EPS@ISEP | The European Project Semester (EPS) at ISEP

Differences

This shows you the differences between two versions of the page.

--- report [2019/06/22 10:33] – [3.12 Sprint Evaluations] team4
+++ report [2019/06/26 16:32] (current) – [8.7 Tests and Results] team4
@@ Line 1018: / Line 1018: @@
 ^ PBI/P ^ Task ^ Assignee ^ Planed effort [days] ^ Needed time [days] ^ Status ^ Reasons why tasks were not completed ^
 |168|Final Presentation |Elien|1|1.5|Completed|/|
+|176|Final Table List of Requirements |Vaido|2|2|Completed|/|
 |164|Wiki review |Team|6|10|Completed|/|
 |174|Graphs, images and texts about several tests |Marcel, Tobi|6|9|Completed|/|
@@ Line 1025: / Line 1026: @@
 |P|After meeting with supervisors - 13th Meeting (2019-06-06)|Alex|0.1|0.1|Completed|/|
 |P|Week Report (wiki Logbook) 15th Week Report (2019-06-10 to 2019-06-14)|Alex|0.1|0.1|Completed|/|
-^ ^  ^Sprint Velocity ^16.9 ^23.4 ^ ^ ^
+^ ^  ^Sprint Velocity ^18.9 ^25.4 ^ ^ ^
 </WRAP>
@@ Line 1033: / Line 1034: @@
 </table>
 ^ PBI/P ^ Task ^ Assignee ^ Planed effort [days] ^ Needed time [days] ^ Status ^ Reasons why tasks were not completed ^
-|/|/|/|/|/|/|
+|169|Final version of the poster |Elien|0.3|0.3|Completed|/|
-^ ^  ^Sprint Velocity ^0.0 ^0.0 ^ ^ ^
+|170|Final version of the video |Elien|0.2|0.2|Completed|/|
+|171|Final adjustments on the Tests Chapter |Marcel, Tobi|4|5|Completed|/|
+|172|Final adjustments on SOLIDWORKS |Ko|0.5|0.5|Completed|/|
+|173|Closing of the project with several improvements in wiki |Team|12|12|Completed|/|
+|P|Sprint analysis - Sprint 12, 13-06-2019 to 19-06-2019 |Alex|0.6|0.6|Completed|/|
+|P|Week Report (wiki Logbook) 14th Week Report (2019-06-03 to 2019-06-07)|Alex|0.1|0.1|Completed|/|
+|P|Sprint analysis - Sprint 13, 21-06-2019 to 27-06-2019 |Alex|0.6|0.6|Completed|/|
+|P|Week Report (wiki Logbook) 17th Week Report (2019-06-24 to 2019-06-27)|Alex|0.1|0.1|Completed|/|
+^ ^  ^Sprint Velocity ^18.4 ^19.4 ^ ^ ^
 </WRAP>
@@ Line 2538: / Line 2547: @@
 <WRAP centeralign>
 <figure HSschematic>
-{{ ::homestation1_schem.jpg?600 |}}
+{{ ::SchematicNew.jpg?600 |}}
 <caption>Home Station Schematic Drawing </caption>
 </figure>
@@ Line 2555: / Line 2564: @@
 ==== - Tests and Results ====
 In the following, all parts of bGuard are installed, tested and evaluated.
-=== - Crash Test Home Station ===
+=== - Pressure simulation of the Home Station in SOLIDWORKS ===
-The material for the home station concept is going to be ABS. This material is strong enough to hold a force of 100 N on top without bending too much or breaking it. The reason for 100 N is because the model has to fall from two meters without breaking. However, the model is only 58 g so when it falls from two meters, it will probably only reach a force of 50 N. This is the reason of a safety factor of two what makes 100 N. A SOLIDWORKS test has been carried out to prove this. See **Figures** {{ref>tension_1}} and {{ref>verpl_1}}. The images show that when there is a force of 100 N on the top of the ABS. The displacement {{ref>verpl_1}} of the material is only 0.386 mm on the most loaded point. Normally, you can't consider this to be anything. The tension in the product shows the same result.
+The material for the home station concept is going to be ABS. This material is strong enough to hold a force of 100 N on top without bending too much or breaking it. The reason for 100 N is because the model has to fall from two meters without breaking. However, the model is only 58 g so when it falls from two meters, it will probably only reach a force of 50 N. This is the reason of a safety factor of two what makes 100 N. A SOLIDWORKS test has been carried out to prove this. See **Figures** {{ref>tension_1}} and {{ref>verpl_1}}. The images show that when there is a force of 100 N on the top of the ABS. The displacement {{ref>verpl_1}} of the material is only 0.338 mm on the most loaded point. Normally, you can't consider this to be anything. The von Mises stress equivalent in the product shows the same result.
 <WRAP centeralign>
@@ Line 2736: / Line 2745: @@
 <figure temp30>
 {{ :temphum30.png?nolink&1000 |}}
-<caption>Temperature and Humidity measurements for 30°C and comparison to reference device and error and uncertainty calculation</caption>
+<caption>Temperature and relative Humidity measurements for 30°C and comparison to reference device and error and uncertainty calculation</caption>
 </figure>
 </WRAP>
@@ Line 2744: / Line 2753: @@
 <figure temp28>
 {{ :temphum28.png?nolink&1000 |}}
-<caption>Temperature and Humidity measurements for 28 °Cand comparison to reference device and error and uncertainty calculation</caption>
+<caption>Temperature and relative Humidity measurements for 28 °Cand comparison to reference device and error and uncertainty calculation</caption>
 </figure>
 </WRAP>
@@ Line 2751: / Line 2760: @@
 <figure temp26>
 {{ :temphum26.png?nolink&1000 |}}
-<caption>Temperature and Humidity measurements for 26 °C and comparison to reference device and error and uncertainty calculation</caption>
+<caption>Temperature and relative Humidity measurements for 26 °C and comparison to reference device and error and uncertainty calculation</caption>
 </figure>
 </WRAP>
@@ Line 2762: / Line 2771: @@
 </WRAP>
-The required accuracy of the temperature is ± 3 % and of the Humidity ± 5 %. Therefore the values are acceptable.
+The required accuracy of the temperature is ± 3 % and of the relative Humidity ± 5 %. Therefore the values are acceptable.
+<WRAP centeralign>
+<figure temphumkurve>
+{{ :bildschirmfoto_2019-06-26_um_16.35.06.png?nolink&1000 |}}
+<caption>Temperature and relative Humidity tendency curve and synthesising graph</caption>
+</figure>
+</WRAP>
+The measured values are calibrated software-wise by calculating the average absolute error and subtract it from the measured value. Doing that the precision of the sensor could be improved as it can be seen in **Figure {{ref>temphumkurve}}**.
 === - Pulse Measurement ===
@@ Line 2768: / Line 2786: @@
 == - Electrocardiography ==
-The Electrocardiography (ECG) is a graph with voltage over time measuring the electrical activity of the heart. The cardiac muscle re- and de-polarization during a cardiac cycle is detected. As you can see in **Figure {{ref>pqrs}}** the heartbeat is divided into specific phases. During each heartbeat, a healthy heart has an orderly progression of depolarization that starts with pacemaker cells in the sinoatrial node, spreads throughout the atrium, passes through the atrioventricular node down into the bundle of His and into the Purkinje fibres spreading down and to the left throughout the ventricles. [(EKGphysio)]
+The Electrocardiography (ECG) is a graph with voltage over time measuring the electrical activity of the heart. The cardiac muscle re- and de-polarization during a cardiac cycle is detected. As you can see in **Figure {{ref>pqrs}}** the heartbeat is divided into specific phases. During each heartbeat, a healthy heart has an orderly progression of depolarization that starts with pacemaker cells in the sinoatrial node, spreads throughout the atrium, passes through the atrioventricular node down into the bundle of His and into the Purkinje fibres spreading down and to the left throughout the ventricles [(EKGphysio)].
@@ Line 2806: / Line 2824: @@
 </WRAP>
-The systolic upstroke does not occur immediately following the contraction of the heart. On the ECG, the electrophysiological phenomenon which signals the beginning of systole is the R wave. Usually, the arterial pulse wave does not appear on the monitors until a 160 to 180 ms delay. The main reason next to measurement uncertainties is that after the R wave, (the depolarization wave) has to spread through the left ventricle, some isovolumetric contraction needs to take place, then the aortic valve has to open, and then the aortic pressure wave needs to travel up the aorta and down the arm (at 6 m/s to 10 m/s). The systolic upstroke is the ventricular ejection being generated by the fast-moving 10 m/s wave and corresponds to the peak aortic blood flow acceleration at the opening of the aortic valve[(puls02)].
+The systolic upstroke does not occur immediately following the contraction of the heart. On the ECG, the electrophysiological phenomenon which signals the beginning of systole is the R wave. Usually, the arterial pulse wave does not appear on the monitors until a 160 ms to 180 ms delay. The main reason next to measurement uncertainties is that after the R wave, (the depolarization wave) has to spread through the left ventricle, some isovolumetric contraction needs to take place, then the aortic valve has to open, and then the aortic pressure wave needs to travel up the aorta and down the arm (at 6 m/s to 10 m/s). The systolic upstroke is the ventricular ejection being generated by the fast-moving 10 m/s wave and corresponds to the peak aortic blood flow acceleration at the opening of the aortic valve[(puls02)].
@@ Line 2836: / Line 2854: @@
 </WRAP>
-In the following the graph of the reference medical device Silvercrest SPO55 with an accuracy of ± 2 BPM in the range of 30 – 250 BPM Pulse. The error and uncertainty calculations are done the same as explained in the temperature and humidity measurement chapter before.
+In the following the graph of the reference medical device Silvercrest SPO55 with an accuracy of ± 2 BPM in the range of 30 BPM to 250 BPM Pulse. The error and uncertainty calculations are done the same as explained in the temperature and humidity measurement chapter before.
@@ Line 2909: / Line 2927: @@
 <WRAP centeralign>
 <figure fade>
-{{ :bildschirmfoto_2019-06-05_um_13.14.37.png?nolink&600 |}}
+{{ :bildschirmfoto_2019-06-05_um_13.14.37.png?nolink&450 |}}
 <caption>Signal after filter  </caption>
 </figure>
 </WRAP>
-For calibrating the sensor a sound with a constant level is created with the function generator and the speaker. While creating the sound the sound meter measures the decibel. The microphone measures at the same the voltage level. Assuming that the sound meter decibel (x) is linear to the voltage level (y), the output sound level in dB is calculated with this formula:
+For calibrating the sensor a sound with a constant level is created with the function generator and the speaker. While creating the sound the sound meter measures the decibel. The microphone measures at the same the voltage level. Assuming that the sound meter decibel is linear to the voltage level, the output sound level in dB is calculated with this formula [(Sensitivity)]:
 <WRAP centeralign>
 \begin{equation}
-    L= x +10*\log_{10}({\frac{mic}{y}}) (dBA)
+     Output Sound Level= Sound Level Meter +20*\log_{10}({\frac{Sensititvity Sensor}{Output Sensor}}) (dBA)
 \end{equation}
 </WRAP>
-If the microphone value (mic) is similar to the voltage level (y), the logarithm is zero and the sound level is equal to the decibel of the sound meter measurement (x).
+If the microphone value is similar to the voltage level, the logarithm is zero and the sound level is equal to the decibel of the sound meter measurement. This offset added to the referenced formula.
 A baby cry has a frequency range from 336.9 Hz to 502 Hz [(babyschrei)]. Due to that, the frequency stability of the MAX4466 is tested. In **Figure {{ref>extfreq}}** the noise level in dBA overtime for the two extreme frequencies can be seen. The reference graph is laid over the ones of the microphone. The lower the frequency gets the bigger is the deviation between these graphs. Due to the fact that our target is to create a cry detection and not an exact sonometer the deviations can be accepted. Because of that, we accept a deviation of ± 5 %. Within that range, a cry is still reliably detected. As an example, both extreme values are shown with the acceptance range in **Figure {{ref>extfreq}}**. It can be seen that the measured extreme values for frequencies of 100 Hz and 500 Hz compared with the sound level meter with the acceptance range of 5 %.
@@ Line 3025: / Line 3044: @@
 Also bGuard mobile application is one of the things that need further development. The team had an idea of what the app should look like and what data it should provide but were only able to design the interface. The application is now merely a concept. Moreover, the team was not able to develop a real app in the given time. For example, now bGuard is limited to sending an audio file to the Smart Pillow but in the future, the team would like to expand this to a communication feature which allows the parents to talk to the baby.
+Additionally, the tests can be improved. The simulation in SOLIDWORKS by taking into account the calculation of the force (based on the real weight of the home station including all the components) as also the pressure. Now, the tests has been done with assumptions of real life examples.  Also, the tests of the sensors and their aim can be improved.
 Furthermore, the team would make our bGuard comply with the regulations of being a medical device. This would help to position the bGuard as a trustworthy device and help make bGuard to a market leader.
-Additionally, the team would focus on using smaller and more precise electronic components. This way they will take in less space and become more accurate results. The given budget made these things difficult to realize during the project.
+Finally, the team would focus on using smaller and more precise electronic components. This way they will take in less space and become more accurate results. The given budget made these things difficult to realize during the project.
 ===== Bibliography =====

Trace: • bib

Differences

Search

Navigation

Print/export

Tools

QR Code