The simple, clever sensor behind automatic windshield wipers
Summary
TLDRThe video script explains the technology behind automatic windshield wipers in vehicles. It clarifies that the wipers are not controlled by a camera, but by a rain sensor located near the top center of the windshield. The sensor uses infrared LEDs and photodiodes to detect light reflected from the glass. When the windshield gets wet, the refraction of light changes, affecting the signal received by the photodiode. This change in signal intensity is used to measure the wetness of the windshield and activate the wipers accordingly. The script also humorously discusses the manual calibration process of the sensor and the importance of referring to the car's manual for troubleshooting. The video concludes with a reminder that simple components can achieve complex tasks and the value of consulting manuals for guidance.
Takeaways
- 🚗 Automatic windshield wipers in cars are activated by a rain sensor, not a camera, to avoid overloading the car's computer vision system.
- 🔍 The rain sensor is located near the top center of the windshield and is typically black, housing an infrared LED and a photodiode.
- 💡 The sensor works by using infrared LEDs that emit light towards the glass, which is then detected by a photodiode.
- 🌧️ Wetness is detected when water on the glass alters the refraction of light, breaking the total internal reflection and reducing the signal received by the photodiode.
- 📉 As the windshield gets wetter, the signal to the photodiode diminishes, which triggers the wipers to activate and increase their frequency.
- 🤖 The sensor needs to calibrate a baseline 'dry' signal level every time it powers up, adjusting for different starting conditions.
- 🔄 The system compensates for inconsistencies in wetness by employing two sensor assemblies, which compare signals to determine the wetness state.
- 🛠️ Manual adjustments can be made to the sensitivity of the wipers through a control on the wiper stalk to suit driver preferences.
- 📚 The importance of reading manuals is emphasized, as they contain valuable information that can help avoid frustration and guesswork.
- 👍 The simplicity and effectiveness of using basic electronic components like LEDs and photodiodes to achieve complex tasks is highlighted.
- 😅 The video humorously addresses the challenges of changing wiper blades and the need to find the right procedure in the car's manual.
- 🎵 The video concludes with a reminder that sometimes, simple solutions and reading manuals can save time and effort, wrapped up with a touch of humor and smooth jazz.
Q & A
How do automatic windshield wipers in a car detect when it's wet?
-They use a rain sensor that consists of infrared LEDs and photodiodes. The LEDs shine light onto the windshield, and the photodiodes detect the light. When the windshield gets wet, the refraction of light changes, which alters the signal received by the photodiode, indicating wetness.
What is the role of the black area near the top center of the windshield?
-The black area houses the rain sensor, which is responsible for detecting wetness on the windshield and activating the automatic wipers.
Why is it not ideal to use a camera for detecting windshield wetness?
-Using a camera would divert valuable computational resources from other critical tasks like computer vision, which is used for features like lane keeping assistance. Additionally, it might not be as effective or efficient as the current sensor technology.
How does the rain sensor work in conjunction with the windshield wipers?
-The rain sensor monitors the signal from the LEDs. When the signal diminishes due to wetness, the sensor triggers the wiper motor to activate. The sensor is also placed in the path of the wipers to allow for continuous calibration.
What is the purpose of the ambient light sensor in the same assembly as the rain sensor?
-The ambient light sensor controls the car's headlights automatically, adjusting them based on the surrounding light conditions.
How does the rain sensor leverage the concept of total internal reflection?
-The rain sensor uses infrared LEDs shining at an angle just below the critical angle for total internal reflection. When the windshield is dry, the light is reflected back towards the photodiode. When the windshield is wet, the change in refraction index disrupts this reflection, reducing the signal to the photodiode.
What happens when the windshield is wet and how does it affect the rain sensor's operation?
-When the windshield is wet, the refraction angle changes due to the different refractive index of water compared to air. This causes some of the light to escape through the wet surface rather than being reflected back to the photodiode, resulting in a diminished signal that triggers the wipers.
Why are there two sensor assemblies under the windshield?
-Having two sensor assemblies allows for a more accurate detection of wetness. If there's a difference in the signals from the two sensors, it indicates that the windshield is wet, providing a more reliable trigger for the wipers.
How does the automatic wiper system calibrate its baseline signal level for dry conditions?
-Each time the sensor powers up, it establishes a baseline signal level that it considers 'dry.' If the windshield is already wet when the car is turned on, the sensor starts with a lower signal level and adjusts its calibration after the first wipe.
What is the user's recommendation for adjusting the sensitivity of the automatic wipers?
-The user recommends using the sensitivity adjustment on the wiper stalk to fine-tune the wipers' behavior according to personal preference.
What is the user's opinion on the manual controls for windshield wipers in cars?
-The user appreciates the manual controls, known as stalks, as they are always within reach and allow muscle memory to take over, providing a quick and convenient way to activate the wipers when needed.
What lesson does the user take away from their experience with the automatic wiper system?
-The user emphasizes the importance of reading the manual for any device or system, as it contains valuable information that can help in understanding and effectively using the technology.
Outlines
🚗 Automatic Windshield Wipers Explained
This paragraph explains the technology behind automatic windshield wipers in cars. It clarifies that the car doesn't use a camera to detect rain, but rather a rain sensor located near the top center of the windshield. The rain sensor consists of infrared LEDs and photodiodes working together to detect the presence of water on the windshield. The sensor operates on the principle of total internal reflection, where water changes the refraction angle, thus affecting the light signal received by the photodiode. The paragraph also includes a demonstration using a laser pointer and a piece of glass to illustrate the concept of refraction and how the sensor uses this principle to detect rain.
💡 How the Rain Sensor Works
This paragraph delves deeper into the functioning of the rain sensor. It describes how the sensor uses infrared LEDs and photodiodes to create a modulated signal that changes in intensity when the windshield becomes wet. The change in refraction due to water on the glass disrupts the total internal reflection, causing some light to escape and reducing the signal received by the photodiode. This change in signal intensity is used to measure the wetness of the windshield and control the automatic wipers. The paragraph also mentions the sensor's calibration process and the presence of two sensor assemblies for increased accuracy. It touches on the imperfections of the system and the manual adjustments available to the driver.
📚 The Importance of Manuals and Simple Components
The final paragraph reflects on the importance of reading manuals and the power of simple components in technology. It humorously recounts the speaker's struggle to change the car's wiper blades and the discovery of the correct procedure in the owner's manual. The speaker emphasizes the value of the information contained within manuals and encourages viewers not to overlook them. Additionally, the paragraph highlights that software is not the only key to innovation and that simple components can be used in clever ways to solve complex problems, as demonstrated by the rain sensor technology.
Mindmap
Keywords
💡Automatic Windshield Wipers
💡Rain Sensor
💡Total Internal Reflection
💡Refraction
💡Photodiodes
💡Infrared LEDs
💡Ambient Light Sensor
💡Signal Modulation
💡Critical Angle
💡Calibration
💡Dual Sensor Assemblies
Highlights
Automatic windshield wipers in cars are triggered by a rain sensor, which is a simple yet effective technology.
The rain sensor is located near the top center of the windshield, often appearing as a black area.
Contrary to common belief, the camera is not used to detect wetness; instead, a rain sensor does the job.
The rain sensor uses infrared LEDs and photodiodes to detect changes in light reflection caused by water on the windshield.
Total internal reflection is a key principle exploited by the rain sensor to detect changes in light due to rain.
The sensor is calibrated to determine a baseline 'dry' signal level and adjusts its response based on the change in signal.
Having two sensor assemblies improves the accuracy of wetness detection by comparing signals from both sensors.
The sensor is strategically placed in the path of the wipers to ensure clear readings and effective wiping.
The system can adjust the frequency of the wiper operation based on the rate of signal drop, correlating to the intensity of rain.
Calibration is important for the sensor to accurately measure the 'dry' state and respond correctly to wet conditions.
The presence of two sensors allows for immediate detection of wetness by comparing the signals from both, accounting for uneven distribution of water.
The simplicity of the rain sensor, composed of just an LED, a photodiode, and adhesive, showcases the power of basic electronic components.
Despite being a reliable technology, automatic wipers may not always perfectly adjust to the rain conditions and may require manual adjustment.
The video emphasizes the importance of reading manuals for understanding the proper procedures and functionalities of devices.
The presenter humorously discusses their experience with changing wiper blades and the process required to do so.
The moral of the video is to not underestimate the capabilities of simple components and to always consult the manual for guidance.
The technology behind rain sensors has been available since the nineties, highlighting the long-standing effectiveness of this innovation.
Transcripts
[ambient noise]
My car knows when it’s wet.
That’s right, it’s got automatic windshield wipers.
When they’re set to automatic, and the car gets wet, they wipe.
How it know that?
It’s actually really simple.
If you look at the windshield,
you’ll notice an area near the top center which is black.
And if you look closelier you’ll see the component the car uses to determine windshield wetness.
Oh, the camera?
No, it's not the camera - that’d be silly!
Then you’d have to devote some precious clock cycles away from the already wildly complicated computer vision tasks
which help keep the car centered in its lane.
That seems like a weird decision
and I don’t even know how well that could possibly work no matter how many software updates you throw at it.
No, I’m not alluding to anything specific, why on Earth would you think that?
Right above that camera which looks forward at the road you’ll see a little circular spot with some spots within the spot and that, viewers,
is the rain sensor.
Look, I get it wet - and the car wipes!
But two can play at that game.
You may think this is wildly complicated and expensive technology
but actually it’s just two of the simplest electronic components you can imagine working together in a very clever way.
Below the dark portions of the rain sensor are infrared LEDs shining light up into the glass,
and adjacent to them are photodiodes which detect that light.
Now, that bright spot at the bottom?
That’s not actually part of the rain sensor.
It’s an ambient light sensor used to control the car’s headlights automatically.
The two components just live in the same assembly.
The parts that make up the rain sensor aren’t really visible
because they’re below a filter which blocks visible light and thus it appears black to our eyes.
That’s strange, didn’t we just encounter that with stovetops?
Weird connections happening lately.
To demonstrate how that detects rain, I’ll use a piece of glass and a laser pointer.
If I shine the laser up at the glass at about a 45 degree angle,
you’ll notice that a spot of laser light is reflected back down towards the table.
I’ll put a piece of paper there to make it more visible.
Now watch what happens when I get the glass wet.
Not a whole lot.
That’s a bummer.
Ah, but this isn’t actually an accurate demonstration of the principles involved in the rain sensor.
Rather than look at the light reflected back downward by the glass,
let’s look at the spot produced above the glass by the laser light which makes it through.
Now watch closely.
Did you see that? It moved.
That happened because the water on top of the glass changed the angle of refraction as light left the glass.
Now, like some politicians, I’m really not really good at the whole optics thing
so I’m not getting too deep into the weeds here.
But as light passes from one medium to another, its speed actually changes
and because of… reasons that means it appears to change direction.
That concept is known as refraction.
And the refraction index of water is different from that of air.
That means the change in speed and thus change in refraction angle is different between light passing from glass into air and light passing from glass into water.
The rain sensor, though, is entirely under the glass
so it’s not as if it can directly detect that change.
Instead, it leverages the effect of total internal reflection.
If you’ve ever gone swimming in a pool with goggles on and looked up at the surface of the water while submerged,
you may have noticed that it looks like a mirror from shallow angles.
Here’s some stock footage to illustrate.
That’s total internal reflection at work - the water directly above you transmits light just fine and you can see through it,
but there’s a critical angle at which the air-water interface will reflect all light back down
and since it’s smooth like glass, it looks like a mirror.
So now - how can the rain sensor take advantage of that?
Well, first, since the module isn’t part of the glass,
we need an optical interface material to couple the sensor to the glass and remove the air-to-glass optical interface on the bottom.
That takes the form of a sticky gel which, now that it’s in-place, you can’t see.
Which, really, is the point - when it’s doing its job,
the sensor and the glass become one
(from an optical perspective).
Now the key is that the infrared LEDs that we talked about earlier
are shining up at the glass just shallow of the critical angle of total internal reflection.
So, all the light they produce will simply bounce off the top surface of the the glass and head back downward.
And, at the other end of that beam of light, is a photodiode.
That will then detect the light being generated by the LED.
And to make sure it’s detecting that light and not something else,
the LEDs are actually rapidly blinking and the photodiode is looking for that pattern of blinks.
That’s a simpler way of saying the LEDs are producing a specific modulated signal that the photodiode is tuned to detect.
But because the angle between the photodiode and the LED is so close to the critical angle of total internal reflection,
if conditions should change the intensity of that signal being received by the photodiode will also change.
What condition?
Condition wet.
Water on the glass, as we saw in the earlier demo, changes the refraction angle because its refractive index is different from air.
And it will change it just enough to break the effect of total internal reflection.
Wet glass will allow some of the light produced by the LEDs to actually escape and be transmitted through to the outside surface.
Which in turn means there’s less light bouncing down to the photodiode to be detected,
so the signal it was receiving begins to diminish.
And, with a little logic circuitry and programming, you can use that loss of signal as a measurement of windshield wetness.
And honestly… that’s it!
It’s that simple.
The sensor starts to see the signal from the LED drop out so it says to the windshield wiper motor -
wipe.
And the wetter the glass, the more the signal drops, so the more it wipes.
And you’ll notice the sensor is deliberately placed in the path of the windshield wipers so they clear the glass with every wipe.
That allows the logic to get some sense of how hard it might be raining based on how quickly the signal drops out after every wiping event.
The only other complexity here is calibration.
Every time the sensor powers up, it’s got to pick a baseline signal level which it deems “dry.”
Yet, if you are out and about in the rain and you turn your car on with the windshield already wet,
it’s going to start out with some lower signal level than typical.
So, somebody smarter than me probably established a minimum signal dropout level which always causes a wipe,
and in fact I’m certain I’ve encountered the car do a single wipe after turning it on
when it didn’t really need to.
But then it can reset its calibration after that wiping event.
And, there’s another trick up its sleeve, and it's my very favorite one:
having two of them.
There are actually two sensor assemblies under here.
You can barely make out the infrared light in this smartphone camera footage.
You'll see there's two spots.
If the windshield is dry, the two sensors should see very similar signals
but if there’s even just a tiny bit of water on top of one of them, or differing amounts between the two,
then the two signals will be very different and it will know immediately that the windshield is wet.
Which calibration method is it actually using?
I do not know.
And if you’ve never lived with a car with automatic wipers, you may wish to know they are great but not exactly perfect.
You are afforded a sensitivity adjustment on the wiper stalk, so you can fine-tune its behavior to your liking.
But while the wipers pretty much always come on when they need to,
sometimes they go absolutely nuts when it’s barely raining or they get a little lazy in a sudden downpour.
Lucky for me, if that happens all I have to do is just slap this stalk which is right next to my hand on the steering wheel
and the wipers will come on full-steam!
Handy user interface, those stalks.
They’re always there and muscle memory takes over!
I’m pro-stalks, is what I’m saying. It’s a good idea.
What’s less of a good idea, though, is the Konami-code like trick I had to look up just to change my car’s wiper blades.
The hood blocks you from lifting the wiper arms so you need them to stop in the up position in order to change them.
and despite digging through all the settings menus I couldn’t find a “change wipers” option.
So I tried just switching the car off with the wipers in the up position, y'know just time it right, using the power button,
but it outsmarted me and parked them anyway.
It turns out what you have to do is turn the car off and then hold the wiper stalk up in the mist position for a few moments
and then the car will do this.
Is this procedure in the owner’s manual?
Yes, but who looks there for information?
I usually like to end my videos with something akin to a moral.
In that vein, the first lesson today is for me
and that is to read the freaking manual!
There’s even an index in here and finding the appropriate information would have taken me mere moments.
People worked hard on this thing and I just… completely ignored it!
So don’t ignore the manuals in your life.
And the second moral is…
don’t ignore what you can do with a few simple components.
Software isn’t everything.
That’s not directed at any organization in particular, mind you.
Just something to keep in mind.
Did I get to 10 minutes yet?
♫ internally smooth jazz ♫
Thanks, by the way, to Jason, a supporter on Patreon, for recommending this video topic.
That happened a long time ago and I’m pretty certain at least one other person has suggested this in the meantime
so if I forgot who you were, I’m sorry.
There’s just too many bimetallic strips getting in the way.
That’s right, it’s got automatic… the thing didn’t start.
You’ll notice that the spot of laser light is re… oh.
…conditions should change, the intensity of a-
Ooh, I needed a comma for my sake
...critical angle of total internal reflection
[annoyance at outside noise]
...it’s got to pick a baseline signal lever.
Signal.
Level.
...had to look, oh yeah I forgo ohyeahIgottagetthething!
You mean to say all you need is an LED, a photodiode, and a bit of adhesive to take the task of detecting rain away from a sophisticated computer vision system?
And that this was a technology available back in the nineties?
That sounds unpossible, I mean if there were a better way to do things, surely it would only come from the halls of one particular company and not anyone else.
This section is usually for puns but today I chose vicious sarcasm.
Not directed at any particular organization, of course :)
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