Imagining an ad-free Internet with AdTrap

Particularly in the holiday season, many of us are bombarded with advertisements as we surf the web. While there may not be a whole heck of a lot we can do about other forms of ads (like billboards or digital signage) we come across throughout the day, a Palo Alto-based company is however letting us eradicate adverts from our computer, mobile device and even smart TV screens.

In essence, AdTrap is an ad-filtering, open-source hardware device that simply plugs into your Internet router and banishes ads from your entire network. The creation, which first successfully debuted on Kickstarter two years ago, is the brainchild of Makers Chad Russell and Charles Butkus as they reminisced the ad-free “glory days” of the Internet.

The white rectangular box, resembling a wireless router and costs $129, is packed with an Atmel | SMART AT91SAM9X25 MCU, 128MB RAM, 256MB Flash for storage, two ethernet ports, two CAN buses, a serial port, a software modem, USB host/device as well as a ZigBee interface. AdTrap is also based on open-source Linux firmware, which its creators say can be easily tweaked.

And for those wishing to access certain ads or sites, you can still do so by easily configuring your own set of rule filters using its online management system. So, are you ready to browse the web without any interruptions? You can more about the Atmel | SMART based device by visiting its official site here.

Preview: Atmel is headed to Vegas for CES 2015

What happens in Vegas doesn’t necessarily have to stay in Vegas! From January 6-9, 2015, the Atmel team is headed to Sin City for the 2015 International CES, where we’ll be showcasing a number of cutting-edge Internet of Things (IoT) solutions and offering insight into the smarter, more connected world of tomorrow.

Attendees will have the chance to meet our team, demo our latest devices, and get a unique glimpse into some next-gen technology — from the Security of Things (SoT) to futuristic car center consoles — inside Las Vegas Convention Center’s South Hall, meeting space #MP25760. (The show is huge, so it may be helpful to map it.)

Bluetooth and ZigBee and Wi-Fi, oh my! Those looking ahead to a bright future of wireless and smart lighting are also welcomed to join members of our team at the Sands Expo Center in both the ZigBee Alliance Pavilion (booth #71023) as well as the Connected Lighting Alliance (booth #70432).

So what can you expect to see?

Atmel’s SMART LIVING ZONE brings more connectivity, security and intelligence to the home. 

• Wide-range of Atmel SmartConnect enabled applications including intelligent weight scales, door bells with built-in cameras, Wi-Fi connected speakers, as well as motion sensor-laden windows, smart plugs, and ZigBee-controlled lightbulbs and gateways.
• A new energy management solution capable of providing real-time, historic data of gas, energy and water consumption through a wireless remote with secure hardware authentication between the wireless device and home automation controls.
• The recently-revealed Atmel® | SMART™SAM L21 running on an Xplained Pro board with an ePaper display.

• Some of today’s leading tablets, smartphones and phablets powered by Atmel’s maXTouch® controllers, along with keyboards, mice and other human machine interface devices based on the company’s latest QTouch® capacitive platforms.
• Bringing together the IoT ecosystem, we’ll also be exhibiting solutions from a number of our friends and partners.

Atmel’s AUTOMOTIVE ZONE enables smart, connected cars with simple-to-use interfaces. 

• Ushering in an era of connected cars, the fully-functional and futuristic AvantCar™ center console concept is equipped with curved touchscreens driven by Atmel’s XSense®, maXTouch, QTouch, 8-bit AVR MCU technologies, and LIN-controlled ambient LEDs.

• RF and LF technologies for keyless entry systems, LIN- and CAN-based car networking applications, audio via Ethernet-AVB, MCUs and crypto technologies for safe data transfer via automotive networking.
• Multi-channel audio streaming over automotive Ethernet Audio Video Bridging (AVB) with low-power yet powerful SMART | ARM MCUs.
• The latest hardware and communication protocol offerings for remote keyless entry (RKE), passive entry, passive start (PEPS) and immobilizer, this demo showcases a complete reference design for automotive car access applications.

Atmel’s MAKER ZONE showcases Internet-enabled innovations. 

• At the core of the Maker Movement, the well-received Arduino Wi-Fi Shield is further enabling rapid prototyping of IoT projects on the Arduino platform, and will be exhibiting its ease-of-use and wide-range of applications for the professional and DIY communities alike.

• A number of other Maker demonstrations, including a remote-controlled Maker Robot powered by the Atmel | SMART SAM D21 will be displayed. “Mr. Abot” is controlled through an Android app and the communications driven through Atmel’s recently-announced WINC1500 Wi-Fi solution.
• Good news, Makers! You’ll have a chance to bring home a free Atmel Evaluation Kit by simply spotting AVR Man on the show floor, snapping a selfie and tweeting it to @TheAVRMan himself.

“Powered by Atmel” ZONE highlights the latest gadgets using Atmel solutions.

• Aside from an assortment of today’s smartphones and tablets, there will be a collection of wearables on display, too. This includes everything from the Narrative life-logging camera to various fitness tracking bands. As recent teardowns have revealed, Atmel can be found embedded within several highly-popular wrist-adorned gadgets like the TomTom Runner and Motorola Moto 360, as well as in a number of flagship phones like the Google Nexus 6 and Xiaomi mi4.

Stay connected!

Unable to make the show? Can’t find the booth? Follow along with us on Twitter using the hashtag #AtmelLive for all the latest trends and real-time happenings right from the CES floor. Don’t forget to check out insightful interviews on YouTube, daily recaps on Bits & Pieces, photos on Facebook and a whole lot more on our other channels as well!

Zymbit wants to get your IoT ideas to market in days, not months

As the next frontier of the Internet, the IoT represents a compelling opportunity across a staggering array of applications. That’s why the team behind Zymbit has developed a platform of open hardware and software devices to enable Makers, engineers and developers alike transform their IoT ideas into real-world products in a matter of days, not months. In an effort to deliver secure, open and interactive devices for our constantly-connected era, Zymbit is hoping that its pair of solutions — the Y and Z Series — will help accelerate adoption.

The company, who will be exhibiting inside our CES booth next month, has recently unveiled two devices each designed to interface with our physical world in a more secure, authenticated manner. Zymbit seeks to provide users with local and remote live data interaction, along with a low-power MCU, battery-backed operation.

“Y-series motherboards incorporate some of the latest secure silicon from Atmel, providing accelerated processing of standard open security algorithms. A separate supervisor MPU takes care of security, while you take care of your application,” a company rep writes.

Based on the Atmel | SMART SAM D21, the Y Series motherboard is electrically robust with enhanced security provided via the ATECC108 crypto engine and ATWINC1500 Wi-Fi controller. Ideal for those developing next-gen IoT applications, the board is easily customizable and compatible with Atmel Xplained Pro wingboards, Arduino shields, Raspberry Pi B+, as well as ZigBee, cellular and POE module options.

Meanwhile, the Z-series not only boasts several standard expansion and mounting options, but allows 3D-printable parts to easily be integrated for ultimate personalization.

Each Zymbit device features a dedicated hardware crypto engine to ensure that only trusted data is exchanged between devices. Security processes run within a supervisory ATSAMD21J18A, separately from its ARM Cortex-M0+ application MCU.

The unique Zymbit architecture delivers three key security components:

• Authenticated data source with 72-bit ID Serial Number
• Secure data transmission with SHA 256
• Private data transmission with Wi-Fi embedded AES engine

The Z-series packs several addition security features, including private data transmission with AES engine 124/192/256, secure data transmission with SHA 1/2/3, public key acceleration, black key management and high assurance boot.

Wait… there’s more! In the forthcoming weeks, the team plans on revealing an innovative (and extremely cool) way for devices, users and data to interact through visually, audibly and of course, by touch. See it for yourself next month at CES!

Interested in learning more? You can stay up-to-date with the Zymbit team’s progress here.

8- or 32-bit, that is the question…

Writing for Electronic Design, Atmel’s Ingar Fredriksen and Paal Kastnes recently explored the latest market trends for both 8- and 32-bit microcontrollers (MCUs). While the 32-bit MCU devices continue to rise in popularity throughout the embedded community, 8-bit MCUs are still experiencing a CAGR close to that of their bigger cousins.

These 32-bit, function-rich devices suit an array of different applications, which explains why many embedded developers select them for their next designs. Designers recognize that such complex devices offer everything they need in terms of raw compute power, a rich peripheral set, and easy access to a wide range of development tools and libraries.

Many of these 32-bit devices — which are members of the Atmel | SMART family — are based on the highly-successful ARM cores. Thus, developers feel confident in having access to second source devices and a comprehensive set of development, test and validation tools being available in the market.

However, taking a closer look at recent MCU market trends has revealed that 32-bit devices aren’t the only ones experiencing strong growth. The surging 8-bit MCU market boasts a CAGR (6.4%) close to that of 32-bit (6.9%). Meanwhile, a number of other industry analysts forecast identical growth rates for 8- and 32-bit microcontrollers.

The upswing in 8-bit devices, like the incredibly popular Atmel AVR lineup, clearly highlights that there must be some compelling reasons to use an 8-bit device in place of a 32-bit MCU. The recently-published Electronic Design article looks to shed some insight as to why 8-bit devices are retaining market share.

Essential Differences

The principle differences between 8- and 32-bit MCUs are cost and price structure, CPU performance, ease of use, efficiency in hardware near functions, and static power consumption. When embarking on a new design, developers need to carefully scope out the requirements for an MCU based on the amount of processing capability required, the degree of interfacing needed, and, for battery-powered designs, the all-important power consumption profiles. There’s no doubt that a 32-bit MCU delivers higher performance than an 8-bit device, but the engineer faces the traditional decision of choosing between the best available device in the market versus an application’s actual needs.

Of course, these decisions will greatly influence the likely bill of materials (BOM) cost. With a lower gate count, a less complex 8-bit device will certainly be cheaper than a 32-bit device. When comparing 8- and 32-bit MCUs from leading vendors, each with a similar amount of flash memory, pin-out etc., 8-bit devices typically cost about 20% less. But this is only the first of many considerations. Another aspect relates to the ease in setting up for a new development.

Ease of Development

MCU suppliers tend to add more features and functionality to their 32-bit devices as opposed to 8-bit products. Consequently, far more setup considerations emerge with a more complex device. While some 32-bit MCUs can run with a limited setup similar to that of an 8-bit device, you’re unable to take advantage of the more powerful device’s additional features.

For example, a typical 32-bit ARM device will have independent clock settings for the core itself, the AHB bus, the APBA bus, and the APBB bus. They all can be set to different frequencies. Typically, you will also have to switch to the clock you want to use because it’s set in software, not in hardware like most 8-bit parts. Furthermore, changing the clock means you must set up the wait states for flash, possibly predicated on measured V_CCvoltage.

Such a setup can be much simpler with an 8-bit MCU, though. For example, Atmel’stinyAVR and megaAVR products only require initialization of the stack pointer, which typically takes four lines of code, prior to coding the application. The choice of clock, brownout detector, reset pin function, etc., is all pre-programmed into the device.

The architecture is also much more straightforward than a 32-bit device with internal registers, peripherals, and SRAM all mapped on the same data bus. The peripherals and CPU would normally run at the same frequency, so no peripheral bus configuration is necessary. Moreover, designers can avoid being concerned about latency in synchronizing between different clock domains.

Performance

When it comes to desired CPU performance, the engineer should consider all use cases. The reality is that many embedded designs don’t have high compute requirements. Often, very little manipulation of data is required, so balancing those needs against power-consumption and peripheral-interfacing requirements becomes crucial.

For instance, a simple thermostat application will spend most of its life in a sleep mode. Every so often, it will wake up and measure the temperature and then make a decision to turn a relay on/off or send an instruction to a host controller. Then it will resume sleep. The compute and interface requirements of this application are small, but many other applications such as fire detectors, power tools, flow meters, and appliance controls have a similar use profile, too.

Efficiency of Hardware Near Functions

Many modern microcontrollers incorporate some hardware functions that serve to help the CPU operate as efficiently as possible. In Atmel’s case, both the 8-bit AVR and 32-bit ARM-based MCU families feature the Peripheral Event System. An event system is a set of hardware-based features that allows peripherals to interact without intervention from the CPU. It allows peripherals to send signals directly to other peripherals, ensuring a short and 100% predictable response time.

When fully using the capabilities of the event system, the chip can be configured to do complex operations with very little intervention from the CPU, saving both valuable program memory and execution time. In the case of detecting a hardware event, it’s important to first detect the event and then switch control to the desired interrupt service routine (ISR).

In these situations, CPU speed isn’t the single determining factor. It’s a question of how long, in terms of cycles, does it take to respond to the interrupt, run the ISR, and return. As the following example will show, 8-bit devices can be more efficient in handling hardware near actions.

Consider receiving one byte on the SPI, using an interrupt to detect it, and then running a simple ISR routine to read the byte from the SPI peripheral and store it in SRAM. Using this scenario, table above draws comparisons between an Atmel 8-bit AVR device and an Atmel ARM Cortex M0+based 32-bit MCU. Calculated with information available, the results are based on minimum implementations. However, engineers should check with their own applications since the interrupt detection and return from interrupt could take more cycles than shown in the table. Requiring 12 cycles versus 33 cycles equates to having a theoretical maximum SPI bandwidth of 1.67 MB/s for the 8-bit CPU and a 606 kB/s bandwidth for a 32-bit CPU when running at 20 MHz.

The degree of numeric processing can also have an impact on the stack and required memory. Applying the Fibonacci algorithm is one particularly good method for testing memory requirements. Since it only uses a local variable, everything needs to be pushed to the stack.

When making a comparison between an 8-bit AVR and an ARM 32-bit CM0+-based device, and using a recursive 15-stage Fibonacci algorithm, the AVR uses a total of 70 bytes of stack, including 30 for return stack (15 calls deep). The ARM-based device uses 192 bytes (60 should be return stack). This means the CSTACK is more than three times the size of the 8-bit solution. In typical C code, more of the variables on the stack often come in a packed format, so this is an extreme corner. However, saying 1.5 to 3 times more SRAM is needed for the same 8-bit-centric application on a 32-bit (versus a native 8-bit) device is a fair estimation.

Power Consumption

No MCU article would be complete without investigating static power consumption. This alone may be a key factor in choosing between an 8- or 32-bit device, especially for battery-powered applications. The table below illustrates power-consumption differences between 8- and 32-bit devices in both active and static modes.

Aggressive manufacturing technologies increase transistor leakage current, which roughly doubles with each process generation, and is proportional to the number of gates. Leakage current increases exponentially at higher temperatures, which can be easily overlooked when designing a consumer design. Mobile phones and personal media players are transported everywhere, and as we have all found out, temperatures experienced during the summer inside a car can easily climb above 40°C.

The amount of time the microcontroller will spend in active mode versus static mode contributes significantly to the overall application power budget.

Naturally, the ratio between active and static modes will vary depending on the application requirements. Taking the previous SPI interrupt example (second table from above) and assuming a SPI data bandwidth of 80 kb/s, the 8-bit CPU will spend 1.2% of its time in active mode compared to that of the 32-bit, which will spend 3.3% in active mode (table below).

Conclusion

Contemplating whether to use an 8- or 32-bit microcontroller for a future design may involve an Internet of things (IoT) application. How IoT actually takes shape provokes lots of debate, but it will certainly challenge engineers to make a detailed appraisal of the MCU requirement. Wireless connectivity, especially ZigBee, will also be an essential component, but that doesn’t automatically mean that it will need a higher power device.

A number of available 8-bit microcontroller products satisfy the need for low levels of processing and wireless connectivity. One such example is the Atmel ATmegaRFR2 series, which provides an IEEE 802.15.4-compliant, single-chip, 2.4-GHz wireless microcontroller solution that suits battery-powered, low-cost IoT designs.

Interested in reading more? Be sure to check out the original article from Electronic Design here.

SAM G family and Arduino Wi-Fi Shield 101 among EDN’s Hot 100 Products of 2014

Another year, another couple of spots on EDN’s Hot 100 Products list! Just announced, the industry publication has chosen both the newly-unveiled Arduino Wi-Fi Shield 101 and the Atmel | SMART SAM G family among this 2014’s hottest boards and development tools helping to enable key trends like the Internet of Things, wearables and security, as well emerging technologies such as 3D printing and wireless power.

“Of the many thousands of products announced during the past year, the EDN Hot 100 are the products that especially caught the attention of our editors and readers. We are pleased to share the tradition of showcasing these technologies as we celebrate the 21st anniversary of this program,” said Rich Pell, EDN’s Executive and Chief Technical Editor.

The SAM G ARM Cortex-M4-based MCU lineup integrates high-performance and ultra-low power in a small form factor, and is ideal for a wide-range of sensor hub and battery-operated consumer applications, including healthcare, gateways, bridges and audio devices.

Optimized for ultra-low power, high-performance applications, Atmel’s SAM G MCU family can be found in products shipping from Tier 1 OEMs around the world from wearables to sensor hub management solutions in smartphones, tablets, and other mobile devices. The family is based on an ARM Cortex-M4 core for unparalleled efficiency, and optimized with a highly efficient set of serial peripherals including a 12-bit ADC, DMA, a good SRAM-to-flash ratio and an optional floating point unit (FPU).

In the rapidly growing market for smart, connected devices in the Internet of Things (IoT) era, there is a demand for MCUs with ultra-small form factors, rich features, high performance and lower power. As a result, Atmel’s new SAM G51 and SAM G53 series meet all these requirements with 3x3mm packaging, high-performance frequency at 48MHz, ultra-low power consumption down to 100µA/MHz in active mode, 7µA in sleep with SRAM retention and down to 3µs wake-up time.

“This recognition further validates Atmel as a leading provider of smart, connected solutions for the booming IoT market,” explained Vince Murdica, Atmel Senior Director of Sensor Centric Systems Business Unit. “Atmel is committed to providing best-in-class MCU, touch, connectivity and security solutions for IoT applications. Our SAM G family sets the bar for wearables and sensor hub processing capabilities, affirmed by EDN’s selection. We’re thrilled EDN readers and editors have awarded Atmel’s SAM G family in EDN’s Hot 100 Products for 2014.”

Meanwhile, the ongoing collaboration between both Arduino and Atmel has produced a new Arduino Wi-Fi Shield 101 which made its debut at the World Maker Faire back in September. The shield looks to facilitate rapid prototyping of IoT applications on the highly-popular open-source platform.

The cost-effective, secure Arduino Wi-Fi Shield 101 is an easy-to-use extension that can seamlessly be connected to any Arduino board enabling high-performance Wi-Fi connectivity. This new device gives the design community more opportunities to securely connect applications, ranging from consumer goods to wearables, robotics, high-tech devices and more.

The Arduino Wi-Fi Shield 101 is powered by Atmel’s wireless network controller — part of the Atmel SmartConnect family — and also includes the CryptoAuthentication device which allows users to easily incorporate hardware authentication capability in their design.

Makers can now sync the shield to any modern Arduino R3 board, thereby enabling connectivity to the Internet using any traditional Wi-Fi access points. It is based on the WINC1500 802.11b/g/n network controller which features an integrated TCP/IP stack, TLS security and SoftAP for seamless provisioning. The Atmel authentication security device can be used for keys, passwords or secret data.

“In this increasingly connected world, the Arduino Wi-Fi Shield 101 will help drive more inventions in the IoT market,” explained Arduino Co-Founder Massimo Banzi. “Expanding our portfolio of Arduino extensions, this new shield can flawlessly connect to any modern Arduino board giving our community more options for connectivity, along with added security elements to their creative projects.”

With IoT, low power and security among EDN’s annual trends, it’s no wonder both the Wi-Fi Shield 101 and SAM G family have been named to the list. Want to read the entire press release? You can do so here.

Report: Smart garments are set to explode in 2016

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50% of those considering buying a smart wristband will choose a smartwatch instead, says Gartner.

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According to Gartner’s most recent report, smart wristbands will decrease in popularity over the next year as consumers will migrate to more all-purpose smartwatch devices. However, the market for smart wristbands and other fitness monitors will experience a resurgence come 2016 because of versatile designs with lower-cost displays, as well as the arrival of smart garments.

While smart wristbands are expected to dip a bit from 70 million units in 2014 to 68.1 million devices in 2015, Gartner suggests this temporary decline in sales will be a result of an overlap in functionality between the bands, fitness monitors and smartwatches. 

“Smartwatches having retail prices of $149 or more will typically have the capability to track activity and have accelerometers and gyroscopes similar to their smart wristband cousins. The smartwatches differ from smart wristbands in that smartwatches need to display the time and have a user interface oriented around communication. However, some smart wristbands have the ability to display and send text messages,” explained Angela McIntyre, Gartner Research Director.

While these wrist-adorned devices will carry on, Gartner believes the emergence of less invasive devices, particularly smart garments, will potentially disrupt the wearables space. So much so that embedded clothing shipments are projected to rise from a mere 0.1 million units in 2014 to 26 million units in 2016.

For those unfamiliar with the territory, smart garments typically refer to items ranging from t-shirts with bio-sensing circuitry woven into its fibers — which may be able to monitor vital signs more accurately given its larger body surface area — to sensor-laden athletic shoes.

The research firm believes that this product category has the greatest potential for growth going forward because “the category is emerging from the testing phase and smart shirts are available to athletes and coaches of professional teams.” Take for instance, Ralph Lauren’s Polo Tech smart apparel collection which made quite the ‘racket’ at this year’s U.S. Open. In collaboration with OMSignal, the shirt was equipped with embedded sensors, including an accelerometer, a gyroscope and a heart rate monitor.

Aside from Polo’s latest breakthrough, Adidas miCoach and Under Armour’s E39 compression shirts, e-textiles have the ability to revolutionize the manner in which data is tracked and measured in healthcare, fitness, military and industrial settings. Writing for Forbes, Robert J. Szczerba recently highlighted an array of smart garment products that are either already or will soon be available:

1)  AiQ Smart Clothing Company produces a line of smart apparel, including conductive gloves for smudge-free touchscreen use, clothes that light up, clothes that give off evenly distributed heat, and even metal mesh clothing that shields the wearer from radiation.

2)  Designer Pauline Van Dongen offers a wearable solar clothing collection. Her coats and dresses integrate solar cells that can charge your smartphone, but be obscured with fabric when not in use.

3)  SmartSox help prevent amputations in diabetes patients who have lost sensation in their feet. They incorporate fiber optics and sensors to monitor temperature, pressure, and the angles of joints in the feet, and alert the wearer or caregiver of any developing problems.

4)  Exmobaby is smart clothing designed for newborn and infants. Sensors monitor vital signs and movement, and send this information to 3G and Bluetooth components that can issue appropriate alerts.

5)  Researchers at Universidad Carlos III in Madrid, Spain have developed an intelligent hospital gown that wirelessly measures body temperature, heart rate, patient location, and whether the patient is sitting, standing, lying down, walking, or running.

“Smart garments is the newest market out there. In 2014 there really are very few of these on the market. They’re more like betas, the few that are actually being sold. But that’s why we see such large growth,” McIntyre added.

This doesn’t take into account the countless number of soft electronics DIY projects either. Inspired to create their very own smart textiles, Makers have embraced various Atmel powered platforms specifically designed for wearable applications, including the Arduino Lilypad (ATmega328) and Adafruit’s FLORA (ATmega32U4), which can be easily daisy chained with various sensors for GPS, motion and light.

Interested in reading more? Check out the latest Gartner report in its entirety here.

Walk this way! Arki does more than just count steps

Arki — which recently made its Kickstarter debut — is a stylish wearable band that not only tracks a wearer’s daily activities, but seeks to improve posture along the way. In short, the device analyzes your steps, then vibrates if and when you aren’t standing tall. Guess this means that you may want to stop looking down at your phone while you walk.

According to the American Podiatric Medical Association, the average person takes anywhere between 8,000 to 10,000 steps a day. That equates to nearly 115,000 miles — more than four times the circumference of the globe. However, are enough steps (pun intended!) being taken to maintain good posture and healthier lifestyles?

Aside from proper walking form, think of the 1,000-plus pedestrians injured annually while glancing at their mobile device. Just imagine, had the Arki been present, these epic fails (seen in the video below) may have been prevented…

The brainchild of Los Angeles and Seoul-based startup Zikto, the latest tech to adorn our wrists is powered by an Atmel | SMART SAM4LS ARM Cortex-M4 microcontroller (MCU). Ariki offers all the classic activity tracker functions, however in a rather attractive and fashionable package. A popular complaint around fitness trackers is that they are bulky and not practical to wear in professional settings. However, the newly-unveiled device caters to everyone, from activity seekers to fashionistas, with its waterproof casing and interchangeable straps to match any ensemble.

While a number of competitive bands simply collect and display the number of steps taken and calories burnt, Arki actually shares quantified measurements of the quality of steps achieved by a users.

This is done through a function they call “Sound Walking,” which alarms wearers of their bad walking postures via haptic vibrations on a real-time basis. For instance, when users are peering down at their smartphone or putting a hand in a pocket while taking a stroll, the SAM4LS controlled gadget automatically senses an imbalance of their bodies and transmits a signal.

“Arki measures your swing speed, rotation angle with respect to gravity, transferred vibration from the feet and more. Based on these measurements, Arki learns your walking habits, such as looking at a smartphone while walking or putting a hand in a pocket,” a company rep explains.

Truth of the matter, no one has a perfectly balanced body and subsequently, left and right arm swings are never identical. As the team notes, Arki utilizes this imperfection to compare the two swings to determine the extent of a body’s imbalance, including shoulders, back and hips. Normally, a user would wear Arki on their preferred side; however, Zikto advises that once in a while, by switching arms, Arki can collect both arms’ swing data. As a result, the smart band can offer personal workout recommendations to improve and recalibrate your balance.

Unlock your computer with a flick of the wrist? In what may sound like something out of Minority Report, since each person’s gait is unique much like fingerprints, Arki is also capable of biometric authentication, meaning a user simply has to move his or her mouse back and forth while wearing Arki, and can access their device.

In addition to being extremely customizable and functional, Arki also works with smart home systems to sync wearer’s thermostats to complements their physical activity. “Once Arki detects you sleeping, your thermostat will turn down to your ideal temperature,” the team notes. This makes for more comfortable nights, and more importantly, lower electric bills.

Given the tremendous success of their Kickstarter campaign, Zikto has decided to also add call and SMS notifications to Arki’s interface.

Well into its crowdfunding campaign, the team has well exceeded its $100,000 pledge goal. Following Kickstarter, Zikto is planning to expand their business to a medical service in connection with hospitals by developing its own algorithm and utilizing big data. If all goes to schedule, Zikto hopes to ship the first batch of Arkis to all backers come early April 2015. Interested in learning more or walking correctly, stroll on over to its official page here.

Video Diary: A look back at Electronica 2014

Electronica 2014 is officially in the books! Atmel was front and center in this year’s activities, as the week of November 11-14 was filled with numerous product releases, countless visitors, endless giveaways, and of course, more than 40 jam-packed application demos for the ever-growing Internet of Things.

Weren’t able to join us in Munich? Here’s a look back at how we’re inspiring next-gen M2M connections, smart homes, connected cars, Makerspaces, and more. Plenty of more videos to follow… stay tuned!

SMART HOME ZONE 

Eivind Berntsen shows off the recently-announced Atmel | SMART SAM L21.

Ramzi Al-Harayer demonstrates the WINC1500, an IEEE 802.11 b/g/n IoT network controller SoC.

Dr. Attila Römer exhibits some of the latest (and smartest) lighting solutions, including the Philips Hue LED colormix bulb, the Philips Lux dimmable bulb and the Philips Tap switch.

INDUSTRIAL ZONE 

Highlighting the need for security in the connected world, Atmel’s resident security expert Kerry Maletsky shows off a three-light switch demo that communicates via ZigBee to a remote panel with 3 LEDs.

Dr. Peter Sauer highlights the SIGFOX network infrastructure and various Internet of Things applications.

Thomas Souche explores the mulit-touch capabilities of a maXTouch powered industrial control panel from Siemens.

Eirik Slettahjell showcases the SAM D20 QTouch Evaluation Kit, demonstrating best-in-class capacitive touch performance.

Alexander Kurz reveals how digital temperature sensors can be implemented to prevent overheating in your product.

AUTOMOTIVE ZONE 

Not only is our world becoming increasingly more connected, our cars are getting smarter as well. Rob Valiton explores the future of automobiles in the Internet of Things era.

A closer look at passive entry and passive start for automobiles through capacitive touch and proximity detection technology.

Rob Valiton takes us through a next-gen door handle application powered by our fourth generation LIN system.

MAKER ZONE

Former AVR Hero winner Pamungkas Sumasta and Ralf Smit introduce their all-in-one, Arduino-compatible prototyping gadget — which is now live on Kickstarter.

Tired of always having to sort through Skittles to find your favorite color? This Maker-built, SAM D21 powered machine will take of that tedious task for you!

Paal Kastnes maneuvers a remote-controlled robot powered by the Atmel | SMART SAM D21. “Mr. Abot” is controlled through an Andriod app, while the communications are driven through our recently-announced new WINC1500 Wi-Fi solution.

Some of the news you may have missed…

Jacko Wilbrink shares an update on the Atmel | SMART SAMA5D4 and ARM Cortex-M7 based MCUs.

Low power gets three times lower with the Atmel | SMART SAM L21 ARM Cortex-M0+ MCU.

A new QTouch safety platform is introduced for home appliance user interfaces.

Your favorite 8-bit AVR MCU family gets even bigger.

The SAM W25 becomes the industry’s first FCC-certified Wi-Fi and MCU integrated module.

The new CAN transceiver lineup meets the growing demands of the auto and industrial markets.

The recently-unveiled LIN system basis chip portfolio enables a wide-range of in-vehicle applications.

Atmel’s AvantCar is a fully-functional concept to meet the growing demand for new features and technological upgrades in tomorrow’s vehicles.

IAR Systems supports Atmel’s complete MCU and MPU portfolio, expanding its IoT software and tools ecosystem.

The ATA8520 device becomes the first SIGFOX Ready-certified system-on-chip (SoC) solution.

And to wrap up the week in winning fashion, the Atmel based SatNOGS is crowned the Hackaday Prize champion!

1,400 new example projects in IAR Systems’ dev tool support entire Atmel MCU and MPU lineup

We have just announced the extension of our partnership with IAR Systems have to include over 1,400 new example projects in IAR Systems’ development tools to support Atmel’s entire portfolio of world-class MCUs and MPUs.

Designers using both Atmel AVR and Atmel | SMART family can now leverage IAR Embedded Workbench, the leading C/C++ compiler and debugger toolchain, with new example projects to bring their products faster to market. With all the information available to a developer at the start of a project, including over 1,400 new examples from the Atmel Software Framework (ASF) for reference designs across a broad range of applications and Atmel’s Xplained Pro family of evaluation boards, this significantly increases developers’ productivity.

ASF is a large library of free source code for Atmel | SMART ARM and highly-popular AVR devices. This framework minimizes much of the low-level configuration and design required for projects to get off the ground, by providing hardware abstraction with consistent APIs, as well as high-value middleware components designed for evaluation, prototyping, design, and production phases.

“We are committed to providing simple, yet sophisticated tools for our designers’ complex development,” said Steve Pancoast, Atmel Vice President of Development Software and Tools. “Since the introduction of our AVRs in the early 90s, IAR Systems has always been an important partner for us, providing world class tools to our most demanding users. The integration of our reference application examples into IAR Embedded Workbench will reduce overall time-to-market for developers, enabling them to bring products faster to market.”

“High-performance development tools are critical for success in today’s advanced embedded systems designs, specifically for the Internet of Things and connectivity markets,” added Stefan Skarin, IAR Systems CEO. “IAR Systems’ position is unique in that we are the only commercial vendor able to provide this, as well as our world class support, across Atmel’s entire range of microcontroller architectures.”

Day 1: Atmel @ Electronica 2014

Day 1 of Electronica 2014 in Munich, Germany has drawn to a successful close. Surely enough, it didn’t take long before the Atmel booth — located in Hall A5, #542 — was jam-packed, hosting countless engineers, designers, partners and industry insiders throughout an exciting nine hours.

While at the booth, visitors had the opportunity to check out a plethora of our recently launched products like the new megaAVR family, the super low power Atmel | SMART SAM L21, the QTouch Safety Platform and our fourth generation LIN device, as well as an extensive lineup of interactive demos ranging from CryptoAuthentication to the futuristic AvantCar center console concept.

In addition to an assortment of IoT solutions, Atmel’s AVR Hero Design Contest winner Pamungkas Sumasta was on hand showing off the latest rendition of the award-winning, all-in-one Phoenard platform — which is slated to hit Kickstarter later this week.

Heading to Messe Münche later this week? Learn more about all the tech you can expect to see here. Meanwhile, stay tuned for more on Bits & Pieces for updates from the show floor, and be sure to follow along with all the real-time happenings on Twitter!