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36C3 preroll music
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Herald-Angel: Good. Ladies and gentlemen,
we have here a talk by Sebastian Staacks.
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Do I pronounce this well?
Sebastian Staacks: Yes.
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Herald: Yes. Staacks. Staacks. [In German]
Ich musste das mal in Deutsch sagen. And
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he's related to the University of Aachen.
He did a PhD physics. And he was in a team
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that developed a fantastic application, as
I mentioned earlier on. He developed the
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app phyphox. Do I pronounce this well?
Staacks: I would say phi-phox, physical
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phone experiments.
Herald: Okay. Yep. Of course. I'm sorry.
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I'm not in that kind of department. But
this application actually gives you all
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the possibilities off your the usage, off
your smart smartphone. Really? Really
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extending certain borders, to my opinion.
So please give a warm, warm welcome here
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to Stefan.
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Applause
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Stefan: Thank you. Thank you for the
introduction and welcome everybody to my
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talk. Yeah. As you've just heard, I'm a
physicist from the RWTH Aachen university
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where I developed the app phyphox. Phyphox
is an app for those of you who do not know
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it already. That uses the sensors in the
smartphone for physics teaching. So the
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idea is that students can use their own
phones to do experimentation in class, in
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the lecture hall. So for schools and
universities. I should explain. That in
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contrast to some other talks by me. This
one will not be that much about education
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because it is the chaos communication
Congress and this is the hardware track
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here. So I tried to tell you a little bit
about the app, a little bit about the
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sensors that we have on our phones and.
Yeah. Would we love to get in touch with
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some, especially people from maker
community and from open source communities
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to find some connections, how he can get
many open source projects together?
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Because I've got so much feedback from
teachers and I think I could also use some
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feedback from other developers as well. So
I would like to start with a short
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explanation of what we actually do. So
yes, I said I come from a university and
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there we have this introductionary lecture
for physics students, which is called
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experimental physics one. And it's typical
lecture. Looks like this. We have a fancy
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new lecture hall by now, but the situation
is the same. We've got 300 I think 370
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students this year sitting in a lecture
hall and doing no experimentation at all.
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There's only one guy experimenting and
that's the professor. And the students are
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sitting there and enjoying the whole show
like they would enjoy a YouTube video and
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maybe they are mildly amused if something
goes wrong. OK. And we thought we could
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change this by using the sensors in the
smartphones. We're not the first ones with
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the idea to use the sensors there, but for
some reason we decided to write our own
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app, which turned out to be quite
successful then. So in contrast to the old
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version where students just had to look at
and I'll get the assignments where they
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can do their own experiments with their
own measurement devices. And to give you
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an idea of what this looks like. I would
like to start with the first experiment.
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Which is about centrifugal acceleration or
centripetal acceleration depending on your
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preferred frame of reference. So the idea
is from a rotation movement, we want to
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measure the radial acceleration as a
function of the angular velocity. So the
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rotation rate. To do this we take a
regular smartphone, this is an iPhone 8 in
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this case and we put it into a salad
spinner. Okay. We get some rotation in
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there and whoops let me just place it in
there. Sound is not important, but it
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sounds nice. I have been told. So here we
get the live data from the phone already.
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Acceleration on the y axis and angular
velocity on the x axis. If the salad
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spinner is actually moving. And what you
see is the faster I rotate the spinner,
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the farther on the right you get your data
because that's angular velocity and also
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the radial acceleration increases. If I'm
not going too fast because then I do not
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get any data at all anymore. Let's slow
down again and we can fill up the gaps
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there by going really slow and filling up
this path. And in the end, if so, who here
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has a physics background some more than
expected. Great. Because those of you who
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just raised their hands would not be
surprised that we expect a square
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relationship between the radial
accaleration and angular velocity. Those
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of you who do not know will believe me
from this plot where on the x axis we've
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got the angle of velocity squared and on
the y axis the radial acceleration we get
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a straight line and that's what you would
expect. So besides the physics, because
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this is not that much about the physics.
This is a simple experiment all our
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students could do and actually they ge, we
gave them this assignment. We gave them
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also a bonus point if they created a
video. Don't worry. Their consent to that
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we use the video was not related to the
point, they first got the point and then
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we asked for their consent to use the
video. And we learned two things from
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these videos. A Our students do not really
have salad spinners. they've got bicycles
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and office chairs, but b and that was the
most important thing. It looks like I
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mean, these are from this year where we
got almost 100 videos they we actually
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could trigger them to go out, search for
something where they've got the
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rotationary movement and they could repeat
this experiment. Ok. Another example which
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actually changed just the course of the
lecture a little bit is a situation where
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we first give the assignment before we
actually let them, before we actually
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discuss the theory behind this, which
means in this example, this is a little bit
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older because we did not get there yet this
year, we assigned our students to build
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string pendulums. They look very similar
because we were very precise about how
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they should build them. And then we had an
online form where they could submit the
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length of their pendulum and the frequency
they received from it that they measured
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with the pendulum. They should do this for
three different cases. And the idea was
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that we did this assignment long before we
discussed the pendulum in the lecture so
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that they have got a little bit of
research experience. And after we
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collected all the data from them, then the
lecture would discuss the pendulum. So the
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physicists were there now. We do a small
angle, approximation solving differential
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equation. All this theory stuff. And in
the end we were done, we could tell our
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students, well, we do not have to do this
experiment on stage. Now, because all of
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you did this experiment and we simply can
compare the theory that we just arrived
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with your data. And it worked out quite
well. So you see most of the white points,
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which is the data from the students
matches the theory, which is the orange
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line, except maybe for those three who
should proceed on a career of theoretical
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physics. But yeah, so this is all
something got nice feedback from and this
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is in principle how we use the app and
what it's designed for. There are also of
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course many applications in school by now.
More teachers use this in school than we
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use it at the university. So we take this
into consideration as well. But that's the
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reason that I am standing here talking
about the sensors in the smartphone.
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That's the reason that I am trying to
access them. so let's have a look at what
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sensors we actually have in our phone. I
think the first one that most of you would
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think often talking about sensors besides
obvious stuff like the microphone would be
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the accelerometer. So I think yeah, I
think I first explain how the
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accelerometer works. OK, so the
accelerometer in your phone is actually a
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so-called MEMS device. MEMS is M E M S
stands for Micro Electrical Mechanical
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System and it looks roughly like this.
It's a simplification. If you search for
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actual MEMS devices, simply search for M E
M S and accelerometer and you find some
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pictures. They usually are a little bit
more complicated, although the
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accelerometer is not that much more
complicated. It consists of an orange
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case. Yeah, well so far so obvious, but
also two contacts. The blue and the red
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one and important part is this silvery
structure here or the metallic structure
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which is under etched its bit hard to see
on this picture, but it's actually
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floating. It's only attached to the sides,
you see light in between here. So if you
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move around, the accelerometer the inner
path, can actually move. So let's do this.
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So at each point where the device is extra
riding in one direction or the other
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direction, due to inertia the that the
metallic part in here is distorted, moved
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into one direction and we can measure the
amount by which it is deflected by this
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movement with the two contacts by
measuring the capacity between these
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structures. So that's the principle of the
accelerometer. One thing to mention at
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this point is that it's in the sense of
physics. It does not really only measure
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acceleration. It measures acceleration you
see in this image of the device
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accelerating. We get some data, but if you
imagine we take this device and rotate it
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like this, then of course you also get a
deflection of the of the metallic part by
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gravity. So gravity is pulling it down as
well. And that's the main reason the
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accelerometer is in there because the
developers and manufacturers of the phones
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are not really interested in measuring
acceleration, at least there aren't that
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many use cases for it. But instead, what
they want to have is an indication on
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which direction is down or which direction
is up. So when you rotate the screen of
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your phone, actually they can rotate the
content of the phone as well or with this
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you can also then control video games by
tilting your phone and stuff like this.
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Because gravity also deflects the
accelerometers. Earth's acceleration,
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which you try to avoid because from
didactic point of view, this is a
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nightmare to distinguish these both. But
the point is that we can detect rotations
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like this and this is pretty much in every
phone. I mean, this is not really a
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statistic. This is just the first pie
chart we have about availability. I have
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never encountered a single phone or tablet
that does not have an accelerometer. So if
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anyone ever encountered some special
device, some very unique device that
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doesn't have one. Let me know because I
would be interested in this at least. I do
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not know of any device on which phyphox
actually runs, which doesn't have an
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accelerometer. A bit more interesting is
which data rate we can achieve. So most
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accelerometers have several hundred
samples per second. Actually the fastest
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ones go up to 500 hertz and but there are
also many devices that only do one hundred
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hertz That's 100 values per second. These
are mostly the cheaper Android devices and
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all the iPhones. So I think the internal
accelerometer will do more on an iPhone.
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But I have to admit, at some point I can
understand why they might limit this. But
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on an iPhone, you get 100 hertz. That's
the limit. From the API, what you can get
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there. But this is actually quite a lot. I
will later see what we can do with this.
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And one other point about calibration of
this thing. Actually for all the sensors
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to get reasonable units from the system so
the acceleration is given in meter per
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square second. I just realized that if I
get the units, that's something I would
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really tell my students. But yeah. So on
the x axis, it's a meter per square second
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and you see that as a wide range of values
that you get there. So this data is from
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our sensor database. I would mention it
later as well. This is contribution from
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our users what data there this. This only
absolute value that we get from resting
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phones and we would expect nine point
eight one meter per square second for
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earth acceleration. There are some local
variation, but not on that scale. So do
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not expect your sensors to be well
calibrated. Also, if you've got any app
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that tells you you can push a single
button and then calibrates your sensor,
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don't trust it. It's not that simple.
These sensors may have different errors on
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each axis. They're all 3D sensors we've
got an X, Y and z axis. These errors can
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be linear errors so you have to multiply a
correction. It could be an offset. So it
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would have to add an correction. And on
top of this, the entire device could be
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tilted within your phone. OK. So actually,
if you look into the data sheets of the
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accelerometer, they have some tolerance on
how much they might already be shifted or
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rotated within the package. And when
soldering it into the phone, I would
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assume there will be an additional error.
I've seen so many different errors on
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different phones. It's not that easy to
simply calibrate that. But let me give you
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an example of what you can do with it. Or
just a quick look first. So we see in our
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app. Yeah. So this is phyphox. OK. Thank
you. Got this. You have an entry
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acceleration with G. That's the extra raw
data from the sensor or as raw as we get
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it. If I started you see if I shake it,
you get some readings there. It's fast.
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It's already great. You can apply to
pendulum and measure the acceleration of
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the pendulum like this. But something I
want to demonstrate is that we can also
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get the frequencies from this data by
doing a fourier transform and calculating
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the frequency spectrum of this exploration
data and to demonstrate this I brought a
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little device a old hard disk drive. It says
it's broken, but it's still rotating and
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that's important part for us. So if I
place my phone on top of it, start the
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measurement. Turn on the hard disk drive.
And then you see a peak showing up in the
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spectrum and it settles at 120 hertz. If
you don't believe me. Unfortunately, we
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don't have a camera here right now. You
can later have a look. It's supposed to
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run at seven thousand two hundred RPM,
which is 120 hertz. We can even get a time
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resolution of this. So if I turn it off
again, you see how the frequency drops
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down. And if I turn it on again. There it
comes up again. OK. So this an example of
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what you can do. It's great for students
that can check if the washing machine at
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home is working properly or they can
check other things. But usually I do not
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like to bring washing machines to talks.
So I used the hard disk drive here. One
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other thing you might have noticed before
is that we've actually got acceleration
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with G and acceleration without G. The
second one is actually a sensor that
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removes Earth's gravity. So if I start the
one with G, you will notice that down here
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on the Z, the axis you still have the 9.81
meter per square second, which is great
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because if i rotate the phone. This
contribution goes to other axis and we can
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determine the orientation of the phone.
But this is bad actually for dedactics
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because actually the phone is resting.
It's not moving at all. There's no
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velocity involved. There's no
acceleration. So luckily, there's also an
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acceleration without G, which gives us
roughly 0 an all axis unless I actually
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accelerate this thing. Problem with this
is this is only a virtual sensor. This is
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a sensor that's fusing the data from the
accelerometer with an additional sensor
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like the gyroscope. So we can actually
distinguish between rotating the phone or
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accelerating it in one or the other
direction. Usually you only get
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acceleration without G. If you also have a
gyroscope in your phone, I've seen two or
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three devices that offer you acceleration
without G, even though they don't have a
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gyroscope. This case, don't trust them.
This is merely guessing. OK. So it's. They
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probably have only low frequency filter
on top of this, or they're averaging out
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your movement and this doesn't really work
for anything. Yeah so that's the
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accelerometer or one other thing I want to
mention is if you look into the API to
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access the sensors yourself for some
reason you will notice acceleration
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without G is usually called linear
acceleration in our app since it's made
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for teaching. We decided to call it with
and without G. So if you find
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accelerometer, that's the one with G and
linear acceleration is the one without G.
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If you look at other apps or the API.
Okay. Next up, I already mentioned this
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one is a gyroscope. If you have, some
physics background. Then when you think of
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a gyroscope, you're thinking of a device
that's spinning fast so it has some angular
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momentum and then usually you want it to
be heavy and to have the weight at the
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large radius. We've got a strong moment of
inertia so that you get when it's spinning
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fast, a strong, angular momentum and due
to the conservation of angular momentum.
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These spinning devices can keep an axis
regardless of rotating the frame around
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it. That's what I was thinking about, a
gyroscope of what I think is a gyroscope.
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When you just give me the term out of
context, of course, a heavy, huge, fast
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spinning device is the last thing you want
in your phone. So that's not what's meant
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with the gyroscope when people are talking
about gyroscopes in your phone. Instead
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there again you have a MEMS device. So
again, micro electromechanical system. You
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notice this looks almost exactly like
accelerometer. If you look for real
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devices, those are actually much more
complicated because they need some
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specific geometry to make sure that they
do not act like an accelerometer. But the
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principle is easy to explain with the same
geometry. So we again have this floating
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metallic part and we've got 2 contacts. So
again, we've got a part that can wobble in
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this direction here. But on top of this,
we've got the motion that's perpendicular
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to this. So this is now not depicting the
motion of your phone, but this is
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depicting a vibration that the gyroscope
does by itself all the time. So there are
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different ways to build them. Some have a
rotary motion, some have this linear
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motion. Also, the way to create this
motion makes this device so much more
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complicated. But in principle, it's a
similar structure which is vibrating forth
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and back and now if you add rotation to
it. It's a little bit hard to see it as
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it's rotating the inner part now suddenly
gets deflected. That's changed, right?
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Frame of reference. So let's get the
camera in sync with this device. What you
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now see is that the inner part is moving
left and right, although the device itself
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is only moving up and down. And the reason
is I don't want to deduce it entirely
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here, but most of you probably have heard
of it. This is the Coriolis effect. So,
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yes, in fact, your phone is determining
the rotation rate of your phone, not the
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actual angle, but the rotation rate or
angular velocity due to the coriolis
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effect, which is just mind blowing if you
do some of the calculations. There are
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some manufacturers on the Internet which
claim that they can detect a movement of
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the order of magnitude of a single atom.
And I believe them because we use similar
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structures in solid state physics. So
that's possible. If you want to try it,
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just turn on the gyroscope on your phone.
And do slight rotation like this, which is
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about the Z axis, one perpendicular to the
display, you can detect really slow
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rotations with this. And think about the
fact that this is done using the coriolis
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effect and it's just mind blowing I think.
So this sensor is a bit more available.
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Actually, almost 80 percent of the phones
have them. This has become significantly
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more since Pokémon GO. The reason is
when this game came up, suddenly people
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noticed that there's a device called the
gyroscope. And if it's not present, they
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did not have this AR mode where you can
actually take pictures of the nice cute
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Pokémon and so on. So this is when the
many people noticed it and the
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manufacturers decided, OK, let's just
throw in the gyroscope as well, because
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it's not that expensive, in fact, usually
it's on the same chip as the
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accelerometer. Then they're sold as one
thing it's an IMU - Inertia Measurement
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Unit not important at home, but so it's
quite a common thing. And the sensor rates
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look pretty much the same. You mostly
notice the dip in the 100 hertz regime
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because those are the real cheap phones,
which then also don't have a gyroscope.
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But most of the phones achieve higher
rates. Again, since we were laughing
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before the iPhones also are here again at
the 100 hertz. Wouldn't make sense to have
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the gyroscope faster at this point. Yeah,
but that's it about the gyroscope you've
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seen it in action in the salad spinner.
And that's one of the sensors you do not
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really see that often directly, but were
just mostly there to assist other things
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that you do where you need to get smooth
motion like controlling games, AR . And
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actually removing the Earth's acceleration
from the accelerometer. Next up is a
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magnetometer, which I think is a more
obvious sensor because that's your compass
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in your device. So when you're doing
navigation with a GPS in your car, it's a
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simple thing. GPS gets a position, you get
a sequence of position as you going and
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from the sequence of the positions you
get, the direction you're moving in your
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car and your phone is attached to the
dashboard at least i hope so. So it's
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pointing in the same direction you're
moving, everything's obvious. But if
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you're standing on an open space looking
for not sure a train station or anything
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and you wondering which direction you want
to go from point of view of GPS, it's
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always the same position it doesn't get an
orientation. You need a compass, which is
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the magnetometer. How do we get a compass
on your phone? This is usually a hall
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sensor. A hall sensor is in principle just
a conductor with charge carriers so these
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are the nice shiny white balls here
drifting from one side to the other so
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it's just an electric current. And if you
apply a magnetic field to an electric
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current or to any electric charge, then
there is an effect. You might know from
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school, which is called the lorentz
effect. So there is a charge going one
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direction, you get the magnetic field
perpendicular to this and then the charge
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is deflected into a direction
perpendicular to the flying direction. And
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yeah, that's lorentz effect the older
guys, of you would know it from CRTs. If
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you bring a magnet close to a CRT, the
entire image is messed up due to this
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effect. And that's what we're using in
hall effect sensor or hall sensor you've
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got this electric current and if you bring
a magnetic field close to it, the charge
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carriers are deflected to one side or the
other. And therefore, if you're measuring
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the voltage perpendicular to the flow of
the count, you get. Yeah. You get an extra
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voltage that's proportional to the
magnetic field. That's the hall effect.
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That's how your phone is able to determine
the magnetic field. This one is even more
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common than the gyroscope simply because
it's used for navigation and people start
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to notice if it's not. If it's not present
and they do not get an orientation in the
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navigation software. But the actual rate
of the sensors is much slower than for the
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accelerometer. Most of them are running at
100 Hertz. It will be important in two
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more slides. Besides that, there's not
that much strange about the availability
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of this, but it's extremely sensitive
because it's supposed to measure Earth's
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magnetic field. Earth's magnetic field has
the strength around 50 micro Tesla. This
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is not much actually if ever carried the
magnetic magnet with you. Did you fear of
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some force from the Earth's magnetic
field? Of course, it didn't need to build
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some compass where the needle is floating
on something like this to actually get a
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rotation. It's a very weak field and
that's good news and bad news as well,
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because on one hand, it's very sensitive.
downside is it's very sensitive. Which
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means it saturates very early. If you want
to measure the magnetic field of an actual
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magnet. Don't even try it will saturate
right away. You do not get anything to
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demonstrate how how sensitive this
actually is. I've brought a flashlight, so
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a very simple one. And I switch to a modus
where we've got an s.o.s signal. That's
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coming up, a point in this direction and I
place it next to the magnetometer in my
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phone. And yeah, you see right away so
much of his seeing the lights are pointing
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in this direction. You see the s.o.s
signal popping up in the magnetic field
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reading simply because of the current
going through the LED. So that's what we
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call an Oersted-field. This is just the
typical magnetic field you get from any
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current flowing. So I stop it. We got a nice
SOS signal over there. Three short, three
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long and three short signals. And it's just
coming from this simple flashlight. And
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this is also a good indicator on how
sensitive this thing is. I mean, if you
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place your phone in a case with a magnetic
some magnetic closing mechanism, compass
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wouldn't work anymore. If you're not
careful when paying your clothes and you
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place your phone on the big magnet that
removes the theft protection from the
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clothes, something in your phone would get
magnetized and would certainly be stronger
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than Earth's magnetic field. For the rest
of the day, your compass would be pointing
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in the wrong direction. Okay. Luckily,
usually the phones are able to notice this
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and they recalibrate the phone to simply
subtract any constant fears. That again is
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bad. If you want to do absolute
measurements because you have not much
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control over the recalibration mechanism,
you can access the raw data value. So if
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you folks there's a checkmark where you
can disable the calibration, but then you
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have to do everything by hand. You will
certainly have some background that's
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annoying. And one other thing, you should
also take care and notice where your
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actual magnetometer is because in most
phones it's on top left corner, top right
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corner, top center. And this Pixel 3 is a
very strange one. It has it on the right
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hand side, but it's never dead center. I
think because of all the currents in the
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phone, I mean, you're charging your
battery with three amps. How much you
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charge them now? This would yield a
stronger field than a flashlight and you
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would see it in the magnetometer again.
Now for what you can do with this. So as
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little homework for all of you who came by
train yesterday, when I came here on the
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ICE, I turned on the magnetic spectrum,
the same thing as the acceleration
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spectrum you just seen. And when you're
doing it on train, you would see a peak at
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16.6 hertz. It might depend on your actual
seat. You might move it around a little
-
bit. But so far I usually always saw this
peak. This is the electrification
-
frequency of the German railway. So you
can simply check if it's working properly.
-
You should see 16.7 hertz. Okay. One other
thing that some of you might get in your
-
head right now, that you could do this
with simple electrical outlets. There you
-
would get a problem with the rate. So
that's what I mentioned, that the rate of
-
the sensor is quite important. I also got
something via Twitter yesterday. Just as a
-
response to the other one, I thought,
well, I was looking for an example like
-
this for this talk talk, so I just put it
in. This is a measurement of an American
-
power outlet which is run at 60 hertz. But
this guy is seeing 40 hertz and he was
-
wondering about this. That's what's called
aliasing. So the alias effect, sort of you
-
might notice this from computer games.
They usually use it in slightly different
-
context. The idea is if you're measuring a
frequency that's higher than half of the
-
data acquisition rate of your sensor. So
this one is runningat 100 hertz like most
-
of the phones do. Then half of this
frequency is what's called the Nyquist-
-
frequency. And you notice that the
spectrum goes from zero to the Nyquist-
-
frequency. This is simple math, not simple
math, but its maths. The roots of the
-
fourier-transformation, you could say so.
And if you try to detect a frequency
-
that's higher than this, so an American
power outlet with 60 hertz, actually the
-
higher frequency is showing up as on the
other side of this upper limit at 40
-
hertz, even if you go to a higher
frequency, it would shift down further and
-
further until reaching zero and then it
would shift up again. So if you're
-
interested in this. Check out some
articles about aliasing. If you're not
-
that interested in this. Just keep in
mind, if you're measuring frequencies that
-
are higher than half your data acquisition
rate, you will not see the correct
-
frequency. OK. Then one of my favorite
sensors, the pressure sensor for this one
-
I need. Again, the phone. That's not on a
wire. Let me before before I show
-
anything. Let me demonstrate what it can
do, because that's something I find quite
-
surprising. Let's turn on the measurement.
By the way, those who are wondering how
-
this works. There's a function in phyphox,
we call it remote access. It's basically a
-
web server running in the app which
provides the data so we can simply access
-
the data on the phone to demonstrate or to
control the measurement. And now here we
-
see the pressure sensor. Right now, just
mostly noise or what I do now is I hold it
-
up. And if we wait a few seconds, you
would see that the pressure's actually
-
dropping. It has dropped far enough. Then
I place it on the ground and the pressure
-
is rising again. So actually, your phone,
if it has a pressure sensor, has a
-
pressure sensor that's sensitive enough.
So we turn it off to measure a change of
-
pressure of a distance like this. OK. And
that's again, when I first tried this, I
-
repeated this test several times before,
believed it was just not by accident. And
-
how do they do this? You have got another
device that actually has a cavity. So
-
below the bluish gray part, there's a
cavity in there which is covered by a
-
silicon membrane, which is the bluish
part. And if you change the pressure this
-
simply moves it like you would expect from
a membrane just in small. And to detect
-
this movement, here is some material on
top of this which changes its resistance.
-
Or resistivity depending on the strain
created by morphing, dismembering. And
-
unfortunately, this sensor is not that
much available. So about a third of the
-
devices that we know of have the sensor.
Of course, there's some bias in there from
-
the users that submit data to us. This
means that, yes, these are usually the
-
more expensive devices. So my rule of
thumb is if it's an iPhone, they usually
-
have the pressure sensor except for the
iPhone SE or some older models. If it's an
-
Android, if you payed half as much as you
paid for an iPhone, then you have a good
-
chance that you have to pressure sensor as
well. But OK, that data rates? Yeah.
-
Varies a lot. So the iPhones, like you
just saw the rate of about 1 Hertz. Most
-
Android phones are on five, ten or twenty
five hertz. I've never had a device like
-
this in my hand. It does 100 hertz. I
don't really believe that this makes sense
-
because I already noticed on my phone that
I think it does 25 hertz. Just handing it
-
because of the sealed casing introduces
more noise than you can actually use, at
-
least for these small distances that I use
it for. But you can do other funny things
-
with this. So this is something I received
by Dianna Cowern. You might know her as a
-
YouTuber called "The Physics Girl". She
used a pressure measurement on the flight.
-
It's something you should do anyways,
because that's the way you can figure out
-
how much air you get to breathe up there.
It's much lower than you might expect.
-
But she saw something else. So at some
point she saw the drop in the pressure and
-
increase again. And she asked her
followers, what could this be? And I'm not
-
asking the audience right now. I just give
you the solution. She wasn't lavatory and
-
she flushed the toilet. So when water and
air gets sucked out, you can actually
-
measure this. And then about a month ago,
I found someone else who allowed me to use
-
his measurement. So this guy, Phillip
Smith, was on an airplane again. But he
-
did not actually go to the lavatory. He
stayed on his seat and he just checked
-
when people were flushing the toilet. So
as he sat, there was there were
-
turbulence. So they couldn't go for a
while. And then there was the rush while
-
the toilet and he was plotting it. So just
for those of you that came here by plane,
-
just a hint as a conversation starter next time,
when the guy next to you goes to the toilet and
-
he comes back, tell him exactly all of the
head to flush the toilet and ask him why.
-
Okay. And you would enjoy the rest of the
flight. Some other example that we
-
actually use is measuring the movement of
an elevator. So this is a lift in Aachen.
-
We have the accelometer which measures the
acceleration of this thing, gets the total
-
height difference of the elevator from the
again, from the pressure sensor, a
-
barometer. That's a pressure sensor. And
the velocity of the elevator as well from
-
the change in height. OK, so next time you
enter an elevator, I want to see you all
-
to take out your phones and measure the
distance that the elevator is traveling
-
and the velocity at which it does so. OK.
So these are, in my opinion, most
-
important sensors, some honorable
mentions. Almost all phones have a light
-
sensor as well, which controls the display
brightness depending on the ambient light.
-
Unfortunately, there is no API on IOS
to access this. So if there are apps
-
that seem to access a sensor like this,
they usually use the camera instead, which
-
is which also works quite well. But it's
slightly different since the difference
-
between illuminance and luminance, which I
do not want to go into detail here. And on
-
most Android phones, they are badly
calibrated or do this so much difference
-
in the quality of the sensors. We have to
check it on your own phone if it's worth
-
anything. But it's a bit difficult. This
proximity sensor, which is the one that
-
turns off the screen when you hold the
phone to your ear when you're
-
actually doing your call. Sounds
interesting, but unfortunately it only
-
distinguishes or has I know it
distinguishes between between the near and
-
far value, which is the difference between
five centimeters. So I do not have that
-
much use for it. There is the temperature sensor,
maybe if they are officially there, then
-
they usually come along with the humidity
sensor, but that's the sensors in your
-
phone. So you should be a little bit
skeptical about this. You're mostly
-
measuring the heat from your battery or
from your device. They tried to compensate
-
for this, but that's a difficult thing to
do. So if you actually, one, need a
-
thermometer, take a thermometer. They're
not that expensive. OK. You might see some
-
temperature sensors that are not official.
Which phyphhox can pick up. Those are usually
-
temperature sensors that are part of the
pressure sensor to compensate for
-
temperature effects. So they're not even
designed to get an outside temperature.
-
OK. So I wanted to mention this. While the
information about where we got the
-
information about the sensors from, so in our
App at the very bottom, does this entry
-
submit to a sensor database which tells
you to leave the phone resting on a table?
-
It also checks if you're actually doing
this, doesn't let you submit it before it
-
is happy about the error rate or the
standard deviation of the accelometer. And
-
if you submit it, we collect the data on
phyphox.org/sensordb and that's
-
where I got the statistics from so far. So
if you're interested in what a new phone
-
that you're about to buy can actually do.
Of course we don't give you any guarantee,
-
but you can check up or check out all the
data, all the phones. At least those that
-
are already in our database. And of
course, I'm happy if you contribute
-
statistics about the census in your phone
as well. So you might want to play with
-
this later. And then finally, the last
thing to finally conclude is some
-
information on how you can access the
sensors. Of course you can write your own
-
APP. I think here quite a few who can do
this. Just have a look if you can write an
-
App. Have a look at the API. They're not
too complicated. It's easy to access the
-
sensor data. If you're not interested in
designing your own app, but you want to
-
include sensor data in some other
projects, there are three ways you can use
-
Phyfox for this, which I want to
introduce, because that's something that's
-
one of the reasons I wanted to connect
here. Don't hesitate. Phyfox is free. You
-
can get for free on Google Play and on the
Appstore. And when I say it's free, I mean
-
it's really free. So it's open source. The
GPL and you can also get an afterwards we
-
assured of code running on your phone
is the code that you see. And we have
-
three versions how you can.. At least they
are categorized into three versions. How
-
you can access the sensor data. First
thing is you can implement something in
-
Phyfox yourself. So I've got this editor,
visual editor of all file format, which
-
allows you to take a sensor, place on
mathematics. So this is just adding stuff,
-
but you can apply a Fourier transform or
anything and then assign it to a graph.
-
Alternatively, and of course a bit more
powerful. You can have a look at our XML
-
format, which defines all the experiments.
So actually all experiments to see in
-
Phyfox are not hardcoded, but they are defined
in our own file format you can edit any of
-
them to your needs. And when you're done
you can transfer your data with the QR
-
code. Do not try to scan this QR code just
from your QR code app. You have to scan
-
it from within Phyfox and if you do,
you'll find a nice little experiment which
-
uses our file formats to implement a Turing
machine that's counting binary up to 256.
-
So this is the proof that all file format
actually is Turing complete. So you can do
-
a lot with it. Okay. I'm not suggesting
that you're trying to implement doom on it
-
or something like this because you won't
be able to. It's not efficient that way.
-
It's not designed to be Turing complete.
It just happens to be Turing complete. So
-
if you want to do something more, you can
connect to Phyfox via a network. You've
-
seen one example with the salad spinner.
When I said that there is a
-
a web server running on the App. You can use
this to access the data directly from your
-
preferred programing language. There's an
example where I'm using Python to read out
-
the sensor data and control a synthesizer.
So what's running on the web server is
-
basically a rest API. So yeah. Just visit
our website and learn how to do this. So
-
you can read out the sensor data of a
network and control your project with it.
-
An alternative to this is a new network
interface that we have, which is more on
-
this XML side or the design of our
experiment configurations, which is meant
-
to collect data from many users and not
life data. So we had this lecture. So this is
-
the new lecture hall, by the way. So we
had a lecture where every student got a
-
spring from us and there was supposed to
build a spring pendulum and we collected
-
the data from all students and the lecture
hall in realtime on the big screen to
-
determine the dependency of the frequency
from the mass of the pendulum. And another
-
example. Just a few days ago, we during
the winter solstice, we asked our
-
international users to point their phone
at the sun. So we get an angle for the
-
elevation of the sun and the azimuth from
the magnetometer with a compass. And this
-
way we could trace the path of the sun
across the earth from all the users. What
-
each black point with the line is a
contribution from a user. So, yeah, from
-
this we could, for example, determine the
tilted angle of the earth's axis. OK, so
-
just example, what you can do is this
network interface, as long as we're able
-
to set up some server to receive the data,
you can use this network interface. We're
-
still working on this network interface.
So far it can only do HTTP requests, get
-
or post. But we are also planning on
implementing Mqtt and other protocols like
-
this. And the third option is a Bluetooth
connection, which is mostly designed for
-
sensors. So if you want. If you have some
Bluetooth low energy sensor that you want
-
to read out, you can use Phyfox. So
there's an example of a Texas Instruments
-
sensor tech, which has a software which is
not designed for Phyfox. But our file
-
format is flexible enough to
simply tell Phyfox how to read all the
-
data and suddenly we've got the sensor
that can run independently from the phone.
-
And of course you can include your own
projects like this. So there is an example from
-
actually my institute, because originally I'm in
solid state physicist. So we're working a
-
lot with graphene and this is a
demonstrated we create that was an ESP 32.
-
So this is another version of an Arduino, or
Arduino compatibel. What we're doing here.
-
We're reading out a graphene Hallsensor
and so. It's all similar to the holecenter
-
of phone, but based on graphene and we can
get life measurements in Phyfox with this.
-
And so if you have an Arduino project with
which you want to.. from which you want
-
to send data that is plotted in Phyfox,
you can do it with a bluetooth low
-
energy interface. But if you have some
patients and maybe wait two more months,
-
we are working on Arduino library to make
this simpler. So this the entire code, you
-
would need to read out the analog input
from an Arduino and send it to Phyfox to
-
be plotted. OK, so this is working right
now. If you cannot wait, you can check it
-
out on our website. So this is already
available, although it's a work in
-
progress. The interface will change a bit
still. I would prefer if you want to
-
start right now, if you contact me so we
can get some feedback and maybe even
-
design the library also to your needs. So that
we get an idea. So with this, I'm about to
-
finish. So just a short summary what I'm
hoping I can trigger. Yeah. So if you were
-
mildly amused, mightily entertained by
this by this talk, check out our Web site
-
or check out our YouTube channel or
Twitter. We can get some more examples,
-
what we do with the sensors in the phone.
If you are a teacher, are teachers here?
-
Quite a few. That's great! And if you want
to use this in class or in a lecture,
-
check out our Web site phyfox.org. We've
got a database of experiments that you can
-
do: phyfox.org/experiments .That's then
actually about physics and less about the
-
hardware where we also demonstrate the
experiments and how they work. If you are
-
a teacher and has a specific project in
mind. Check out our editor to design your
-
own set up with which you can do something
specific for a very specific experiment.
-
phyfox.org/editor. Then if you are working
on arduino project and want to plot
-
something, you can visit Phyfox.org/arduino,
where you already can access
-
our library. Although it's not complete as
I said. So maybe wait a little bit or
-
contact me first. If you have a Bluetooth
low energy device that you want to use or
-
integrate. You can visit phyfox.org/ble.
If it's about a device that you did not
-
design yourself, you probably need some
background information about bluetooth low
-
energy. Should know what a GATT server is
and how characteristics and services, new
-
ideas and all this stuff and bluetooth
energy works. And it's good to get some
-
documentation or to be good as reverse
engineering, but in principle I haven't
-
seen many devices so far which could not
work with phyfox easily. Then if you want
-
to read the values for another project via
network, visit our website, the wiki on
-
our website. phyfox.org/wiki, where you
can get information about the rest API and
-
on your network interface. And finally,
something I would really love if you want
-
to contribute. If you can write some apps,
I mean you can use a lot of things. The iOS
-
app is written in swift. The Android
version is written in Java. Our webserver,
-
of course, has web development and Html in
JavaScript. So if you want to contribute
-
there. Visit our Web site at a
phyfox.org/source. And we would love to
-
see some help in development. With this I
finish my talk and I'm looking forward to
-
any exchange we will have later and any
questions. And I'm just thankful that it
-
was allowed to talk here and
get so much attention. Thank you.
-
Applause
-
Oh, by the way, since it is up there. One
bad news, unfortunately, I can only be
-
here today. So if you want to talk to me,
try to catch me today. You can also call
-
me. I actually brought a DECT phone,
but, uh, sorry, only today.
-
Herald: Oh, my God. So quickly, though, we
have questions now, 15 minutes, then 15
-
minutes, I think. And then afterwards, you
have to find him and catch him. Thank you,
-
Sebastian. Questions. Shoot. There is one.
Question: You mentioned aliasing affect
-
during.. Is it possible to change or modulate
the sampling frequency to actually find
-
out our frequency above the sampling frequency?
Sebastian: Yeah, that's that's a good
-
question. Not only because of the of the
alias affect, but also because some
-
projects also want to reduce the sampling
frequency. It's a little bit tricky
-
because on both APIs and both IOS and
Android, you cannot specify a target
-
frequency, you can only specify a
frequency that specific for certain use
-
case. So for example, you say I need the
accelerometer data, that's which at a rate
-
that's reasonable for UI changes or at a
rate that's reasonable for games. Right.
-
Right. That's as fast as possible. So if
you do it for UI, you get something like
-
let's say two three hertz. We heard something like
this or you doesn't waiting ages before
-
the screen rotates for games. It's 25 50
hertz something like this. So we can
-
control the game and fastest is the
data I've just plotted. And Phyfox always
-
request the fastest we can see and in
Phyfox we have a setting, we can limit the
-
frequency. Unfortunately, if your
frequency is not simply a multiple, no,
-
the other way around is. The frequency
given by the device, is not a multiple of the
-
frequency that you gave. It's not easy to
break it down to the target frequency. So
-
you usually see some odd cases where
Phyfox tells to group the sensor events
-
along this to get near this frequency. So
it might not work that well. And
-
especially if you're looking for the alias
effect. This might really mess up their
-
alias effect, so you might need to try a
little bit which frequency looks good to
-
do this. But of course in principle you
can average about multiple values in this
-
way or simply pick only every end value.
And this way we'd use the frequency. And
-
yeah, this can be done to our editor or to
the main screen. There's a plus button
-
with which you can simply expand which
already allows you to set this simple
-
frequency. Just keep in mind that you
cannot really always get to the
-
target frequency, right?
Herald: Right. There is another question.
-
No? Yes. Please.
Question: Hi. Thanks for the cool task.
-
It's a great app. I love using it in
school. I was wondering if those cool
-
animations how to sensor types of working
are available.
-
Sebastian: Sorry. The animation scene.
Yeah. I think I wonder how to do this
-
best. Before that, I was already thinking
about sharing the slides. Actually, my
-
talk is space it's just written in HTML in Javascript
it's not easy to control for everyone. That's
-
why I did not simply upload it. I would if
I would check later, if I can, upload the entire
-
talk in some way that makes sense either
on our website. I'm not sure if it makes
-
sense to upload it to the system of the
conference. Still, after the talk, I would
-
check it, but I am not... I want to share
the slides, but I probably need to add
-
some documentation on how to use them
because they are not Power point PDF or
-
Latex generated PDF.
It's handmade.
-
Herald: You can always cut them out of the
video getting streamed and La la la la la.
-
Yeah, right.
Question: Just a quick question of the the
-
axis of the phone. They're like like that
and that distorts us.
-
Sebastian: So it's not for most phones.
The X-axis is reading directlon. The
-
Y-axis is upwards along the screen and Z
access, Z-axis depending on your dialect is
-
perpendicular to the screen. I'd say in
most cases because officially the X-Axis
-
at least I think I've written this
documentation for Android is along the
-
natural reading direction of the device.
So if you've got a huge tablet which you
-
naturally would put in horizontal
alignment, not portrait mode, it might be
-
that the X-Axis is the long Axis. I have never
seen this myself, but I'm a little bit
-
careful to say that all these devices have
the same axis, but Z is definitely always
-
perpendicular to the screen and X and Y are
than the other ones and they are fixed and
-
usually the short side is the X-Axis.
Herald: Ok. There is one more question
-
there, please, sir. Take the microphone.
It's next to you. You got it off the
-
...
Question: Hi, you mentioned the necessity
-
of the magnetic sensor to to determine the
content orientation. Can you not use past
-
G.P.S. data and then integrate over the
gyroscope data to get the current
-
orientation?
Sebastian: Lauthing Mathematically, your
-
correct, problem is integrating sensor
data is not as simple. I'm often
-
surprised on what some software
can actually do. If you do it naively
-
right now I only have an example in mind
for the accelerometer cause it could also
-
say you can integrate the accelometer data
to get velocity. You can integrate the
-
velocity to get the displacement of the
phone of the location. If you do this,
-
we've got a very simple example in our
wiki. Very naiv even one without any
-
filtering, then just the noise means
that's if there's little arrow, you summit
-
up integrations, nothing else but
suming up in small steps. You get an
-
offset error in the velocity. If you
integrate this again, you get an error in
-
the location with which is growing with
the square of the time. So if you do this
-
for location and try it out with our naive
approach your phone is supposed to
-
be 100 meters upwards after about 10
seconds. If you do this for the gyroscope,
-
it's a little easier because you only
want integration. But still there will be
-
some drift. I'm not sure about all the
techniques the manufacturers imployed to
-
filter out any errors. I mean, obviously
the gyroscope is self calibrating
-
otherwise, it would be pointing in
different direction all the time. And on
-
some phones I've seen it jumping
when it recalibrates. But if you simply
-
integrate this, you will certainly get
drift, there's no way that you can get
-
a fixed position. What I think what they
probably do for most cases, they use the
-
gyroscope to immediate direct
rotation and then try to fuze it
-
in some way with the magnetometer
information to keep it fixed so that at
-
the end you're not pointing the wrong
direction. But the gyroscope itself, only
-
on its own, is unfortunately only giving
you the rotation rate, not the absolute
-
rotation in contrast to an actual
gyroscope. The big one that's rotating. So
-
it's at least not that easy.
That's all I can say.
-
Herald. Whow? What the bunch of
information, Sebastian? I really love the
-
.... There is someone else with a
question. I really love your replication.
-
Actually, it was really immediately fun
to, go.
-
Question: Thank you so much for a great
application. And my question is, just very
-
short. Can you also integrate external
sensors through Wi-Fi or is it only to be
-
early?
Sebastian: No. That's what I meant with
-
the network connection. Network usually
has Wi-Fi in this case, I'm not sure if it
-
would work on a conference like this into
the cable. So now you can get the data
-
through our REST API. Might not be the
fastest thing. Maybe we will add to our
-
network, our new network functionality,
something that will keep open apart and
-
push the data in there, so far the best
thing to go is with our rest API.
-
Question: I was just thinking about the
external sensor connection.
-
Sebastian: So external? Sorry, I was
thinking a different direction. Actually,
-
that's a good question. That reminds me of
that, that there's something I wanted to
-
add. You can use the REST API in theory to
push data in there, but that's only a
-
parameter in the Url. It's simple a Get/
push off a single value which doesn't get
-
get you far and which is quite
inefficient. However, within you network
-
interface you can do requests to other
devices so you can GET request and already
-
is able to respa Json packet as a
response us to interpret the adjacent
-
packet as a response. And that's where
adding Mqtt and stuff like this, this is
-
supposed to go in both directions. But
this is really new. So if you've got
-
something specific, try if it works or
contact me if it's not working, if you
-
need some help, if you find the bug. So but
it's supposed to work on your network
-
stuff. That's there in the configuration. So
the idea of the workflow of all this
-
connection with specific devices have
something set up like this. You create a
-
configuration for Phyfox, which in the end
is supplied to the QR code. For example,
-
the user scans the QR code. And this all
the information, how to communicate with
-
the device is already supplied. You can
also do this for Bluetooth. That the
-
device itself provides it to Phyphox.
But in the end it's these configurations
-
and for the new network interface, it can
also receive data from the network. But so
-
far only via HTTP.
Question: OK. Thank you.
-
Herald: I have maybe a last question if no
one else has. What's the next step? What
-
is your next goal? Because this is a
tremendous successful thing. And you see
-
the educational purposes. So that's
fantastic, actually, isn't it? It's not
-
only on university level if you're using
it, that's all around in Germany.
-
Sebastian: That's not in Germany. It's by
the way another thing you could
-
contribute. If you're speaking a language
that has been translated into Phyfox is
-
translated by volunteers and it's already
available, I think in 2010 and 2012, 2013,
-
14 languages, something around this. So
yeah, but next step I think will be using
-
the camera because that's another sensor,
broadly speaking, which we are not using
-
at all, which can do a lot, but we haven't
yet started on this. So lot to do in this
-
project.
Herald: Super. I'm looking forward to see
-
you next year then. Laughing, Applause
Sebastian Starks, thank you very much. An
-
honor and a pleasure to have you.
-
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