Designing an industrial control panel with Atmel’s SAMA5D3

An industrial control panel or terminal provides a visual interface for operators to monitor and control equipment, typically in a factory setting.

Clearly, industrial control panels must support high-end graphics without negatively impacting system communication. And in today’s connected world, the panels must also be capable of linking and seamlessly interfacing with a wide variety of external peripherals as well as accessories.

Atmel’s SAMA5D3 (ARM) Cortex-A5 eMPU, paired with a maXTouch-powered display, is an industrial control panel platform that is more than capable of fulfilling the above-mentioned requirements.

“Atmel’s platform offers high processing power and bandwidth for optimized graphics performance with the ARM Cortex-A5 based SAMA5D3 – which boasts a fully integrated MMU and a floating point unit to accelerate graphics processing. Meanwhile, our 32-bit DDR-2 memory interface provides high bandwidth to support high resolution screen displays and render complex animation,” an Atmel engineer told us.

“We also offer three high-speed USB Ports with integrated PHY, providing simultaneous support for three USB clients – which removes the need for an external hub. Plus, there are multiple interfaces available, including Gigabit EMAC with full IEEE 1588 support.”

In terms of graphics, the SAMA5D3 offers integrated resistive touch screen support, along with a direct interface to an external (maXTouch) capacitive touch screen module. On the software side, support for Linux 3.6.6 includes sources, pre-built demos with installation scripts, build instructions, along with various tips and tricks.

Atmel’s extensive development system also includes in-house and third-party modules, kits, OS/RTOS/Middleware and UI options, with the SAMA5D3-EK Evaluation Kit enabling rapid code development.

Additional information about the SAMA5D3 can be found here.

Designing portable fitness devices with Atmel’s SAMA5D3 eMPU lineup

Atmel’s lineup of ARM Cortex-A5 processor-based eMPUs (embedded microprocessor units) do not compromise when it comes to performance, power and ease of use.

Operating at 850DMIPS at under 200mW, the SAMA5D3 eMPU is ideal for a wide range of high-performance, low-power and cost-sensitive industrial applications, including control panels, smart grid devices and bar code scanners.

Of course, the SAMA5D3 eMPU lineup can also power fitness and outdoor portable electronic equipment, which are often used to measure performance (or provide navigation) for various outdoor activities, including running, cycling, hiking and golf.

Such devices offer low active and standby power consumption, while reducing battery size and extending time between charges and offering fast wake up to respond to user commands.

Key (supported) features include direct support for TFT displays, capacitive touch,
camera sensors and audio. On the software side, designers can look forward to Atmel’s extensive SAMA5D3 dev ecosystem, which offers up in-house as well as third-party suppliers in modules, kits, OS, RTOS, Middleware and UI solutions. Atmel also provides and supports Linux 3.6.6 as well as Android 4.0 (ICS) packages, while the SAMA5D3x-EK evaluation kit facilitates quick evaluation and development.

Interested? Additional information can be found on Atmel’s SAMA5D3 ARM Cortex-A5 eMPU homepage.

Atmel’s SAM4L ARM MCU tech powers game controllers

Atmel’s SAM4L ARM-based microcontroller lineup redefines the MCU power benchmark, delivering the lowest power in both active (90µA/MHz) and sleep modes – 1.5µA with full random access memory (RAM) retention and 700nA in back-up mode.

Simply put, the SAM4L lineup is the most efficient MCU tech available today, achieving up to 28 CoreMark/mA (using the IAR Embedded Workbench), while also offering the industry’s shortest wake-up time at 1.5µs from deep-sleep mode.

The SAM4L is targeted at a wide variety of portable and battery-powered consumer, industrial and medical applications.

However, the MCU lineup can also be used to power next-gen game controllers, along with related Atmel tech like the AT24C/AT25/AT93C serial EEPROM and ATR2406 RF transceiver.

On the software side, designers can look forward to an extensive ecosystem from Atmel and its partners, with an integrated development environment (IDE) and compiler (Studio 6 is free and integrated), along with multiple libraries.

And last, but certainly not least, there are also production-ready software packages available for drivers, software services and libraries. Interested? Additional information can be found on Atmel’s SAM4L MCU page here.

Video: Enabling ethernet ports on Atmel’s SAMA5D3 (Linux)

Today, we take a closer look at how to enable ethernet ports on Atmel’s SAMA5D3 in a Linux demo environment.

As Atmel’s Sr. ARM Application Engineer Swapna Gurumani notes, simply typing “ifconfig” at the command prompt does not show the existing (ethernet) ports. Watch the video below for more information.

In addition to taking a closer look at enabling the SAMA5D3’s ethernet ports in a Linux environment, Gurumani offers up a quick talk on the subject of cross compiling for the very same ARM-based microcontroller running Atmel’s Linux-based demo package. See the video below for additional data.

Achieving a secure lockdown with Atmel’s ATSHA204

Despite its obvious importance, security often takes a backseat when it comes to designing a device or electronic component.

Perhaps one of the most shocking examples of security failure in the electronic world was highlighted last year during the Black Hat conference when a hacker demonstrated how he used a simple microcontroller to compromise hotel room doors by accessing 32-bit keys.

Unfortunately, the above-mentioned breach is hardly an isolated incident, as hacks for poorly secured hardware can be found swirling around the internet ether where they are routinely bought and sold by less-than-savory elements.

While it may seem somewhat daunting, securing a device can be made easier with an optimized authentication chip like Atmel’s ATSHA204 which includes a 4.5Kb EEPROM. This array can be used for the storage of keys, miscellaneous read/write, read-only, password or secret data. As expected, access to various sections of memory can be restricted in a variety of ways, with the configuration locked to prevent changes.

The chip also boasts a number of defensive mechanisms specifically designed to prevent physical attacks on the silicon itself or logical attacks on the data transmitted between the chip and the system. Plus, each ATSHA204 ships with a unique 72-bit serial number. By using the cryptographic protocols supported by the chip, a host system or remote server is able to prove the serial number is authentic and not a copy.

In addition, the ATSHA204 is capable of generating high-quality random numbers and employing them for any purpose, including usage as part of the crypto protocols of the chip. Access to the silicon is granted via a standard I²C interface at speeds up to 1Mb/sec. And last but certainly not least, it is compatible with most UART or serial IO controllers.

So that’s the physical spec rundown, but what about specific attacks ATSHA204 is designed to shield against? Well, the authentication chip is capable of helping to protect devices from a variety of nefarious threats, including algorithmic, protocol, microprobe, environmental, timing, bug, dumpster diving, emissions, fault and power cycling.

Meanwhile, a secure boot system prevents unauthorized modification of host firmware and protects against hackers enabling extra features without payment. And last, but certainly not least, the ATSHA204 helps thwart illicit system copies, piracy and code reverse engineering.

So while securing a device may seem like somewhat of a daunting task, especially in the face of so many critical threats, Atmel’s ATSHA204 is a comprehensive hardware-based solution that offers full applications support for both AVR and ARM systems, while helping to streamline and optimize the lockdown process.

The ARM-Atmel Churchill Club connection

Early this morning, journalists, analysts and industry watchers gathered at the Churchill Club in San Francisco to discuss cross-industry collaboration between ARM and its extensive network of partners.

Collaboration is often easier to talk about than achieve in Silicon Valley, yet ARM has been incredibly successful with its licensing model, generating an ecosystem that spans multiple industries and spaces – including the incredibly lucrative mobile market.

“ARM is in a fantastic state of health. Of course there are lots of challenges ahead, but we are confident our open partnership model is the way forward,” said incoming CEO Simon Segars.

“We have always thrived on a culture of collaboration from the very beginning, an attitude which has only increased with the rise of the Internet and social networking.”

Segars also noted that ARM had begun as a small start-up in a converted farmhouse with a limited budget.

“From the start, we knew we couldn’t do everything ourselves, and needed partners to make it work,” he said. “So we have always worked very closely with people from various industries.”

Clearly, ARM’s strategy has paid off over the years, as the Cambridge-based company has built up an impressive portfolio of collaborative IP projects with a number of industry heavyweights.

One example of close collaboration with ARM is the use of the company’s architecture in a number of Atmel microcontrollers, including the recently launched SAM4E and SAMA5D3.

As previously discussed on Bits and Pieces, the SAM4E is based on ARM’s high-performance 32-bit Cortex-M4 RISC processor with a floating point unit (FPU). It runs at a maximum speed of 120MHz and features up to 1024KB of Flash, 2KB of cache memory and up to 128KB of SRAM. Meanwhile, the SAMA5D3 is built around ARM’s Cortex-A5 processor, operating at up to 536MHz (850DMIPS) at under 200mW.

There are obviously many more examples of collaboration between Atmel and ARM which can be found here.

Rako starts at Atmel

Some of you might recognize me from my previous job at EDN magazine. I covered the analog beat. So many of my friends were surprised to hear I was joining Atmel. What they did not realize is that being an analog expert is only part of what I love. I ran a consultation business for 20 years. My specialty was designing, prototyping and delivering working hardware. One of my favorite jobs was in 2001, at a startup where I designed a complete point-of-sale terminal in only 2 months. I knew I would need help doing the software, so I called my friend Dave Mathis. He agreed to write the code, but only if I used a modern micro. Not knowing any better, I suggested a well-known micro. He said he would quit if I used that hardware. He refused to program one, after more than a few bad experiences. Then I figured we could use an 8051 clone. He said that he really did not want to deal with special function registers. OK, this was going nowhere fast, so I asked him what he thought would be a good embedded processor. Dave had written Forth compliers for Samsung micros, so I didn’t know what to expect. He said I should check out Atmel. I did. I was impressed. I had been exposed to Atmel micros when I was consulting to HP. They ran wicked fast and did not need 8 clocks to execute an instruction. The other thing I loved is that I could get a Butterfly prototyping board for $49.95, and a real in-circuit emulator for $200. When you are in a startup in angel-investment mode, that low barrier to entry really means a lot.

So I picked a nice little AVR micro that did everything we needed and more. I wrote the assembly language firmware for the point-of-sale terminal as well as some other products we developed. I hired two buddies to write some C code. I see why Dave recommended Atmel. Wags have joked: “The best programming language is the programming language your best programmer likes best.” I really like the Atmel development system and the chips worked great. Both buddies have gone on to love and use Atmel micros in their projects as well.

So I am really looking forward to document how Atmel can make your design work go better. I will be getting up to speed on Atmel’s touch technology and will share with you what I learn. I am also looking forwarded to getting into the ARM controllers. That is some heavy iron to an 8- and 16-bit guy like me, but my buddy Dave will point me in the right direction and I am sure my co-workers here will put up with my questions.

When Sander Arts asked me to join him at Atmel, the first thing I did was call my pal Dave. We thought Atmel was cool and we knew it 13 years ago. But I was not sure of how Atmel was doing in the eyes of the world. Dave said “Atmel’s star has really risen in the last 5 years.” The Arduino was part of that. But he said people were also seeing how cool the Atmel ARM stuff was. And the whole world was seeing what Dave saw in 2000, how Atmel can get you into 8-bit development cheaply, and how nice the code works. When I was at the Design West conference this year (2013) I saw my buddy Windell Oskay, the co-founder of Evil Mad Science. When I told him I was starting with Atmel he was really jazzed. He said that he loved the Arduino and the whole development ecosystem that has sprung up around it.

In addition to telling you about all the cool things Atmel is up to, I will be sure to keep you informed of all the fun things my pals are doing. This includes lifestyle things like the electronic flea market here in Silicon Valley and career things like how my crack protégé has figured out a LinkedIn profile that gets him 3 headhunter calls a week. Stay tuned and look for all the system design scuttlebutt that will help you be a better engineer and programmer.

Intelligent MCUs for Low Power Designs

By Florence Chao, Senior Field Marketing Manager, MCU Business Development

Industrial and consumer devices using ARM® Cortex®-M4

Blood glucose meters, sport watches, game controllers and accessories, guess what they all have in common. Yes, like a lot of other industrial and consumer devices, they run on batteries and demand long or extended battery life. As an engineer, this translates into a key challenge when designing an embedded computing system. You need a central heart—in this case a microcontroller—that consumes as little power as possible in both active and static modes yet doesn’t sacrifice performance.  The Atmel® SAM4L ARM® Cortex®-M4 based series is designed with this in mind.

The SAM4L microcontroller redefines low power, delivering the lowest power consumption in its class in active mode (90uZ/MHz) as well as in static mode with full RAM retention running. It also delivers the shortest wake-up time (1.5us). At the same time, this is the most efficient microcontroller available today, achieving up to 28 CoreMark/mA.

The SAM4L series integrates Atmel’s proprietary picoPower® technology

The SAM4L series integrates Atmel’s proprietary picoPower® technology, which ensures the devices are developed from the ground up—from transistor design to clocking options—to consume as little power as possible. In addition, Atmel Sleepwalking technology allows the peripherals to make intelligent decisions and wake up the system upon qualifying events at the peripheral level.

In this video, you will see how the SAM4L microcontroller supports multiple power configurations to allow the engineer to optimize its power consumption in different use cases. You will also see another good feature of the SAM4L series, Power Scaling, which is a technique to adjust the internal regulator output voltage to further reduce power consumption provided by the integrated Backup Power Manager Module. In addition, the SAM4L series comes with two regulator options to supply system power based on the application requirement. While the buck/switching regulator delivers much higher efficiency and is operational from 2 to 3.6V. The linear regulator has higher noise immunity and operates from 1.68 to 3.6V.

The Atmel® SAM4L ARM® Cortex®-M4 based Microcontroller

It’s all about system intelligence and conserving energy. Simply put, the SAM4L microcontroller is your choice if you are designing a product that requires long battery life but you don’t want to sacrifice performance.  To get started, learn more about Atmel SAM4L Xplained Pro Evaluation and Starter Kits.

News from the Gallery

News from the Gallery

By Joerg Bertholdt, Director of Marketing, Tools and Software, Atmel Corporation

We launched Atmel Gallery less than 6 months ago, the first app store of its kind to deliver integrated embedded tools and embedded software straight into a development environment, specifically for Atmel Studio 6.

We were excited to get into uncharted territory, but also anxious about the types of reaction we’d get from our customers. It’s time to see how we did.

With over 25,000 developers – and counting — signed up for a Gallery account, our expectations have by far been exceeded. The servers handled the big demands very well, proving the infrastructure design and scalability.

Keil MDK-ARM Toolchain from Keil enables Atmel Studio to use its highly optimizing ARM compiler

With the February update of the XDK, the Extension Developer’s Kit, partners have been able to easily integrate embedded software and package integrations as projects that install directly into Atmel Studio. For example, developers who are interested in exploring commercial real-time operating systems, now have access to Micrium’s uC/OS and Segger’s embOS. Trial versions of these RTOSes are available as ready-to-run example projects for Atmel’s ARM Cortex-M4 based SAM4S devices.

Two popular extensions are compiler plug-ins. The Keil MDK-ARM Toolchain from Keil enables Atmel Studio to use its highly optimizing ARM compiler. CodeVisionAVR allows the use of HP Infotec’s AVR compiler, which also includes CodeWizardAVR, a graphical peripheral configuration tool for AVR MCUs.

Besides development tools and embedded software extensions, training modules such as Integrating USB In Your Design have also been made available through the Gallery. With the XDK supporting the development of hardware extension boards for Atmel’s Xplained Pro kits, the drivers for the first Xplained Pro partner board will soon be delivered as an Atmel Studio project.

We’re six months in and happy to see the masses have adopted Atmel Gallery.

Are you a Gallery user? Let us know what you like, what you’d like to see improved or if there are additional extensions you would want to see. Just comment on this blog or send me an email to joerg.bertholdt@atmel.com.

Haven’t checked out the Gallery yet, just take a look at gallery.atmel.com. Don’t have Atmel Studio 6? It’s free, you can download it from atmel.com.

Are you an independent software vendor or developer and want to be part of the growing Atmel Studio ecosystem, join the Gallery as a developer; the XDK makes it easy to participate.

1:1 interview with Michael Koster

Series 3 – Why IoT Matters?

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By Tom Vu, Digital Manifesto and Michael Koster, Internet of Things Council Member

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Three-part Interview Series (Part 3)

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Tom Vu (TV):  Describe how Internet of Things matters? Why should anyone care? Should futurist, technologist, data hounds, product extraordinaires, executives, and  common consumer need to understand what’s to come?

Michael Koster (MK):

There are two main effects we see in the Internet of Things. First, things are connected to a service that manages them. We can now monitor things, predict when they break, know when they are being used or not, and in general begin to exploit things as managed resources.

The second, bigger effect comes from the Metcalfe effect, or simply the network effect, of connecting things together. Bob Metcalfe once stated that the value of a communications network is proportional to the square of the number of connected compatible communicating devices. Since then it’s used to refer to users, but maybe Bob was thinking way ahead. Notice the word compatible. In this context, it means to be able to meaningfully exchange data.

When we connect physical objects to the network, and connect them together in such a way as to manage them as a larger system, we can exploit the Metcalfe effect applied to the resources. We are converting capital assets into managed resources and then applying network management.

Because Internet of Things will be built as a physical graph, it’s socialization of everything, from simple everyday devices to industrial devices. Metcalfe states that 10X connections is 100 times the value.  Cisco is projecting that the Internet of Everything has the potential to grow global corporate profits by 21 percent in aggregate by 2022. I believe these represent a case for pure information on one end, and an average efficiency gain over all of industry on the other.

This has the potential to change things from a scarcity model, where the value is in restricting access to resources, thus driving up price, to a distribution centered model, where value is in the greater use of the resource.  Connecting things to the network is going to reverse the model, from a model of “excluding access” to “inclusion access”, a model where you push toward better experience for consumer/customer/co-business.

Crowdsourcing of things is an example, where models are inverted.  The power arrow is going in the opposite direction, a direction equalizing toward the benefit of the massive body consumers and people.  This in turn, helps shift the business model from a customer relationship managed by vendors, also called advertising, to vendor relationship managed by customers. This is called Vendor Relationship Management, or VRM, pioneered by Doc Searls. This reverses the power arrow to point from customer needs toward business capability to meet needs, and needs are met now that the vendor is listening.  A lot of this is not just IoT but also open source nature, and the big changes happening in people, where sharing being held more valuable than the exclusion of access.

Inverting the value model, breaking down artificially bloated value chains, creating a more efficient economy, I believe it important to create a layer of connectivity that will act as the necessary catalyst to the next Internet of Everything, Internet of Things, Industrial Internet.  Break down the scarcity-based models, exclusion of access, turn it around. Instead of excluding access and driving prices up for limited resources, we will yield higher more efficient utilization of resources.

Michael Koster describing Internet of Things and the Maker Movement and Open Source Importance of this Development with Booth attendees at Maker Faire 2013 in San Mateo

It matters on a Global Scale, by giving us better resource utilization. SMART Grid alone has resulted in up to 19.5% efficiency improvement, with an average of 3.8% improvement over all deployments already. We do not have enough energy storage or transmission capacity to deal with the major shift to solar energy sources now in progress worldwide. We are going to have to adapt, learn, monitor, manage, and control our usage in ways only possible with large scale sensing and control.

For the spirit of IoT, it’s not only in making peoples/consumers lives more convenient, solving their first world problems, but its more in the ability to manage resources together as a larger system, from the individual out to a global scale. Especially, this holds true with the effects of globalization, balancing, localization, connectivity, and ubiquity.  It’s for the people.  Social Media had it’s transformation across many things, Internet of Things will also have an efficiency and business transformation.

Companies like Atmel play an important role in creating the building blocks for embedded control and connectivity by means of progressing the ARM / AVR / Wireless / Touch portfolio of products, all of which are the necessary thinking and connecting glue of the Internet of Things. Internet of Things has a large appetite for ultra low power connectivity using wireless standards.  Wireless Sensor Networks are key technology for the IoT, so much that WSN was probably the number one issue in the early deployment. There are many competing standards: Zigbee, SA100.11, Bluetooth, Body Area Network, Wi-Fi Direct, NFC, Z-Wave, EnOcean, KNX, XRF, WiFi, RFID, RFM12B, IEEE 802.15.4 (supporting WPAN such as ZigBee, ISA100.11a, WirelessHART, IrDA, Wireless USB, Bluetooth, Z-wave, Body Area Network, and MiWi).

Michael Koster Exhibiting with Atmel Booth at Maker Faire 2013 San Mateo

Tom Vu (TV):  What would be the most important design decision that supersedes the eventual success of an open source Internet of Things compliance?

Michael Koster (MK):

The first most important decisions are to do open source design based on needs and use cases. I don’t think we can build an IoT if its not open source, or if it’s not connected to the real world use cases.

Just like the Internet, built on open source and open standards, the starting data models are important for building on and building out. HTML and http and URLs allowed many platforms to be built for the web and supersede each other over time, for example Server Pages, SOAP, Javascript, and AJAX. A browser can understand all of the current platforms because they are all based on common abstractions. We believe that the Semantic Web provides a solid basis of standard web technology on which to base the data models.

Tom Vu (TV):  Describe the importance of Internet of Things silos and other M2M standards currently at large in the development community? What are the differences?

Michael Koster (MK):

The IoT has started off fueled by crowdfunding, VC money and other sources that have to some extent built on a business model based on vertical integration. Vertical integration has a big advantage; you need to have a self-contained development to get things done quickly for proof of concept and demonstration.

Vertical integration is also a big driver of the current machine-to-machine, or M2M, communication market. This is the paradigm supporting the initial deployment of connecting things to services for management on an individual thing basis.

The downside of vertical integration is that it leads to silos, where the code developed for a system, the data collected, and even the user interfaces are all unique to the system and not reusable in other systems. Moreover, the vertical integration is often seen as a proprietary advantage and protected through patents and copyrights that are relatively weak because they apply to commonly known patterns and methods.

It’s not always this way, though. As an example, the Eclipse foundation is open source, allowing their M2M system to be used for vertical application development as well as integrated with IoT Toolkit data models and APIs to enable interoperability with other platforms.

The European Telecommunications Standardization Institute, or ETSI, also has an M2M gateway that is a combination of open source and paid license code. New features are enabled through Global Enablers or GEs that implement a particular function using an OSGi bundle consisting of Java code. The Smart Object API can be built into ETSI through a GE bundle, which will enable an ETSI M2M instance to inter-operate with other IoT Toolkit instances. This is the power of the approach we’re taking for interoperability, which is obtained by adding a Smart Object API layer to the system.

Tom Vu (TV):  Explain horizontal and service interoperability for Internet of Things, why is it so important?

Michael Koster (MK):

Connected things connect through WSN gateways and routers to Internet services that fulfill the application logic for the user. Today, for the most part, each vendor provides a cloud service for the devices they sell, e.g. Twine, Smart Things, or the Nest thermostat. There are also some cloud services that allow any connection, providing an API for anyone to connect, for the purpose of integrating multiple devices. But the dedicated devices mentioned earlier don’t work with the generic cloud services.

Many IoT services today are based on providing easy access to the devices and gateway, with open source client code and reference hardware designs, selling hardware on thin margins, and Kickstarter campaigns. There is typically a proprietary cloud service with a proprietary or ad-hoc API from the device or gateway to the service, and a structured API to the service offering “cooked” data.

These systems contain a highly visible open source component, but much of the functionality comes from the cloud service. If a user wishes to use the open source part of the system with another service, the APIs will need to be adapted on either the device/gateway end or service end, or both. It’s not exactly a lock-in, but there is a fairly steep barrier to user choice.

Internet of Things (IoT) in Silos

There is the beginning of an ecosystem here, where some devices are being built to use existing services, e.g. Good Night Lamp uses Cosm as their cloud service. Other services that allow open API connectivity include Thingworx and Digi Device Cloud. These services all use very similar RESTful APIs to JSON and XML objects, but have different underlying data models. As a result, sensors and gateways must be programmed for each service they need to interact with.

The current system also leaves users vulnerable to outages of a single provider. Even if there was a programmable cloud service that all could connect to that ran user applications, there would be a vulnerability to provider outages. Much better and more robust would be an ability to configure more than one service provider in parallel in an application graph, for a measure of robustness in the face of service outages. Even more, it should be possible to run user application code in IoT gateways, local user-owned servers, or user-managed personal cloud services. Today’s infrastructure and business models are at odds with this level of robustness for users.

In terms of business and business models, a lot of the connection and network infrastructure today was built on a “value chain” model. These are businesses that are built on a model of vertical integration. In these models, value is added by integrating services together to serve one function, hence vertical.  With the Internet of Things, traditional value chains are collapsing down and flattening. There is a bit of a disruption in the business model (services, etc), but also new opportunities emerge to create new Internet of Things services, which is good for business and consumers.

Companies will continue to build out vertical models to specialize in their services. IoT can potentially augment service models with the customer even further and offer creative possibilities of cost savings and experience and deploy more customer centric business fabrics, which will result in better service for consumers.

If companies build their vertically based infrastructure of applications integrating into the IoT Toolkit platform, the basic enablement for horizontal connections will already exist, making it easy to create horizontal, integrative applications based on automatic resource discovery and linkage.

Access to the knowledge can enhance the customer experience and ROI for businesses.  We are at the brink of the new era, where companies and products can arise from the information economy; only now motivation via implicit or explicit engagement is tied to things, assets, information, sensors, education, and augmentation; and everything is more intertwined and involved.

Tom Vu (TV):  Please assume the role of a futurist or even contemporary pragmatist. How does the landscape of Internet of Things fit into that picture for an individual?

Michael Koster (MK):

It goes back to the idea that your life is going to change in ways that we are no longer be driven by the scarcity pressures we experienced as hunter gatherers. IoT will trigger the overall shift from the resource accumulative, to the interaction driven and resource sharing-enjoying model due to the ubiquitous connectivity and the right kind of applications we can use to bring this experience to maturity.

We expect the Internet of Things to be where the interaction moves away from screens and becomes more like everyday life, only more convenient, comfortable, and easy to manage. We’re still looking for the valet, the system that simply helps us manage things to enable us to become more as people.

Tom Vu (TV):  Do you have any insights into how industries like Semi-Conductor can help share the responsibility of making Internet of Things for the People and by the People?

Michael Koster (MK):

Yes, of course, everyone has a part in the build up and build out of Internet of Things.  From business to academia, in the home and across the planet, the march to Internet of Things is inevitable.  Again and again, the familiar signs of disruption are being seen.  We see that happening today with the very first initial releases of connected products.  There is a movement in Makers, with substantial global activity. Which is quite harmonious to open source and open hardware.  This will be even wider spread once critical mass takes effect with products more and more becoming connected and smart via Internet.  The power of the sensor proliferation is akin to Twitter having 10 people registered and using their Social Fabric versus 100s of millions.  The more everyday devices and things are connected, the more the power of IoT will overwhelmingly surface.

It’s only how well we integrate and collaborate together across industry to propel this next phase of Internet to the next level.  Every potential disruptive technology has a turning point.  We are at that point and we are all part of this movement. In turn, the Internet of Things will make better products, a better user experience, and optimized efficiency across all resources. How we decide to apply this technology will make all the difference.

This very notion forces industries to be more aware, efficient, and productive. Sensors and connected devices will help supply chain, manufacturing, research, product roadmaps, experience, and ultimately drive an economy of growth. The enterprise begins to have a visibility, transparency to customers, people.   Ultimate, it’s a true nervous system, connected via an enterprise level to a personal consumer level.

SMART, AWARE, and SENSORY are new enhancements to business to include customer habits and patterns of use, threaded right into the production routine and product design. Internet of Things will help sculpt a more consumer oriented and customer centric world of products. Customers will have direct influence in the manufacturing of individual products and instances of products.  Companies can help by being part of the community, albeit in the field of electrical engineering, design, data, to software development on the cloud.  Internet of Things will have touch points between customers and business as much as the electrical power grids have influence across all business today.

The new ecosystem will have micro scale and agile manufacturing at a level of customization unimaginable today. It’s the next driver for brilliant machines, maybe artisan-machines that work for individuals but still live on the factory floor.

You can work with the developers and work toward expanding businesses that can embrace the development world.  Help build the $50 cell phone or connected devices that bridge fiscal and energy compliance for a better world.

Ride the long tail wave… and the inverted business models…  Make more accessibility to all products and be responsible in accessibility… From crowdfunding or crowdsourcing, like Kickstarter or Makers, someone is going to figure out how a sensor can do more, in a very impactful and human experience paradigm. The new innovations will come from everywhere; from the 14 year old in Uganda who takes apart her cellphone to repurpose it into a medical monitoring device, from the basements and garages of millions of makers and DIY’ers worldwide who have sure genius among them.

It is super important to get the very latest hardware out to the open community so that innovation can be leveraged, taken to new levels of creativity and crowdsource ideation for collaboration and massive cross-contribution. Accessibility, documentation, development, ecosystem for software support for the MCUs are all too important.  Atmel holds building blocks to many of these pieces, combined with their development tools and evaluation ecosystem (Atmel Studio 6, Atmel Spaces, Atmel Gallery) and involvement with Makers and Arduino.

Open Hardware / Open Source will come to be de-facto standards.  Bundle open source along with the open hardware to make it even more accessible and embed rapid guide start for newcomers. Right now a key piece is the Wireless Sensor Net. If there were a good open source WSN available and supported by manufacturers, it could enable a groundswell of connected devices.

Build open source and open hardware educational IoT developer’s kits for ages 8 and up, for high school and college, to hit all levels of involvement and expertise. Support community hackspaces and places (ie Noisebridge) where everyone can learn about the digital world and programming.

We are seeing the leveling out of the development happening in all parts of the world. Radical innovation is happening everywhere. Open Source is helping shape this curvature.  This is the broader whole tide that we are seeing. Pinocchio is one great innovation emerging from Makers and Open Source, then we have IoT hubs such as SmartThings, Thingworx, or Xively (formerly Cosm).  There is a lot of crowdfunding, ideation, blooming of disruptive products looking to change the scene of things to come….
Support open source and open collaboration in everything, to create a culture of sharing and innovation, a culture of synergy in building the Internet of Things together. Involve customers as participants and makers of their own experiences. Make sure everyone has access to the information and support they need to build, maintain, hack, and repurpose their devices over time to promote a healthy ecosystem.

This time innovation is going global. The ideation is happening everywhere. There are many global Silicon Valley type hubs, other metros in the world, as well as global accessibility to the same information. We see startup mentality blossoming across all geo-locations.  Again, Semi-Conductors is contributing, helping pave the back-plane for innovation & connectivity for the development layers on top.  Global village of innovation is coming of age… Now.

 

Also read Part 1 and Part 2 of the Interview Series.