SMART MCUs for low power, smarter designs in Internet of Things, wearables, and the Industrial Internet

According to analysts at ABI Research, over the next five years businesses will integrate into their wellness plans more than 13 million wearable devices with embedded wireless connectivity. Wearable tech also ties into the rapidly evolving Internet of Things (IoT), which refers to a future world where all types of electronic devices link to each other via the Internet. Today, it’s estimated there are nearly 10 billion devices in the world connected to the Internet, a figure expected to triple to nearly 30 billion devices by 2020. The inherent versatility of Atmel | SMART microcontrollers and Atmel radio chips have made our silicon a favorite of Makers and engineers.

Along with this setting stage, the design aspects for low power are becoming more and more important in the next embedded design products. Atmel is right in the middle of the industrial and wearable tech revolution, with a comprehensive portfolio of versatile microcontrollers (MCUs) that power a wide range of platforms and devices.

Blood glucose meters, sport watches, game controllers and accessories, guess what they are all in common? In fact, many of these today are going to shift and evolve into new form factors and application use case as connectivity and clever interacting interfaces become designed. Yes, like a lot of other industrial and consumer devices, they are all battery powered and demanding a long or extended battery life. Translating it into an engineer’s challenge designing an embedded computing system, you will need a central heart, in this case a microcontroller, consuming as low power as possible in both active and static modes without sacrificing the performance. And, Atmel SMART | ARM Cortex-M4 based SAM4L series is designed with this in mind.

The SAM4L microcontrollers redefine the low power, delivering the lowest power in the same class in active mode (90uZ/MHz) as well as static mode with full RAM retention running and with the shortest wake-up time (1.5us). And they are the most efficient microcontrollers available today, achieving up to 28 CoreMark/mA. In this video, you’ll get an overview of Atmel | SMART SAM4L low-power microcontrollers (MCU), based on the ARM Cortex-M4 core. SAM4L MCUs operate at 90uA/MHz and achieve an efficiency rating of 28 CoreMark/mA. The devices feature an array of power-saving technologies, including Atmel’s proprietary picoPower technology. You’ll see a demo using the SAM4L-EK evaluation kit.

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’s 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 SAM4L microcontrollers support 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. Additionally, the SAM4L series comes with 2 regulators 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.

It’s all about system intelligence and conserving energy. Simply put, the SAM4L microcontroller (See SAM4L Starter Kit) is your choice if you are designing a product with long battery life but without sacrificing the performance — as demonstrated in this walkthrough of the Xplained Pro SAM4L Starter Kit.

The SAM4LC Cortex-M4 processor-based Flash microcontrollers offer the industry’s lowest power consumption and fastest wake-up. On top of what’s mentioned, this sub family of Atmel | SMART microcontrollers [labeled as ATASAM4L] devices are ideal for a wide range of industrial, healthcare and consumer applications.

Get a jump-start on your design with dedicated evaluation kits and software packages.  You can also easily catch up on some of the recent and past articles we posted related to Atmel | SMART SAM4L Microcontrollers.

Understanding the global ZigBee market

A new report published by Research and Markets estimates that the global ZigBee-enabled device sector will grow at a CAGR of 67.64 percent over the period 2013-2018. According to analysts, critical factors contributing to the significant market growth include extended battery life and power saving associated with the ZigBee spec.

Indeed, the ZigBee standard defines a power-save mechanism which allows both controller nodes and target nodes to enter into a power-saving mode and intelligently manage their power consumption.

“The different benefits of ZigBee technology, such as its low cost, low power, and high reliability, is leading to its rapid adoption by consumer product manufacturers. The increasing deployment of this technology in consumer electronics and smart home devices is expected to lead the growth of the market during the forecast period,” explained one of report’s analysts.

“ZigBee set-top boxes are expected to be the major consumer product that will contribute to the market growth in the future. Compulsory digitization of TV has increased the shipment of set-top boxes across the globe. The deployment of ZigBee technology in set-top boxes is expected to increase with the growth of the Global Set-top Box market and the popularity of ZigBee technology.”

The full study can be purchased from Research and Markets here. Readers may also want to check out Atmel’s ZigBits – compact 802.15.4/ZigBee modules featuring record-breaking range performance and exceptional ease of integration. Our ZigBits pack a complete FCC/CE certified RF design that eliminates costly and time-consuming RF development accelerates time to market. A detailed breakdown of Atmel’s ZigBit modules is available here.

IoT sensor fusion with ARM and Atmel on Google+

Sensors convert physical world characteristics into raw data that is subsequently processed by various hardware and software platforms. As the name implies, sensor fusion combines sensory data from multiple sources to improve the overall state of the system being observed.

As we’ve previously discussed on Bits & Pieces, ensuring an extended battery life is perhaps the most important criterion for any device with integrated sensors.

On Tuesday, February 18, ARM will be hosting a live Google+ Hangout panel with executives from Atmel, Freescale and Sensor Platforms. 

The panelists are slated to discuss various software and hardware design techniques that can help IoT developers achieve a precise balance between low power sipping and high software complexity.

You can follow the panel discussion and access the live video feed from the following links:

• ARM Google+ page – A video link will be posted once the Hangout kicks off
• Google+ event page – If you have a Google account you can RSVP and receive a reminder before the hangout
• ARM Facebook event page
• ARM’s original blog post, in the comments section
• @ARMCommunity and @ARMEmbedded Twitter channels

Panelists include:

• 

Diya Soubra – CPU Product Marketing Manager for Cortex-M ARM Processors at ARM
• Adrian Woolley – Director of Strategy and Business Development at Atmel’s Microcontroller Business Unit
• 

Mike Stanley – Manager of Freescale’s Sensor Solutions Division
• 
Kevin A. Shaw – CTO of Sensor Platforms
• Will Tu – Director of Embedded Segment Marketing at ARM

We’ll see you on Tuesday, February 18!!!