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--- report:soa [2026/03/28 08:14] – [Comparative Analysis] team3
+++ report:soa [2026/04/21 14:14] (current) – [Comparative Analysis] team3
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 Before presenting our own solution, we will first analyze concepts, existing products and projects on the market. Finally, a detailed comparative table will be provided, evaluating current market leaders alongside the specific sensors and features relevant to our project.
-<color #ed1c24>Add and cite references properly. References are added in BibTeX format to the refnotes.bib file and then are cited through the text as needed . See how to do it by following the links at the bottom of the page.</color>
 ==== Concepts ====
 ==The IoT and Digital Health Framework ==
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 <WRAP box center>
 ^ Component  ^  Size (mm)  ^  Price (€)  ^  Power Consumption (mW)  ^  Weight (g)  ^
-|TDS Sensor (SEN0244)  | 42 $\times$ 32 (cable ~800) | 23 | 10–30 | ~32 |
+|TDS Sensor (SEN0244)  | 42 x 32 (cable ~800) | 23 | 10–30 | ~32 |
-|Pressure Sensor (FSR406)  | 43.7 $\times$ 43.7 | 13 | 2–3 | ~3 |
+|Pressure Sensor (FSR406)  | 43.7 x 43.7 | 13 | 2–3 | ~3 |
-|UV-C LED Module  | 30 $\times$ 30 | ~30 | 0–5 (standby), 1000 (cleaning) | ~3 |
+|UV-C LED Module  | 30 x 30 | ~30 | 0–5 (standby), 1000 (cleaning) | ~3 |
-|Accelerometer (LIS3DHTR)  | 20 $\times$ 15 $\times$ 3 | ~10 | 0,165 | 2 |
+|Accelerometer (LIS3DHTR)  | 20 x 15 x 3 | ~10 | 0,165 | 2 |
-|Temperature Sensor (KY-015 DHT)  | 32 $\times$ 14 $\times$ 7 | 11 | 7 | 8 |
+|Temperature Sensor (KY-015 DHT)  | 32 x 14 $\times$ 7 | 11 | 7 | 8 |
-|Piece of activated carbon  | 50 $\times$ 30 | 12 | 0 | 5 (dry), 10 (wet) |
+|Piece of activated carbon  | 50 x 30 | 12 | 0 | 5 (dry), 10 (wet) |
-|Microcontroller (ESP32 DevKit V1)  | 56 $\times$ 28 $\times$ 13 | 13 | 792 | 20 |
+|Microcontroller (ESP32 DevKit V1)  | 56 x 28 x 13 | 13 | 792 | 20 |
-|SSD1306 OLED Display (0.96")  | 25 $\times$ 26 | 4 | 82,5 | 4 |
+|SSD1306 OLED Display (0.96")  | 25 x 26 | 4 | 82,5 | 4 |
 </WRAP>
 </table>
 </WRAP>
 ==== Summary ====
 The analysis of existing concepts, projects and smart water bottles shows that many products address individual aspects of hydration and water quality. Some focus on hydration tracking and behavioral motivation through smartphone apps, while others integrate UV-C technology for disinfection or include filtration systems. However, there is currently no product on the market that combines UV-C disinfection, water filtration, volume tracking, mineral content measurement, and a user-friendly app with gamification in one integrated system. While individual features exist across different products, they have not yet been combined into a single solution. This represents a potential market opportunity for the TRAQUA concept.
 At the same time, there is a growing trend toward tracking everyday behavior and focusing more on personal health and wellbeing. People increasingly monitor activity, sleep, and nutrition using digital tools. However, hydration and especially bottle hygiene are often neglected. Studies show that reusable water bottles are frequently not cleaned adequately, which can lead to bacterial growth, and many people drink less water than recommended. Research also demonstrates that digital reminders and tracking apps can significantly increase daily water intake.
 These insights highlight the potential for a smart bottle like TRAQUA that combines hydration tracking, water quality monitoring, and bottle hygiene in one system while supporting healthier habits through an intuitive and motivating app.