of information but in many\\n cases this information is lacking or insufficient. The new sources of\\n information are diverse: smart devices such as smart watches or even the\\n mobile phone itself, portable sensors of various types and even activity\\n records on social networks. All these data can be integrated and processed\\n in such a way that a characterization profile of behaviour related to the\\n emotional state of the individual is determined. However, the manufacturers\\n of these devices apply aggregation algorithms to the monitored data to\\n provide the client with a friendlier and easier to interpret version, but\\n they do not usually provide the raw data collected by the sensors\\n (accelerometer, gyroscope, temperature, etc.). There is still no regulated\\n standardization that obliges the manufacturer to provide the data to the\\n owners of the devices. Both raw data and aggregation algorithms work like a\\n black box in most cases. The information presented by the device\\n applications (generally apps) is very relevant and the interpretation of the\\n users has direct consequences on their behaviour (behaviour modification,\\n medication administration, etc.). For this reason, it is essential to verify\\n the algorithms used in the previous process, guaranteeing that the\\n information integrated (and presented) really corresponds to the information\\n collected by the sensors. In this paper we present a suitable system for the\\n verification of aggregated data from personal activity monitoring sensors.\\n The system includes a parsing algorithm that makes the data structure and\\n relates it to the output. The effectiveness of the algorithm has been tested\\n with real data over a period of two years and for both daytime activity and\\n sleep quality monitoring. The algorithm is perfectly scalable to be used on\\n any device, so the computer system presented can be useful for future\\n computer auditing of this type of process.\",\"PeriodicalId\":231376,\"journal\":{\"name\":\"Human Systems Engineering and Design (IHSED 2023): Future Trends\\n and Applications\",\"volume\":\"1 1\",\"pages\":\"0\"},\"PeriodicalIF\":0.0000,\"publicationDate\":\"1900-01-01\",\"publicationTypes\":\"Journal Article\",\"fieldsOfStudy\":null,\"isOpenAccess\":false,\"openAccessPdf\":\"\",\"citationCount\":\"0\",\"resultStr\":null,\"platform\":\"Semanticscholar\",\"paperid\":null,\"PeriodicalName\":\"Human Systems Engineering and Design (IHSED 2023): Future Trends\\n and Applications\",\"FirstCategoryId\":\"1085\",\"ListUrlMain\":\"https://doi.org/10.54941/ahfe1004158\",\"RegionNum\":0,\"RegionCategory\":null,\"ArticlePicture\":[],\"TitleCN\":null,\"AbstractTextCN\":null,\"PMCID\":null,\"EPubDate\":\"\",\"PubModel\":\"\",\"JCR\":\"\",\"JCRName\":\"\",\"Score\":null,\"Total\":0}","platform":"Semanticscholar","paperid":null,"PeriodicalName":"Human Systems Engineering and Design (IHSED 2023): Future Trends\n and Applications","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.54941/ahfe1004158","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
Verification of the integration process of algorithms and sensor data for
mental health applications
Mood disorders are becoming more frequent and, especially after the
pandemic years, the importance of analysing and preventing such disorders
has become clear. In the worst cases, people can suffer from depression or
bipolar disorder leading to hospitalization or sick leave with serious
economic and social consequences for the individual and their environment.
Thanks to the development of technology, there are increasingly useful
portable devices for monitoring individual daily activity. The data
collected is very useful for understanding not only the individual's
environment but also for characterizing their emotional profile. However,
good monitoring requires the use of a diverse set of information sources.
Medical consultations are the traditional source of information but in many
cases this information is lacking or insufficient. The new sources of
information are diverse: smart devices such as smart watches or even the
mobile phone itself, portable sensors of various types and even activity
records on social networks. All these data can be integrated and processed
in such a way that a characterization profile of behaviour related to the
emotional state of the individual is determined. However, the manufacturers
of these devices apply aggregation algorithms to the monitored data to
provide the client with a friendlier and easier to interpret version, but
they do not usually provide the raw data collected by the sensors
(accelerometer, gyroscope, temperature, etc.). There is still no regulated
standardization that obliges the manufacturer to provide the data to the
owners of the devices. Both raw data and aggregation algorithms work like a
black box in most cases. The information presented by the device
applications (generally apps) is very relevant and the interpretation of the
users has direct consequences on their behaviour (behaviour modification,
medication administration, etc.). For this reason, it is essential to verify
the algorithms used in the previous process, guaranteeing that the
information integrated (and presented) really corresponds to the information
collected by the sensors. In this paper we present a suitable system for the
verification of aggregated data from personal activity monitoring sensors.
The system includes a parsing algorithm that makes the data structure and
relates it to the output. The effectiveness of the algorithm has been tested
with real data over a period of two years and for both daytime activity and
sleep quality monitoring. The algorithm is perfectly scalable to be used on
any device, so the computer system presented can be useful for future
computer auditing of this type of process.