Flowing Forward: The Impact of IoT on Plumbing
The intersection between the Internet of Things (IoT) and artificial intelligence (AI) is transforming homes into smart ecosystems where connected devices communicate and automate tasks to enhance convenience. That smart evolution is coming to plumbing as well.
IoT is reshaping the plumbing industry, bringing forth a wave of innovative solutions for homeowners just in time for the winter season. Here, we’ll explore how manufacturers are implementing these technologies in plumbing, their benefits, and the problems they solve. Additionally, we’ll highlight some cutting-edge smart devices and sensors leading the charge in this transformative journey.
Leak Detection and Prevention
Water damage is one of the most common causes of home insurance claims and affects about 14,000 people a day in the United States1. Undetected leaks can lead to a host of problems for homeowners, including water damage, mold, higher water bills, and electrical damage.
Manufacturers are building IoT-enabled smart water leak detectors to identify leaks before they cause substantial damage. Moen’s Smart Leak Detector, chosen by Wired magazine as the best overall water leak detector2, is a standalone sensor that homeowners can place anywhere indoors3. When the device detects the presence of water, high humidity, or extreme temperatures, it will send push notifications to the homeowner by phone, email, or text. The device, shaped like a drop of water, can be configured through an iOS or Android app and chained together with two other devices to cover large areas and prevent potential disasters.
Prescriptive Maintenance
Appliances, including water heaters, may fail unexpectedly, disrupting daily life. Almost all homes in the United States have water heaters, and 27 million households have water heaters that are more than 10 years old and nearing the end of their functional lives4. Property damages from leaking or burst water heaters can add $1,500 to the $3,000 price tag for water heater replacements.
Manufacturers like V-Guard are integrating AI into water heaters to allow predictive performance analysis, enabling prescriptive maintenance that can identify issues before they become critical5. Their IoT-enabled, smartphone-compatible Verano water heater runs self-diagnostics to detect problems and alert homeowners with automated messages about maintenance issues. Verano also continuously monitors the water temperature and sends alerts when it rises above set levels. Homeowners can operate Verano anywhere in the world with the V-Guard Smart App, enabling scheduling for showers or automated cut-offs when water temperatures rise above a set level.
Water Quality
Americans drink about a billion glasses of water a day, and 58% worry about the safety of their drinking water6. Although the drinking water in the United States is among the safest in the world, contamination—such as in Flint, Michigan—does occur.
Kohler has designed its Aquifer Refine water purification system to sit under a home’s kitchen faucet and improve water quality7. It features a three-stage filtration system to filter out mercury, lead, chlorine, certain pharmaceuticals, viruses, and bacteria. Wi-Fi connectivity allows homeowners to monitor their water usage, filter life, and receive alerts about potential leaks. The system also connects to Amazon’s Alexa, enabling homeowners to automatically order new filters when the current filter life reaches 10%.
Outlook for IoT and Plumbing
These examples of integrating IoT and AI into plumbing systems are just a few of the devices currently enhancing the lives of homeowners. As technology continues to advance, we can anticipate the following:
Enhanced energy efficiency that uses AI algorithms will further optimize water heating and usage, contributing to more sustainable and eco-friendly homes. Wider adoption of smart devices will make them more affordable, making smart plumbing solutions commonplace in households. And plumbing systems will seamlessly integrate with other smart home devices, creating comprehensive ecosystems that enhance overall convenience and efficiency.
Smart devices are transforming residential plumbing into dynamic, responsive, and intelligent home systems. As manufacturers continue to innovate, the outlook for IoT and plumbing is undoubtedly one of continued growth and increased integration into the fabric of modern living.
How Ambiq is Contributing
Smart sensors or devices that connect to in-home appliances and send data-based information about plumbing and energy usage will require continuous monitoring and a long-lasting battery so as not to fail when it is needed the most.
Ambiq makes a wide range of system-on-chips (SoCs) capable of processing complex data at ultra-low powers for key technologies, giving developers the flexibility to make intuitive monitoring devices consumers can rely on. It uses the patented Subthreshold Power Optimized Technology (SPOT®) platform to reduce the total system power consumption of all battery-powered endpoint devices. The result is a smart home that connects to all your devices.
Sources:
1 Water Damage Statistics and Information | 2023
2 The 6 Best Water Leak Detectors for Your Home | September 18, 2023
3 Moen | 2023
4 What causes a water heater to leak or rupture? | November 30, 2017
5 V-Guard | 2023
6 Water Quality Facts and Stats | 2023
7 Kohler | 2023
As the coldest months approach, learning more about how new technology can keep people safer in harsh conditions becomes more important and relevant. Thanks to the Internet of Things (IoT), wearable devices can potentially keep people safe and even warm from the adverse effects of winter, including extreme temperatures, storms, icy conditions, and more. Especially for people who work outside during the winter or travel long distances, wearable IoT devices and technology are an attractive and affordable safety solution for winter conditions.
Since 1979, more than 19,000 Americans have died from cold-related causes, including cardiovascular diseases, respiratory viruses1, hypothermia, and frostbite. As fitness trackers and smartwatches become smaller, more affordable, and more energy-efficient, they become viable options for continuously monitoring vitals, temperatures, locations, and other safety-related stats during winter.
How Wearables Keep People Safe in Winter
Wearables are designed to monitor movement, alert potential dangerous changing conditions, and track vitals like body temperature, heart rate, oxygen, and more. However, in the winter, they take on another role, monitoring external environments and conditions. Individuals become more prone to accidents, such as stepping on slippery ice or getting lost in a snowstorm. Wearables can offer life-saving features that notify care teams of your location. Wearables help keep people safer, and winter is no exception.
Smart Clothing
Temperatures can quickly drop in the winter, and these rapidly changing conditions can be dangerous, especially in storms. Your best defense against the cold outside is ensuring you’re wearing warm clothing, with some manufacturers taking it a step further with embedded temperature sensors in smart clothing that adapt to the weather.
Ministry of Supply is a Boston-based clothing company founded by three MIT students who created a smart heated jacket called the Mercury 2. The Mercury uses an internal and external thermometer and an accelerometer that measures temperature and movement. It then sends this information to heated pads that can warm the jacket up to 135ºF/57ºC – about the same temperature as a cup of coffee. It uses AI to detect a user’s preference, ensuring temperatures are always perfect, and connects to your Alexa so you can warm it up before you leave the house.
Location Tracking
One of the best uses of wearables for safety is through GPS and location tracking. It’s not uncommon to get stranded somewhere due to snow during winter, especially when skiing or snowboarding. With geolocation abilities, wearables can help you find your way back to civilization no matter where you are.
The Garmin fēnix® 7 is a smartwatch with loads of geolocation features, including access to multiple global navigation satellite systems such as GPS, GLONASS, and Galileo3. It supports downloading topographic and satellite maps directly on the watch, and with outstanding battery life, the fēnix® 7 is ready to get you out of a tough jam.
Safety communications
Many wearables, such as smartwatches, are making it easier than ever to call emergency services in the event of an accident. From fall detection to hypothermia scares, wearables with sensors and tracking ability can detect car accidents, falls, or other dangerous accidents. Thanks to slippery ice, falls are more common in winter and can be utilized to alert caregivers or emergency contacts in case you become incapacitated to make a call.
The Apple Watch, for example, calls emergency services if it detects you have fallen. If you become immobile after a fall, the Apple watch will detect inactivity after a minute and start to vibrate on your wrist to get your attention while sounding off a siren to get the attention of anyone nearby. After another minute, it will alert emergency services and emergency contacts to your location so you can get the care you need.
Limitations of Winter Wearables
Like other types of wearable fitness trackers, winter wearables have limitations when it comes to accuracy, affordability, and battery life. Wearable sensors might become dislodged during extreme activity, limiting their accuracy and effectiveness. Data might not be 100% accurate, and high costs can be a barrier for some. There are also concerns about privacy and security regarding storing personal health information. Regardless of these limitations, manufacturers are developing smarter and more capable devices that fit any budget, are more accurate, and protect the user’s data.
The Future of Safer Winters with Wearables
The global wearables market is projected to hit $142 billion by 20305, and over 30% of Americans are currently using endpoint intelligence like health trackers6. As adoption increases, the technology and enhancement of wearables can become more specialized with artificial intelligence to focus specifically on winter conditions. This might include enhanced location tracking, easier ways to contact emergency services, or more temperature alerts for chronically ill individuals.
Mental health also takes a hit in winter, thanks to fewer hours of sunlight, more time indoors, and a drop in serotonin levels. In the future, wearables with augmented reality and virtual reality enhancements could provide immersive, sun-filled experiences that may increase serotonin levels.
How Ambiq Contributes
Battery-powered IoT devices fueled with an energy-efficient System On Chip (SOC) like the ones from Ambiq help smart devices become winter-ready with power-efficient processing solutions that perform complex inferencing while sipping power. Wearables can operate on a single charge for days, weeks, and even months, ensuring the health tracker is on stand-by during icy, snowy, or freezing winter temperatures. In the event of a life-saving emergency, you can count on an Ambiq-powered device.
Sources:
1 Climate Change Indicators: Cold-Related Deaths | 2021
2 Ministry of Supply’s new jacket can heat itself and listens to your voice commands | February 23, 2018
3 Garmin fēnix® 7 – Standard Edition | Multisport GPS Smartwatch | 2023
4 Use Fall Detection with Apple Watch – Apple Support | 2023
5 Wearable Technology Market Size, Share, Analysis, Trends, Growth Report, 2030 | October 4, 2023
6 Study reveals wearable device trends among U.S. adults | June 15, 2023
It’s safe to call the Internet of Things (IoT) a fact of life with a projection that there will be around 17 billion devices in 20241. And unlike some sectors, exponential growth isn’t leading to rapid stagnation. IoT is constantly advancing, and ground-shaking innovations are par for the course.
2024 is already shaping up to deliver major transformations, and big things are happening at the broader societal level. Here are four trends to look out for in the days to come:
Architectures Become More Flexible
As technology evolves and becomes more diverse, the demand to create more cohesive networks that developers can seamlessly build across various platforms will become more prevalent.
Open-sourced architecture has become a winning solution. By allowing collaboration, improvements, and flexibility, developers can use open-source architectures to adapt to their application’s specific needs. This results in agile environments, higher scalability, and continuous improvements.
Recently, Xiaomi announced the Vela Platform at their IoT Ecological partner conference. The Vela platform is an embedded software platform built on the open-source real-time operating system NuttX. Vela provides unified software services on various IoT hardware platforms, supporting multiple components and a user-friendly framework to integrate fragmented IoT application scenarios.
It has a range of tools that help developers debug and is already picking up support from big names in integrated circuits including Ambiq with our Apollo4 Blue Display Kit designed to show off the graphical and technical capabilities of our system on chips (SoCs) for IoT devices.
Ultra-low Power Consumption Will Start to Become the Norm
AI is becoming increasingly integral to business workflows. However, depending on an external cloud isn’t always viable when your sensors and other assets are on-premises. If your sector leans heavily on IoT devices, you’ll have to rethink how you use power to keep up.
Artificial Intelligence (AI) is known for consuming massive amounts of power. While the training phase commonly shoulders most of the blame, studies show that inference is also energy-hungry2. This doesn’t bode well for use cases like stock management, early disease diagnosis, and other innovative applications.
Ultra-low-power SoCs will take center stage in the push for IoT-powered AI sustainability. The increasing availability of AI-enabled endpoint devices will only spur demand. Low-voltage technology like Ambiq’s Subthreshold Power Optimized Technology (SPOT®) has proven that high-end computing is possible without massive energy consumption. Now, it’s just a matter of putting the pieces together.
IoT Cybersecurity Will Blossom for Endpoint Devices
AI is a powerful tool, so what happens when it winds up in the wrong hands? Unfortunately, we’re already starting to see the ramifications play out. AI-generated hacks are emerging among the biggest cybersecurity threats of the modern era.
AI can make finding exploits far less time-consuming and effective. Worse, the wide accessibility of cloud technology makes it all the more appealing to cyber criminals3. This is already happening in the consumer sector, with potentially devastating results. Email security provider Egress revealed that AI makes phishing campaigns harder to detect4. It’s also helping bad actors sidestep quarantines and detectors.
The good news is that fighting fire with fire could be a valid defense. ML models like support vector machines and random forests have been shown to detect suspicious activity with high accuracy and efficient memory usage5. If your most vulnerable assets become compromised, embedding AI-capable hardware right on the endpoint could be an effective countermeasure to regain control over those assets or minimize the damage.
Regulations May Grow Sharper Teeth
While not an exciting trend, IoT regulatory compliance is becoming more of a necessity by the second. Governments may be warming up to IoT like never before, but they haven’t thrown all caution to the wind.
In early December 2023, the US Office of Management and Budget (OMB) exemplified this in a new guidance. To comply with the OMB’s rules, federal agencies must provide detailed inventories of their IoT devices by the end of fiscal year 20246.
The US wasn’t the only nation to move in this direction. In October, the UK government finalized a sweeping set of security regulations for connectable products — devices that either connect to the internet or send and receive data via EM transmissions7. These rules targeted manufacturers, covering everything from password strength to updates.
It wouldn’t be surprising to see vendors face similar requirements. Also, data privacy laws like the EU’s GDPR have long since established that being a foreign-domiciled enterprise doesn’t exempt you from compliance burdens. Regulatory crackdowns don’t necessarily mean application growth has to slow; it just needs a more comprehensive approach to governance. Hardware vendors can and should play a role in this journey.
How Ambiq is Contributing
These predictions aren’t exclusive to 2024. They’ll continue to pose concerns in the years to follow — and waiting to play catch up isn’t quite a winning strategy.
Ambiq’s ultra-low power portfolio empowers you to meet increased processing demand and adapt to the changing landscape. From driving Arm® Cortex® M4 energy consumption lower than thought possible with the Apollo4 Blue Plus SoC to ensuring always-on devices live up to their name. We’re helping IoT reach its true potential. Dive into our catalog to find out more.
Sources:
1 Internet of Things (IoT) in the US – statistics & facts | December 19, 2023
2 OMB guidance asks agencies to provide inventory of IoT assets | December 6, 2023
3 Prepare for AI Hackers | March-April 2023
4 2023 Phishing Threat Trends Report | 2023
5 Detecting Cybersecurity Attacks in Internet of Things Using Artificial Intelligence Methods: A Systematic Literature Review | January 10, 2022
6 The growing energy footprint of artificial intelligence | October 18, 2023
7 UK government finalises IoT cybersecurity requirements | October 25, 2023
In a recent interview with SafetyDetectives, Scott Hanson, the Founder and CTO of Ambiq, delved into the creation and evolution of the SPOT platform, which focuses on building the world’s most energy-efficient chips. Originating from Hanson’s time as a PhD student at the University of Michigan, where he developed tiny systems for medical implants, the SPOT platform utilizes Subthreshold Power Optimized Technology to achieve unprecedented energy efficiency.
Hanson discussed the platform’s departure from conventional digital chip designs, emphasizing the significant energy savings achieved by operating at low voltages. The interview covered Ambiq’s role in addressing technical challenges in the IoT industry, emphasizing the crucial aspects of power efficiency and security. Hanson also expressed his optimism about the future of ultra-low power technology, foreseeing continuous improvements and a surge in compute power for IoT devices in the next 5-10 years.
Can you describe the journey that led to the creation of the SPOT platform?
Hi, my name is Scott Hanson, and I’m the founder and CTO of Ambiq.
Ambiq is a company that builds the world’s most energy-efficient chips. We’re putting intelligence everywhere; that is really the tagline. We want to make chips with such low power that we can embed little microprocessors and everything in your clothing, paint on the walls, bridges we drive over, pet collars, etc.
The company is built around a technology that we call SPOT, or Subthreshold Power Optimized Technology. It’s a low-power circuit design technology platform from my time at the University of Michigan. I was a PhD student there, and we were building tiny systems for medical implants.
When I say tiny, I mean really small. We’re talking about one cubic millimeter containing a microprocessor, a radio, an antenna, sensors, and a power source. When you’re building a system like that, the first thing you figure out is that the battery’s tiny, so the power budget that corresponds to that battery must also be tiny.
We got to thinking in terms of picowatts and nanowatts, right? We usually think about watts and kilowatts in the normal world, but we had to think about picowatts and nanowatts. When we did that, we could build these cubic millimeter systems; they could be implanted in the eyes of glaucoma patients to measure pressure fluctuations. It was exciting that this SPOT platform made all of that possible.
During that project, I started to see a lot of interest from companies in the technology, and it got me thinking that this technology had commercial potential. I remember riding in an elevator at the University of Michigan in the Computer Science building and realizing that the technology would be commercialized one day, and I needed to be the person to do that.
Shortly afterward, I started Ambiq with my two thesis advisors At Michigan, and we managed to raise some money. Then we launched our first few products, and here we are 13 years later, having shipped well over 200,000,000 units of our SPOT-enabled silicon. It’s been a really fun journey.
How does the SPOT platform fundamentally differ from traditional microcontroller technology?
I’m going to avoid giving you the full Circuits 101 lecture here. Conventional digital chips are not just microcontrollers but any chip signals digital ones and digital zeros using voltage.
A digital zero might be 0 volts, and a digital one will be a much higher voltage at 1 or 1.2 volts. That higher voltage is chosen because it’s easy to distinguish between zero and one. It’s also chosen because 1 or 1.2 volts is much higher than the turn-on voltage of the transistor.
Every modern chip is basically made of transistors, the fundamental building block.
We’ve got billions of transistors on these chips, which look like little switches. Think of them like a light switch. When the voltage applied to that transistor is above a turn-on voltage, what we call the threshold voltage, it turns on. A drop below the threshold voltage, and it turns off. You can see how you can string these things together and get devices that signal zeros and ones.
If you look at your Circuits 101 textbook, they teach you to apply a voltage well above the threshold voltage to turn on voltage, and it functions as a proper digital switch. Pretty much every chip out there operates in that way. However, at Ambiq, with SPOT, we ignore that convention. We represent the 1 with a much lower voltage; think of 0.5, 0.4, or 0.3 volts. If that voltage is below the turn-on voltage of the transistor, we call that subthreshold. If it’s at or near that turn-on voltage, it’s called near threshold.
It turns out that by shrinking what a digital one is, you get some huge energy savings. Energy equals voltage squared, so it’s quadratic with voltage, and therefore, you get this huge energy reduction by operating at low voltage.
That comes with all kinds of idiosyncrasies, and it’s what’s kept all the other companies away. Transistors start behaving weirdly but still operate like a transistor or switch, which becomes tough to manage. Our SPOT platform is about dealing with those idiosyncrasies or those subthreshold challenges, and it works.
The subthreshold and near-threshold technology has been around for decades. Ambiq was the first to really commercialize it widely, and our timing was perfect. About ten years ago, as the company was getting off the ground, the Internet of Things (IoT) was just starting to explode. Battery-powered devices were going everywhere, and there was this insatiable hunger for low power. The SPOT platform came along at the right time, and we’ve solved a lot of power problems, but the need for more compute continues to grow.
AI is popping up everywhere. We’re seeing that it’s not just in the cloud but also beginning in the endpoint devices like the ones we serve, such as consumer wearables or smart home devices. AI is straining the power budgets of all these devices, and that means that we’ve got to continue to innovate and release new products that are lower power.
What are the environmental implications of the widespread adoption of ultra-low power technologies?
Lower power is good for the environment, and it’s a green technology. If I have power needs that are that big, with low power technology, I can reduce the need to a lower amount, that’s good. However, the truth is a little bit more complex than that.
What tends to happen is that our customers don’t necessarily take advantage of consuming less energy by having smaller batteries and charging less often. Instead, they tend to add new functions. They’ll say, you have a more power-efficient processor? Then, I’ll add more stuff to that same power budget. So, the power footprint of the world is not really decreasing; it’s just that we’re able to get more done in that same power footprint.
It’s probably a wash in terms of environmental impact. That said, the IoT as a whole has some pretty fantastic potential for the environment. As we put sensors all over our homes and buildings, we could put climate sensors all over the world. We have a better sense of what’s going on in the world, whether it’s climate change and we’re able to track that, or it’s how much energy this building is using, and whether we are leaving lights on in a hallway where there’s nobody, there’s nobody present.
So there’s a potential to use the Internet of Things to dramatically reduce our energy usage, meaning manage buildings, energy consumption, managed homes, and energy consumption better, but also get a better sense of what’s happening in the world.
So I think there is the potential for our technology to be used in a very positive way.
But most of our customers tend to be using it just to kind of get more out of their existing power footprint.
What are the biggest technical challenges facing the IoT industry today?
Power is one of them, and it’s one that we’re addressing diligently every day. We want to put billions of devices everywhere, and you don’t want to be changing billions of batteries? So, having a low-power platform like SPOT is really critical.
Security is a growing concern. Io T has been developed very quickly and often without a proper eye toward security needs. The average person has tens of IoT devices in their home now, and they are collecting all kinds of intimate data about us. It’s collecting health information and movement patterns in my home. We’re seeing virtual assistants constantly capturing our speech to listen for the “Alexa” keyword or the “OK Google” keyword, and that’s not stopping, right?
There’s this insatiable appetite for more AI; deep neural networks are exploding everywhere. We’re going to see this constant need for processing in the cloud, which means we’re sending data up to the cloud.
That’s a privacy problem, right?
There are many ways to handle that. There’s a lot of good, interesting security hardware security software popping up. However, I’m going to say that probably the most effective solution is pretty simple – don’t send as much data to the cloud.
Do most of the processing at the endpoint, such as on the smartwatch, smart thermostat, and the Echo device in your house.
There’s no need to send all the data up to the cloud. It can be processed locally. It turns out that’s a power problem, too. If I say that instead of sending 100% of the raw sound data from an Amazon Echo up to the cloud, we’ll only send the 1% that’s interesting enough to send, it means there needs to be local processing. It must be done on the smartwatch, thermostat, Echo, or devices with sensors capturing the data.
That’s a power problem, especially as the neural networks running to support these use cases are getting bigger. Fortunately, SPOT is a great solution. We’re doing a lot of architectural innovation to ensure our customers can run big, beefy neural networks locally and on devices like this. I’m confident that we can attack that problem. However, I foresee a few years of rocky security problems here in the next few years.
How do you see the role of AI and machine learning in the evolution of IoT devices?
What I think is going to happen is that we’ll see a migration of AI from purely a data center thing to the endpoints, which means wearables, smart home devices, your car, or devices with sensors.
We’re seeing our customers run lightweight activity tracking or biosignal analysis on wearables. They’re embedding virtual assistants in everything, whether it’s a wearable, hearable, or smart home appliance. In all these cases, there’s a balance between the endpoint and the cloud. The neural network can have a lightweight front end that runs locally; if it identifies something interesting, it then passes it to the cloud for further analysis.
What I’m really excited about is the potential for large language models (LLM), such as chatGPT, that are trained with enormous amounts of data, largely from the Internet. However, they don’t have eyes and ears; they’re not in the real world understanding what’s happening. That’s the role of the endpoint devices, your wearables, smart home devices, or smart switches. Those devices are constantly capturing information about us.
If they could run lightweight neural networks locally to identify activities or events of interest, they could ship those to the cloud to a ChatGPT-like model. Imagine if your wearable monitors your vitals, heart rate, breathing, and talking, and it identifies trends of interest and sends those up to the AI.
I’m not talking about megabytes or even gigabytes of the data it’s constantly collecting. I’m talking about sending a few little snippets – a few little observations. For example, you had a high activity date today, or sleep was not very good last night. You send that up to the cloud, and then you can ask it more useful questions like – Hey, I haven’t been feeling great lately, what’s wrong? The AI would be able to answer with something along the lines of I’ve been watching you for the last six months, and I see that your sleep has been irregular. You need to get more regular sleep, and here’s what you can do to fix that, right?
There are countless examples of things like this where endpoint devices can collaborate with large language models in the cloud to achieve fantastic results.
Now, there are obvious security problems there. We just talked about how security problems are one of the major challenges facing IoT. That’s no different here, and it’s a problem that needs to be managed. However, if you do most of the processing locally, we can effectively manage the security issues. I think between the endpoint and the cloud, there’s a way to address the security problems that pop up there. And I think there’s real power in what can be achieved for the endusers.
How do you see ultra-low power technology evolving in the next 5-10 years?
The good news is that I see it improving with really no end in sight. We’re going to see far more compute power packed into shrinking power budgets.
Moore’s law is alive and well for the embedded world. We’re at a process node today that’s 22 nanometers. The likes of Qualcomm, Intel, and others are down below 5 nanometers, so we’ve got a long way to go to catch up to them.
Moore’s law is going to deliver all kinds of gains. That means faster processors and lower power processors. We’re also doing a ton of innovation on the architecture, circuits, and software. I don’t see an end to power improvement, certainly not in the next decade.
Just look at how far Ambiq has come in the last ten years. We have this family of SoCs called Apollo. The first one was launched in 2014 and ran at 24 MHz. It had a small processor and less than 1 MB of memory. Our latest Apollo4 processors have many megabytes of memory. They run at nearly 200 MHz. They have GPUs and USB interfaces, consuming 1/8 of the power of our initial product. So we’re getting dramatically faster, dramatically low power that will continue.
If you just extrapolate those numbers going forward, we’re going to have an amazing amount of compute power for all your IoT devices, and that’s exciting.
I don’t 100% know exactly what we’ll do with all that compute, but I do know that I’ve got customers asking me every day for more processing power, lower power, and they’re going to be doing some pretty exciting things.
So, I’m excited about where we’re going from here.
This interview originally appeared on Safety Detectives with Shauli Zacks on January 4, 2024
The Internet of Things (IoT) is transforming virtually every aspect of our lives, including healthcare. Heart monitoring devices, connected inhalers, and even connected contact lenses allow healthcare providers to enhance their reach outside the clinical setting.
Now, IoT is making advancements in dentistry, offering care that is smarter and more centered on the patient’s experience, which also leads to brighter smiles. Here, we’ll explore how dentistry is adopting IoT, the problems it can help dentists solve, the technologies being developed, and the challenges associated with this innovative approach.
Tooth Decay Detection
Tooth decay and gum disease are issues that often go unnoticed until they reach an advanced stage that demands more extensive treatments. Smart dental imaging technologies can detect early signs of tooth decay and gum disease using advanced sensors. Dentists can access detailed, real-time images of a patient’s teeth and gums, enabling them to identify and address cavities or gum inflammation in their infancy, minimizing the need for invasive procedures.
VideaHealth has launched a dental AI platform that uses an algorithm trained on a dataset of hundreds of millions of data points, surpassing the number of X-rays seen by most dentists in their entire professional lives by more than 50 times1. VideaHealth says its FDA-approved platform has seen real-world results, including a 31% increase in tooth decay detection over human observation. This advanced system also offers tailored treatment recommendations based on its comprehensive learning.
Dental Anxiety
Dental anxiety is a common deterrent to regular dental check-ups for certain patients, leading to delayed treatments and worsened oral health. Virtual Reality (VR) therapy, powered by IoT, is emerging as a solution to alleviate dental anxiety. VR headsets transport patients to calming environments during procedures, making dental visits more tolerable. This technology enhances the overall patient experience and encourages regular check-ups by mitigating anxiety.
Patterson Dental, a vendor of dental equipment, professional services, and software, has introduced OperaVR, a platform designed to ease patient anxiety through 60 immersive experiences2. Patients can choose between visiting a coral reef or a day at the beach with VR headsets featuring stereoscopic 3D, which helps calm and keep the patients still during procedures.
Oral Hygiene
Patients often struggle with maintaining consistent and effective oral hygiene habits. But smart toothbrushes and interactive apps can track brushing habits. Patients receive real-time feedback on their techniques and can set personalized oral care goals. This fosters better habits and empowers individuals to take control of their oral health.
Companies like BrushLink are at the forefront of developing connected toothbrushes3. These devices attach to toothbrushes, turning them into smart brushes. Its Brushlink Pro is a sonic toothbrush with Brushlink technology already integrated within. These innovations leverage IoT to track brushing habits, providing users insights into their oral hygiene routines. Dentists can then use this data to tailor advice and recommendations for better dental care.
Dental Protection
Athletes in contact sports run the risk of traumatic dental damage, but a new generation of smart mouthguards can help. Going beyond basic dental protection, some innovations feature multiple technologies designed to enhance the player’s performance and experience.
Orb Innovations is another player in the IoT dental space, offering smart mouthguards that track physiology and biometrics4. Its Smartguard monitors heart rate by using light to measure changes in blood vessels and impact locations and sizes so players can improve their defense. The device also tracks steps, distance traveled, and movement intensity, all with technology that connects to smartphones or popular fitness apps.
Dental Implants
Dentists use implants as a more permanent alternative to dentures and bridges to replace teeth lost due to gum disease, trauma, or decay. But implants don’t always live up to their intended purpose and may need early replacement due to periodontal disease or inflammation.
Researchers at the University of Pennsylvania are making groundbreaking strides in developing smart dental implants that resist bacteria with two technologies5. The first uses nanoparticle-infused biofilm that resists bacterial growth. The implants also generate electricity from an embedded light source for phototherapy. Its piezoelectric qualities generate power from motions like chewing or brushing teeth, promoting periodontal health in surrounding tissue.
Challenges of IoT in Dentistry
While the integration of IoT in dentistry holds immense promise, it also comes with challenges:
Data Security and Privacy Concerns
The collection and storage of sensitive patient data raises concerns about security and privacy. Manufacturers and healthcare providers must implement robust cybersecurity measures to safeguard patient information.
Standardization and Interoperability
As various IoT devices enter the dental market, ensuring seamless communication and compatibility among different technologies can be challenging. Standardization efforts are essential to maximize the effectiveness of interconnected devices.
Professional Adoption and Training
The successful implementation of IoT in dentistry requires dentists and healthcare professionals to adapt to new technologies. Training programs and educational initiatives are crucial to ensure practitioners can fully utilize the potential of these advancements.
Outlook for Smarter Dentistry
As IoT technology advances in dental care, we can anticipate highly personalized treatment plans, addressing individual needs and promoting preventive care. Remote monitoring and teledentistry will allow dentists to provide guidance and interventions without the need for frequent in-person visits, benefiting those who live in remote or underserved areas. This technology will also enhance patient engagement by way of gamification and interactive features that can make dental care more enjoyable and encourage healthier habits.
How Ambiq is Contributing
Smarter dentistry that recognizes teeth decay and gum disease are data based and will require an embedded chip capable of handling complex inferencing tasks that provide insight into oral health. Ultra-low power System-on-chips (SoCs) from Ambiq® are capable of handling smart inferencing tasks at 10X lower power with extended battery life that can go up to days, weeks, and months on a single charge. See the applications of Ambiq here.
Sources
1 VideaHealth| 2023
2 Patterson Dental | 2023
3 Brushlink | 2023
4 Orb Innovations | 2023
5 Researchers Build a Smart Dental Implant that Resists Bacterial Growth | February 17, 2023