השוואת שיטות
סקרו את השיטות שבחרתם זו לצד זו; שורות שבהן יש הבדל מודגשות.
| איסוף נתונים חיישניים אורכי× | איסוף נתוני חיישנים× | |
|---|---|---|
| תחום | מתודולוגיית סקרים | מתודולוגיית סקרים |
| משפחה | Process / pipeline | Process / pipeline |
| שנת המקור≠ | 1990s–2000s (accelerated with IoT and wearable devices from ~2010) | 1990s–2000s (widespread deployment with IoT ~2000s) |
| הוגה השיטה≠ | Emerging from ambulatory assessment and wearable technology research communities | Multidisciplinary; sensor networks formalized in engineering and computer science from the 1990s onward |
| סוג≠ | Longitudinal quantitative/mixed data collection technique | Quantitative / mixed data collection technique |
| מקור מכונן≠ | Lanza, S. T., Collins, L. M., Lemmon, D. R., & Schafer, J. L. (2005). PROC LCA: A SAS procedure for latent class analysis. Structural Equation Modeling, 14(4), 671–694. [For longitudinal intensive repeated-measures designs context, see also: Shiffman, S., Stone, A. A., & Hufford, M. R. (2008). Ecological momentary assessment. Annual Review of Clinical Psychology, 4, 1–32.] link ↗ | Chong, C.-Y., & Kumar, S. P. (2003). Sensor networks: Evolution, opportunities, and challenges. Proceedings of the IEEE, 91(8), 1247–1256. DOI ↗ |
| כינויים | long-term sensor monitoring, longitudinal sensing, continuous sensor logging, repeated-measures sensor collection | sensor measurement, instrumented data collection, physical sensor logging, IoT data collection |
| קשורות≠ | 3 | 5 |
| תקציר≠ | Longitudinal sensor data collection deploys physical or digital sensors to record phenomena continuously or at regular intervals across an extended study period — days, months, or years. Unlike one-shot measurement, the repeated temporal structure captures change, trajectory, and variability in outcomes such as physical activity, environmental exposure, sleep, or physiological state. The approach combines the ecological validity of real-world sensing with the analytical power of longitudinal design. | Sensor data collection uses physical or digital instruments to automatically capture quantitative measurements from the environment, human bodies, or machines over time. Common sensors measure temperature, motion, heart rate, location, light, sound, or chemical properties. Because the recording is automated and continuous, the method can produce high-frequency datasets with minimal researcher burden, making it central to IoT, environmental monitoring, wearable research, and behavioral studies. |
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