Tag Archives: Internet of Things

TALIS has tapped SIGFOX’s Internet of Things network for real-time fire hydrant monitoring.

Envision this: Your house catches on fire and you dial 911. The fire trucks arrive, the firefighters hop down and immediately throw the hose over their shoulders and rush around the corner to the nearest hydrant. Uh oh, the hydrant isn’t working. The hydrants of today can break, leak and freeze, something which can prove to be costly in a live-or-death situation. Luckily, the Internet of Things is here to help because with the advent of smart cities, comes the rise of much smarter water hydrants.

Most recently, water flow equipment provider Talis announced that they will be tapping into SIGFOX’s rapidly growing IoT network to bring their fire hydrant monitoring technology, called COPERNIC, to connected cities. The solution will enable utility companies and other city officials to track and analyze the status of smart fire hydrants to ensure they are indeed functioning properly and to prevent other issues such as water theft.

The two companies note that COPERNIC allows for real-time monitoring of fire hydrants by time-stamping all data related to hydrant functioning. An electronic module installed on the hydrant sends SMS or email alerts via the SIGFOX network when the hydrant is being opened, closed, tampered with, or malfunctioning. What’s more, all of that data will be made instantly available on a web-based portal, while a mobile app can also access, receive and read alerts.

As previously reported on Bits & Pieces and demonstrated throughout many of our trade show booths, SIGFOX’s cellular, ultra-narrowband (UNB) network has been exclusively designed for small messages that will meet the needs of the vast majority of objects connected to the IoT. The use of UNB is key to providing a scalable, high-capacity network, with very low energy consumption, while maintaining a simple and easy to rollout star-based cell infrastructure. The company’s Atmel based connectivity solution uses license-free frequency bands (runs in the unlicensed 902 MHz band in the U.S. and the 868 MHz band in Europe).

The French IoT startup’s UNB network has been specifically designed for small communications within IoT applications in order to greatly improve the battery life of connected objects. COPERNIC, incidentally, runs on lithium batteries that have an estimated lifetime of 10 years.

“The SIGFOX network, with its ‘plug-and-play’ connectivity, low cost and low power consumption will enable the COPERNIC solution to efficiently deliver a wide range of essential data to water-management officials in real-time,” explained Stuart Lodge, SIGFOX EVP of Global Sales.

This is just one of many bits of news to come out of our friends at SIGFOX in recent weeks. Last month, network operator Narrownet brought SIGFOX to Portugal to enhance the country’s IoT ecosystem for device manufacturers and service providers. Want to learn more? Head here.

Chrona will turn any pillow into a smart pillow

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Chrona is like a wearable tracker that, instead of being attached to your wrist, is placed on your pillowcase.

Like all animals, humans require sleep along with other essentials, such as food, water and oxygen, in order to survive. Truth be told, sleep is a vital indicator of our overall health and well-being. While most of us will spend up to one-third of our lives asleep, we still can’t figure out how to attain that desirable “well rested” feeling. And though most of us know that getting a good night’s rest is paramount, too few of us actually make those eight or so hours between the sheets a priority.

Knowing all too well the difficulties associated with trying to attain the ideal amount of shuteye, a group of St. Louis, Missouri entrepreneurs have set out to help you get the most out of those few hours. In other words, they want you to “not sleep longer, but smarter.”

Recently launched on Kickstarer, Chrona is essentially a smart pillow that is designed to track and improve sleep. The system consists of a thin memory foam pillow that sits atop of your regular head cushion and monitors movements at night using its built-in accelerometer. The pillow wirelessly connects with its accompanying mobile app via an embedded Bluetooth Smart module that safely transmits data.

Using the acquired accelerometer data, the app then determines where you are in your sleep cycle, and tells Chrona how to optimize your sleep or when to wake you up. According to its creators, Chrona can also last for seven weeks or so with just two AA batteries.

“Our design process is focused around comfort and ease-of-use. Chrona’s thin memory foam insert adds a layer of comfort without compromising the integrity of your pillow. Chrona’s minimalist speakers lay on top of pressure sensors, so the volume of the acoustic sleep optimization won’t ever be too loud, no matter how much you roll around,” the team writes.

As Chrona collects and analyzes sleeping patterns, its 0.5W compact speakers emit low-frequency noises that are meant to sooth and lull a user into a deeper, more restorative sleep. (And who said bedtime songs were simply for children?) Meanwhile, the device will begin to play higher frequency sounds to better transition you into a lighter state of sleep before the alarm goes off in the morning.

“When you’re relaxed with your eyes closed, your brain expresses the highest activity in the alpha-frequency range (like during meditation). Perfect Wake-Up uses sound in the same frequency range to prepare your mind to wake up,” the team adds.

People who share a bed needn’t worry about Chrona disrupting their partner’s rest either. That’s because the sounds coming from that pillow are so low in volume that they most likely won’t hear it. Beyond that, if both of you are using Chrona, the company’s proprietary algorithm will allow the two devices to communicate with each other and optimize sleep in a coordinated fashion.

David Rose, author of Enchanted Objects and an advocate of adding ambient technology to everyday items, has even endorsed the innovative product stating, “What’s powerful about Chrona is that it uses an object that is extremely familiar to all of us, improves it, and doesn’t require any complication installation or any new behviors.”

Deciding whether you’d like to rest smarter? Don’t sleep on it, hurry over to the team’s official Kickstarter page, where they are currently seeking $50,000. Shipment to early backers is slated for October 2015, while full-out available is set for December 2015.

Take control of your IoT data with Temboo Streaming

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IoT programming platform Temboo just introduced Streaming, a simple way to send sensor data to the cloud service of your choice.

Internet of Things programming platform Temboo recently debuted Streaming, a simple way to send sensor data to the cloud service of your choice. Streaming allows developers to visually wire sensors to the cloud on Temboo’s website where all the necessary code is dynamically generated within the browser. Once a Streaming application is running, it’s easy to switch where the data is being sent — with no hardware or software updates required.

Temboo is one of the first IoT platforms to forgo building its own sensor data storage solution in favor of giving developers options. Through its close integration with Microsoft Power BI, Streaming provides access to Microsoft’s cloud platform that combines data storage with data visualization, where IoT developers can view their sensor readings in real-time graphs.

“It’s very important to us that people who are working with Temboo are able to choose the tools and services that they want to work with,” explains Trisala Chandaria, co-founder Temboo. “By keeping Streaming open, we think we’ve kept the value front and center in IoT Mode.”

Streaming is also launching with support for Google’s BigQuery platform and can be used to program a wide range of Atmel based Arduino boards. The team notes that added support for other data services and hardware devices will be coming soon.

“We increasingly live in a world in which everything emits data, presenting new and exciting opportunities for those who can harness it,” adds James Phillips, Corporate Vice President, Microsoft Power BI. “Temboo Platform users can now stream data directly into Microsoft Power BI where it can be visualized and monitored in real-time, and analyzed using rich visual and natural language exploration capabilities.”

Streaming is ideally suited for building an assortment of IoT applications at any scale, from a water usage monitor that logs household water consumption to an urban traffic sensor network that enables policymakers to make informed decisions about how to decrease congestion.

Sound interesting? Head over to its official page here to learn more.

Droplet is a wireless button that helps you remember important things

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Recently launched on Kickstarter, Droplet is a smart reminder that tracks activities you don’t want to forget.

By now, most of us have all heard about Amazon Dash. We know it works: You push a branded button, an order for that particular product is ordered and delivered to your front door moments later. As to whether or not it will be successfully adopted, only time will tell. However, one thing is for certain: Companies will continue to find new ways to bridge the gap between our digital and physical worlds through the use of innovative interfaces.

Unlike constant reminders on a smartphone that can easily be dismissed with the swipe of a finger to ignore or the press of a button to snooze, Droplet is a bit harder to disregard. Instead, the Bluetooth-enabled button requires a user to physically tap the object to dismiss.

Whether it’s remembering to take medicine, feed a pet or take out the trash, the wireless, teardrop-shaped button can be attached to anything that requires a mental note. Simply affix the quarter-sized Droplet (26 mm x 21 mm x 7mm) to an object and tap it when you finish its coinciding task. Once completed, the device will record the action through its accompanying app, allowing you to track your activities and goals.

The mobile app also enables you to customize a Droplet to better fit your personal needs. For instance, you can use the app to configure new buttons and set email push notifications, as well as phone call reminders. What’s more, Droplet can be set to only remind you if you’ve forgotten a to-do and won’t bombard you with unnecessary alerts.

Beyond that, Droplet can be employed to initiate online actions, such as sending texts or ordering products. Stick one in the laundry room next to where you stock the detergent and tap it when you’ve poured the last of it out. Same goes for paper towel. Place one inside the closet and after taking out the last roll, hit it.

Aside from the button and app, the system consists of a physical hub, which plugs directly into your home’s Wi-Fi, and pings information stored on the cloud to the Droplet. One hub can manage multiple units.

What’s nice is that Droplet can be configured to share with friends and family, too. For example, you can alert someone if a chore is forgotten or simply notify a workout buddy to help you stay on track with your fitness goals. Designed with the older crowd in mind, the Droplet can also be used to help a family member track their medication or to send you reminders when they need refills. Since a majority of elders may not own a cell phone, let alone a smartphone, Droplets can send data to the smart hub so no smartphone is necessary.

Need a smart reminder in your life? Head over to Droplet’s official Kickstarter page, where the team is currently seeking $80,000. Shipment is slated for January 2016.

Building an IoT app for vertical farmers with Temboo

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Watch as the Temboo team reveals how a smart architecture app can be used to improve urban agriculture.

With urban populations expected to continue rising for the foreseeable future, this will lead to an increase in demand for access to nutritious food in cities. As recent Maker projects have demonstrated, not only does urban farming offer an ideal alternative to satisfy this demand, it has a number of additional benefits as well. For instance, growing food locally minimizes carbon footprint, serves as a source of income generation, and provides employment opportunities in the community.

Limited space, high pollution and variable access to light can make urban agriculture a challenge, however. In a recent episode of their Deconstructing IoT video series, the Temboo team created a smart architecture app to show how vertical farming could be integrated into the built landscape to overcome these obstacles. In doing so, they were able to control the delivery of natural and artificial light to their crops using the Nexmo API, and then base their decisions on UV and weather forecast information from EnviroFacts and Yahoo Weather.

In order to make this project possible, Temboo employed an Arduino Yún (ATmega32U4), a light or temperature sensor, two transistors, switchable glass, a little wiring, a breadboard, and some artificial light. How does the system work, you ask? As soon as the sensor detects suboptimal growing conditions around the plant, it triggers a phone call alert using the Nexmo Voice CaptureTextToSpeechPrompt Choreo. This notification can give a user the option of either turning on an artificial light source or shading their plant with switchable glass. In order to help make that decision, a call alert can also be configured to offer real-time UV and weather information, which is obtained using the EnviroFacts UVForecast HourlyUVByZipcode and Yahoo Weather GetWeatherByAddress Choreos. From there, they would simply have to press a number key to make the glass opaque and turn on the lights.

What’s more, the app can extend its capabilities to include ideal growing conditions based on plant species, email notifications, real-time memos for ready-to-be-picked crops, and even mobile payments via Stripe. With spring officially here, the timing couldn’t be better to get started! You can watch the entire episode of Destructing IoT below for a step-by-step breakdown of the build, as well as find each of the aforementioned Choreos on the Temboo website.

Domino.IO is an open hardware platform for the IoT

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Domino.IO is an affordable yet advanced Wi-Fi platform for the Internet of Things.

Designed with the Maker crowd in mind, Domino.IO is a low-cost, modular 802.11 b/g/n Wi-Fi hardware platform that features unlimited extension capabilities and is entirely Arduino-compatible. The kit is comprised of three different pieces of hardware: the Domino Core, Domino Pi and Domino Qi.

First, the Domino Core is a Wi-Fi module based on the Atheros AR9331 WiSOC. It is a surface-mountable single-sided Linux module, which exposes nearly all of the AR9331 WiSoC available signals to regular 2mm pitch castellated pads for both easy hand and automatic SMT soldering. The Core only requires a single 3.3V power supply to get going, and has a maximum consumption of only 0.5W. The Core comes pre-loaded with an open-source OpenWRT Linux system, enabling users to install more than 3,000 ready-to-use software packages. Beyond that, Makers can modify and customize the distro to better fit their project needs.

Next, the Domino Pi board extends the capabilities of the Domino Core module by adding a range of features, including integrated USB ⇔ UART bridge for serial port, +5V input / +3.3V output and a 2A DC/DC power supply, 2.4 GHz Wi-Fi PCB antenna, a jumpstart push button, some power and wireless LEDs, and two 28-pin, 2.54mm pitch headers. Makers can also customize their Pi board using any of seven building blocks, or tiles, including USB and microSD, single and dual Ethernet, LEDs, JTAG/SPI, as well as I²S audio. This allows Makers to play music from their USB discs or straight from an Internet stream through its open-source I2S audio codec and player.

Last but certainly not least, the Domino Qi Mini is a derivative of the Arduino Yùn, just crammed into a smaller form factor. The inexpensive, compact OpenWRT-based 802.11 b/g/n Wi-Fi board is based on an ATmega32U4 MCU and an Atheros AR9331 WiSoC, while communication between the two chips is achieved using the Yùn’s Bridge Library. To get started, a Maker simply connects the Qi Mini to the Domino Qi baseboard. From there, the device becomes fully-compatible with the ubiquitous Arduino Shield form factor and gives way to hundreds of already existing shields for rapid prototyping.

The Qi Mini is equipped with a 5V input / +3.3 V output and a 2A DC/DC power supply, 2.4 GHz Wi-Fi PCB antenna, a ’32U4 reset, a WLAN reset, some push buttons, two 22-pin, 2.54 mm pitch headers, in addition to power, wireless, WAN and USB LEDs. Just like the Yùn, the board can be programmed in the Arduino IDE and supports the Linino OS as well.

The entire platform comes with an iOS and Android-ready app that lets users control their devices, including RC cars, right from their smartphones. What’s more, Domino.IO is both cloud and framework agnostic; meaning, users can choose from services like SparkFun data stream, ThingSpeak and Weaved, and create their projects in a wide-range of languages such as Python, Node.js, PhP and Lua.

Intrigued? Head over to its official Kickstarter page, where the team is currently seeking $30,000. If all goes well, shipment is expected to begin in June 2015.

Creating an Internet-connected ordering button with Parse for IoT

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Parse uses the combination of an Arduino, a button, and its SDK to simulate ordering toilet paper when running low.

Just the other day, Amazon announced their Dash button, a connected device that lets shoppers reorder frequently used household domestic products like laundry detergent and paper towels with a simple touch. Inspired by the recent system, the Parse team decided to create one of their own using an Arduino Yún, (ATmega32U4), a push button and the newly-revealed Parse for IoT SDK.

Much like the Amazon Dash Button, this DIY device simulates the process of ordering toilet paper when the roll begins to run low. This was accomplished by attaching a push button to the Arduino and using a small breadboard so that the button would sit neatly atop the board. These electronics were then housed inside the Arduino’s actual packaging, which was spray painted to make it a bit more aesthetically pleasing.

“Taking this example further, you could associate devices with user accounts, fully integrate with Shopify or another API (or build your own) and offer a premium push-button experience for people using your app,” the team adds.

Impressively, the entire application consists of less than 100 lines of code. Given the rise of the Internet of Things, you can expect to see many real-time systems like these begin to take shape, and surely Parse for IoT will help streamline the development process. Intrigued? Read more about the project on Parse’s official blog, or get started by heading over to its Github repository here.

A look back at the history of the Internet of Things

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IoT Day falling on Throwback Thursday can mean only one thing… a trip down memory lane to where it all began!

The Internet of Things (IoT) is a term first coined by Keven Ashton in 1999 during a PowerPoint presentation he made while working for Procter & Gamble. The phrase referred to a future world where all types of electronic devices link to each other via the Internet. Keep in mind, Wi-Fi was not ubiquitous back then. There was no email or social media applications on mobile devices. GPS didn’t exist in a meaningful way. Dick Tracy-like wearables were merely a pipe dream.

“If we had computers that knew everything there was to know about things — using data they gathered without any help from us — we would be able to track and count everything, and greatly reduce waste, loss, and cost. We would know when things needed replacing, repairing, or recalling, and whether they were fresh or past their best. The Internet of Things has the potential to change the world, just as the Internet did. Maybe even more so,” Ashton elaborately discussed in a 2009 RFID Journal article.

While on the surface, it may seem like something out of a sci-fi novel or an episode of The Jetsons to a vast majority of everyday folks, IoT represents a pivotal milestone in the history of the Internet as connections move beyond computing devices and begin giving once-ordinary devices new powers. While there has certainly been a tremendous amount of buzz around the concept of an intelligent, more connected world, the visions of this ‘smarter’ society date back several years.

1832

Baron Schilling von Canstatt invented the electromagnetic telegraph. A keyboard with 16 black-and-white keys served as its a transmitting device, while six galvanometers with magnetic needles suspended from silk threads acted as the receiving instrument. Later that year, Schilling managed a short-distance transmission of signals between two telegraphs in different rooms of his apartment. Not long after, Carl Friedrich Gauss and Wilhelm Weber developed their own code to communicate over a distance of 1,200 meters within Göttingen, Germany.

(Source: theapricity.com)

1844

Samuel Morse sent the first morse code public telegraph message “What hath God wrought?” from the Supreme Court chamber in the basement of the U.S. Capitol building in Washington, D.C. to the B&O’s Mount Clare Station in Baltimore.

(Source: Wikipedia)

1926

Nikola Tesla revealed in an interview with Colliers Magazine’s John B. Kennedy:

“Wireless will achieve the closer contact through transmission of intelligence, transport of our bodies and materials and conveyance of energy… When wireless is perfectly applied the whole earth will be converted into a huge brain, which in fact it is, all things being particles of a real and rhythmic whole. We shall be able to communicate with one another instantly, irrespective of distance. Not only this, but through television and telephony we shall see and hear one another as perfectly as though we were face to face, despite intervening distances of thousands of miles; and the instruments through which we shall be able to do his will be amazingly simple compared with our present telephone. A man will be able to carry one in his vest pocket.”

(Source: Wikipedia)

1932

Jay B. Nash wrote in Spectatoritis:

“Within our grasp is the leisure of the Greek citizen, made possible by our mechanical slaves, which far outnumber his twelve to fifteen per free man… As we step into a room, at the touch of a button a dozen light our way. Another slave sits twenty-four hours a day at our thermostat, regulating the heat of our home. Another sits night and day at our automatic refrigerator. They start our car; run our motors; shine our shoes; and cult our hair. They practically eliminate time and space by their very fleetness.”

1942

U.S. Patent 2,292,387 was granted to Hedy Kiesler Markey and George Antheil for an early version of frequency hopping.

1946

Dick Tracy introduced the two-way radio.

1950

Alan Turing noted in his article entitled “Computing Machinery and Intelligence“ for the Oxford Mind Journal:

“We may hope that machines will eventually compete with men in all purely intellectual fields. But which are the best ones to start with? Even this is a difficult decision. Many people think that a very abstract activity, like the playing of chess, would be best. It can also be maintained that it is best to provide the machine with the best sense organs that money can buy, and then teach it to understand and speak English. This process could follow the normal teaching of a child. Things would be pointed out and named, etc. Again I do not know what the right answer is, but I think both approaches should be tried.”

(Source: ScienceMuseum.org.uk)

1952

Norman Joseph Woodland and Bernard Silver received the first patent for a liner barcode.

1955

Edward O. Thorp devised the first wearable computer, a pocket-sized analog device used to predict roulette wheels.

(Source: Slash Gear)

1956

In the promotional film Design for Dreaming, Frigidaire envisioned the “kitchen of tomorrow” where a housewife feeds a recipe card into a slot, which triggers a series of appliances that automatically bake a birthday cake complete with lit candles.

(Source: TreeHugger.com)

1960

Known as the “Father of Virtual Reality,” Morton Heilig received a patent for the first-ever head-mounted display. The unit featured a stereoscopic (3D) TV, wide vision and true stereo sound.

1966

German computer science pioneer Karl Steinbuch stated, “In a few decades time, computers will be interwoven into almost every industrial product.”

1969

The first host-to-host message over ARPANET (the precursor to today’s Internet) was sent. The memo on the ARPANET was transmitted by UCLA student programmer Charles S Kline at 10:30 pm on October 29th, from the campus’ Boelter Hall to the Stanford Research Institute’s SDS 940 host computer.

The Honeywell Kitchen Computer, or H316 pedestal model, was a short-lived product offered by Neiman Marcus as one of a continuing series of extravagant gift ideas. It sold for $10,000, weighed over 100 pounds and was advertised as useful for storing recipes.

1971

ALOHAnet connected the Hawaiian Islands with a UHF wireless packet network. The protocol was an early forerunner to Ethernet, and later the Wi-Fi protocol.

(Source: Wikipedia)

1973

Mario Cardullo is granted the first patent for a passive, read-write RFID tag.

1974

Vint Cerf and Stanford graduate students Yogen Dalal and Carl Sunshine published the first technical specification of TCP/IP as an Internet Experiment Note (IEN) as RFC 675.

(Source: Stanford University)

1976

AT&T and MIT held a conference that brought together of number scientists, theorists and academics to explore the future of technology. There, Bell System news magazine had the chance to catch up with Arthur C. Clarke to share his predictions of mobile devices, home computers, the Internet, Skype, email, the death of newspapers, telecommuting, and of course, “Dick Tracy wrist-radios.”

“We’re going to get devices which will enable us to send much more information to our friends. They’re going to be able to see us, we’re going to see them, we’re going to exchange pictorial information, graphical information, data, books, and so forth. [The ideal communication device] would be a high-definition TV screen with a typewriter keyboard, and through this, you can exchange any type of information. Send messages to your friends … they can wait, and when they get up, they can see what messages have come in the night. You can call in through this any information you might want: airline flights, the price of things at the supermarket, books you’ve always wanted to read, news you’ve selectively [chosen]. The machine will hunt and bring all this to you, selectively.”

1981

Steve Mann developed a wearable personal computer wired to a camera and mounted to a helmet.

1982

TCP/IP is formalized, ushering in an era of worldwide network of fully-interconnected networks, which is known today as the Internet.

(Source: Wikipedia)

1989

Tim Berners-Lee proposed the World Wide Web.

(Source: Wikipedia)

1990

The Olivetti Research Laboratory developed an active badge system using infrared signals to communicate a person’s location.

(Source: David Greaves)

John Romkey and Simon Hackett introduced the world’s first connected device other than a computer: a toaster.

1991

The first web page was created by Tim Berners-Lee.

NCR Corporation with AT&T invented the precursor to 802.11, intended for use in cashier systems. The first wireless products were under the name WaveLAN.

(Source: Wikipedia)

For the first time, the term “ubiquitous computing” was mentioned in the Scientific American article, “The Computer in the 21st Century.”

1993

Steven Feiner, Blair MacIntyre and Dorée Seligmann launched Knowledge-Based Augmented Reality for Maintenance Assistance — more commonly referred to as KARMA.

The brainchild of Quentin Stafford-Fraser and Paul Jardetzky, the Trojan Room Coffee Pot was located in the ‘Trojan Room’ within the Computer Laboratory of the University of Cambridge. The device was used to monitor the pot levels with an image being updated about 3 times per minute and sent to the building’s server.

(Source: PetaPixel.com)

1994

Mik Lamming and Mike Flynn unveiled Forget-Me-Not, a wearable device that wirelessly communicated and recorded interactions of other people and gadgets, and stored the information in a database.

(Source: WN.com)

The term “context-aware computing” was first used by B.N. Schilit and M.M. Theimer in their paper on disseminating active map information to mobile hosts.

A group of engineers at Ericsson invented a wireless communication technology, which would later go on to be called Bluetooth.

1995

Siemens established a dedicated department inside its mobile phone business unit to develop and launch a GSM data module called “M1” for M2M applications.

(Source: Wikipedia)

1998

The name Bluetooth was officially adopted.

Scott Brave, Andrew Dahley, and Professor Hiroshi Ishii of MIT’s Media Lab developed inTouch, a project that “explored new forms of interpersonal communication through touch.” The so-called shared object provided a haptic link between geographically distributed users, opening up a channel for physical expression over distance.

1999

The Auto-ID (for Automatic Identification) Center was founded at MIT by Kevin Ashton, David Brock Dr. Daniel Engels and Sanjay Sarma. That same year, Ashton officially coined the term “Internet of Things.”

Andy Stanford-Clark of IBM and Arlen Nipper of Arcom (now Eurotech) introduced the first machine-to-machine protocol for connected devices: MQ Telemetry Transport (MQTT).

(Source: IBM)

2000

LG announced the world’s first connected refrigerator: the Internet Digital DIOS. Shortly thereafter, the Hollywood film The 6th Day featured a smart fridge which informed Arnold Schwarzenegger that he was in need of milk.

The first Bluetooth-enabled devices came to market. These included a mobile phone and PC card. A few months later, the first printer, laptop and hands-free car kits would also emerge.

(Source: MacLife.com)

2002

Chana Schoenberger and Bruce Upbin published “The Internet of Things” in Forbes stating:

“Stores have eyes. Now they’re getting brains. Soon tiny wireless chips stuck on shampoo bottles and jeans will track all that you wear and buy.”

(Source: Business Insider)

David Rose and others founded Ambient Devices, a spin-off of MIT’s Media Lab, which designs and markets various ambient devices enchanted by next-gen technologies. These objects, including the Ambient Orb, uniquely display information like weather, traffic reports and stock quotes.

2003

The term “Internet of Things” continued to gain mainstream popularity as it is mentioned in notable publications like The Guardian, Scientific American and the Boston Globe.

2005

Led by Massimo Banzi, a team of students and faculty members at the Interaction Design Institute Ivrea in Ivrea, Italy developed the Arduino, a single-board microcontroller based on Atmel’s ATmega8.

The United Nations first mentioned the IoT in an International Telecommunications Union report.

2008

The IPSO Alliance was formed to promote IP connections across networks of ‘smart’ objects.

2009

According to Cisco Internet Business Solutions Group (IBSG), the IoT was born somewhere in between 2008 and 2009 at simply the point in time when more “things or objects” were connected to the Internet than people.

2010

Google debuted a self-driving vehicle project, which served as a major milestone in the development of connected cars.

Bluetooth Low Energy (BLE) was introduced.

2011

IPv6 is launched. The new protocol expanded the number of objects that can connect to the web by introducing 340 undecillion (340,282,366,920,938,463,463,374,607,431,768,211,456) IP addresses.

The term made its first appearance on the Gartner Hype Cycle.

Nest Labs introduced the Wi-Fi-enabled, programmable Nest Learning Thermostat.

2013

Google Glass was released to developers.

Venture Beat named 2014 as the “Year of the Internet of Things.”

(Source: VentureBeat)

2014

A number of groups seeking to spur standard and framework development surfaced, including the AllSeen Alliance, Industrial Internet Consortium and the Open Interconnect Consortium.

Amid growing concerns around data breaches and device vulnerabilities, an HP report found 70% of the most commonly used IoT devices contain serious flaws — this making the case for hardware-based protection clearer than ever before.

Atmel and Arduino team up to launch of the Arduino Wi-Fi Shield 101, a shield that enabled rapid prototyping of IoT applications for Makers.

2015

Forecasts project that 4.9 billion connected things will be in use by the end of the year — up 30% from 2014 — and will reach 25 billion by 2020.

At Atmel, the IoT is already at the heart of what we do. We started preparing for this smarter world way back when, and now offer the industry’s most comprehensive, most highly-integrated IoT solutions. Explore them all here.

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