GeniCan automatically makes shopping lists based on what’s thrown away

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Your garbage can is about to get much, much smarter.

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When it comes to the connected home, there’s smart appliances, smart lighting, smart TVs and smart hubs. Next on that list may very well be smart trash cans. If it is up to one New York-based startup, the garbage bin may become more than just a lowly container of rubbish, but an intelligent household assistant. Think about it: When you run out of something at home, whether it’s the milk, eggs or fabric softener, it’s all too easy to forget to add it to the grocery list. Thanks to the GeniCan, that will soon all change.

Unlike the Bruno smart trashcan, the Genican is a standalone device that attaches to the side of your ‘dumb’ trash pail using a magnetic panel, and scans the barcodes of items as they are thrown out. They are then added to a shopping list, which can be accessed from an accompanying mobile app, or in the near future, automatically reordered in Amazon Dash button-like fashion.

What’s nice is that the unit is designed to work with pretty much any type of bin — square or round, plastic or metal. Wall and cabinet mounting options are available, with a countertop bracket also in the works. The gadget is powered either through a typical wall outlet or an internal battery that can last for an estimated seven days depending on use.

Once installed, the GeniCan connects to an in-home Wi-Fi network, which it cross-references scanned barcodes against a UPC database and sends all data to its cloud service, which it uses to provide money-saving coupons and delivery options. From there, the cloud service relays the information to the mobile app. For those items that don’t have a barcode, the system uses voice recognition through its built-in microphone to add household essentials to a list.

Beyond helping to replenish groceries, GeniCan also features a sensor that is used to determine when a can is full. If so, the device reminds the user to take out the trash through its app.

Sound like something you’d love for your kitchen? Head over to its official Indiegogo campaign, where the GeniCan team is currently seeking $50,000. Delivery is expected to begin in September 2015.

Zebra Technologies unveils ARM mbed IoT Starter Kit

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This new IoT Starter Kit uses an Atmel | SMART Xplained board.

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In collaboration with ARM, Zebra Technologies has developed an ARM mbed Starter Kit for Zatar, an IoT platform for enterprise applications. Powered by an Atmel | SMART Xplained board, the IoT Starter Kit will enable simple, standards-based cloud connectivity for creating next-generation, Internet-aware products integrated with Zatar.

As enterprises are committing to large IoT initiatives, they often require a simple, inexpensive and standards-based artifact to begin development. To provide such a “thing,” ARM mbed IoT Starter Kit for Zatar is a ready-made reference design to rapidly spur apps like enterprise asset management, as well as build and release futuristic concepts into production.

“The IoT is here. To accelerate enterprise adoption, developers and device manufacturers require IoT kits that make it easy to prototype and develop IoT products. We are happy to work with leaders like ARM and Atmel to rapidly widen the appeal of IoT, with the kit our partners and customers can use to easily start building products and solutions on Zatar,” explains Phil Gerskovich, SVP New Growth Platforms at Zebra Technologies.

The kit will leverage the ARM mbed IoT Device Platform, including mbed OS, and provide a full stack with Wi-Fi connectivity, security and enterprise-grade cloud integration for product developers to use. What’s more, it will enable anyone creating enterprise IoT products to reduce development time and decrease expenses, with the standards-based reference design that integrates right into Zatar.

The IoT Starter Kit will use the Atmel SAM W25 Xplained PRO prototyping and evaluation platform consisting of a pre-configured Atmel | SMART ARM MCU dev board — featuring ARM Cortex processors, a fully integrated Wi-Fi network controller and an expansion port to a collection of add-on boards for functionalities such as sensors and user I/O interfaces.

“This Wi-Fi-based IoT platform kit is a great example of a system-level, edge-node solution that simplifies the complexities associated with cloud connectivity and provides IoT product developers an easy-to-use development platform that supports a wide range of IoT devices and security requirements,” says Steve Pancoast, Atmel VP Software Applications, Tools and Development. “We are pleased to team up with Zebra and ARM to enable more designers to quickly bring their IoT products to market.”

A prototype of the IoT Starter Kit will be displayed at the Zebra booth at Maker Faire Bay Area, where developers and product designers can register for early access.

Hyperalarm forces you to wake up and get moving

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This smart alarm will put an end to repeatedly hitting the snooze button. 

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Are you a heavy sleeper who can never seem to get up in the morning? Well, you’re in luck. Madrid startup Think Big Factory has developed a smart alarm that combines both sound and motion to get you out of bed. That’s because the only way to shut it off is by throwing off the covers and walking out of the room. In the past, “five more minutes” may have worked with your mom, but the aptly named Hyperalarm doesn’t take excuses.

The device features a sleek, non-intrusive design and connects with an accompanying mobile app via Bluetooth. This allows users to easily set up and manage their alarm seamlessly with both iPhone and Android smartphones. What’s more, Hyperalarm will soon also be compatible with Apple Watch, Pebble Time and other wearables. At just about four inches tall and two inches wide, it can be placed just about anywhere — desk, nightstand, dresser.

The alarm emits high-frequency sounds of varying, interwoven pitches that are nearly impossible to ignore. This prevents a person’s brain from every become accustomed to a simple tone, all while not having to deal with the unpleasant noises that come from a more conventional clock. The team adds that they will be including new sounds with every software update, not just for awakening but helping ease users into a deep sleep and creating special notifications as well.

As for what’s inside of its ABS / polyethylene casing, the gizmo packs an ATmega32U4 MCU at its core along with a Bluetooth Low Energy module, an LED display, 3D accelerometer sensors, a high-quality speaker, and a LiPo battery. Beyond that, Hyperalarm boasts a fail-proof battery system that won’t let a user activate the alarm if the remaining battery is running low. Instead, he or she will be notified via a pop-up alert.

For those days when leaving a room to turn off an alarm might be inconvenient or not practical, the gadget’s Hyper mode can be turned off, transforming it into a simple smart alarm clock. Are you someone who is prone to hitting the snooze button a few more times than they should? Head over to its official Indiegogo campaign, where Think Big Factory is currently seeking €210,000. Shipment is expected to begin in December 2015 — just in time for the holidays!

Gate is a smart mailbox for the Internet of Things

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Gate is a perfect solution for those weary of postal theft and with mobility issues who’d like to minimize trips to the mailbox.

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In today’s age of constant connectivity, a physical mailbox may seem like nothing but a relic of the past. However, postal theft remains a big problem that wreaks havoc on countless people every day. In an effort to diminish these occurrences, Gate is a digital system that easily fits within any standard U.S. mailbox and notifies a user when someone is going through their letters.

Aside from being geared towards the prevention of crime, Maker Jim Kolchin and his colleagues at ZiK, Co have designed their “first true smart mailbox” for the elderly or mobility impaired to minimize unnecessary trips to the curb, as well as for those who just want to know when their snail mail arrives.

Essentially a modern-day take on the old-school switch-and-doorbell mailbox, Gate is comprised of two main components: an Atmel based home unit that acts as a secure control center and communicates with a user’s smartphone via Wi-Fi, and a motion sensor-laden unit that mounts to the mailbox and detects when its flap is opened. This pair of devices can be connected within an area of 500 feet by means of a 915MHz transceiver, along with an optional solar panel for improved battery life and an antenna for range extension. The home unit can be configured to use Z-Wave home automation networks, too.

Gate works exactly as how you would expect: When the box is opened at a suspicious time, the home unit sends an alert by way of text, email or even a tweet. It can also relay notifications to an Apple Watch or Nest thermostat. What’s more, the home unit syncs to a variety of home automation and security systems, including ADT Pulse, AT&T, Digital Life and Nexia Home Intelligence, making it a suitable product for the ever-evolving Internet of Things.

Additionally, Gate can create a distributed network with other Gate mailboxes in the area — with the permission of its users, of course. Using Wi-Fi and a 128-bit encrypted secure IoT server connection to share data, owners will be provided with a better ETA for their postal worker. Worried about false alarms? No need to fret, as this solution comes with a time-delayed override button to keep those from happening.

“As more people participate in the network, it gets stronger and more effective. It can even analyze mailbox data from around the neighborhood and share alerts about potential mail theft. It all happens automatically, so that you can get your mail without having to worry,” Kolchin explains.

For its crowdfunding debut, the team has unveiled Gate in three color variations: bone white with blue LEDs, obsidian black with red LEDs and a traditional aluminum band with blue LEDs. Sound like something you’d like to attach to your mailbox? Head over to its Kickstarter page, where the team is currently seeking $10,000. Delivery is slated for December 2015.

Zymbit unveils its pre-configured hardware and software IoT platform

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Zymbit launches the first pre-configured hardware software platform for building, connecting and publishing IoT projects.

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To kick off Maker Week, Zymbit has unveiled the first three products within its integrated Internet of Things (IoT) suite: the Zymbit Orange edge device, the Zymbit Iris interactive display and Zymbit Connect software. As previously discussed on Bits & Pieces, the platform is the first pre-configured hardware and software solution that is a finished, secure, out-of-the-box-ready product allowing seriously creative Makers and developers to get their connected prototypes off their desk and into the market in just days, not months.

“Like the motherboard was to personal computing, Zymbit Orange is to the IoT market,” said Phil Strong, CEO of Zymbit.  “We’re giving Makers the first pre-packaged hardware and software platform built upon open components, so they can skip the painful prototype stage and start acquiring real world data and publishing it securely in a day. Zymbit takes care of the tough technology problems freeing seriously creative people to focus on bringing their IoT ideas to market quickly.”

The newly-revealed platform is comprised of three components:

• Connectivity software simplifies the connection and sharing of secured data and the management of remote devices. Its service enables users to SSH to their gadgets, whether they are on a desk or across the country. Publishing through Zymbit’s Pub/Sub Engine lets Makers collect and share data one-to-one or one-to-many, with or without subscriber authentication.

• Orange hardware makes it super easy to customize and interact at the edge of the network for data acquisition and new user interfaces by integrating all essential functions onto a single, Atmel packed motherboard. This includes an Atmel | SMART SAM L21 CPU for device authentication, power and communications, a SAM D21 MCU for I/O applications, an ATECC508 crypto engine for enhanced security and an ATWINC1500 Wi-Fi controller. Ideal for those creating next-gen projects, the modular board is compatible with Atmel Xplained Pro wingboards, Arduino shields, Raspberry Pi B+, as well as ZigBee, cellular and POE options.

• Iris offers a new way to interact with the Internet and physical world through color, touch and scale. This unit features one 128×64 OLED display, four 96×48 OLED soft keys and a 9×9 LED matrix with a fully-equipped RGB perimeter to indicate high-level conditions.

What’s nice is that Zymbit eases the complexity of getting an idea to market by leveraging open technology (such as the incredibly popular Arduino, Raspberry Pi and Linux), open developer communities (GitHub), and open application communities to encourage the quick expansion of smart ideas and products.

At the moment, the Santa Barbara-based startup is devising an open architecture product with enough flexibility to be suitable for most applications, from a single installation to a global deployment. Meanwhile, with the emergence of more connected gizmos and gadgets, security remains a less visible but very real barrier to mass IoT adoption. In an effort to combat these worries, Zymbit addresses privacy with a multi-level security architecture that includes silicon, hardware and software.

In line with their announcement, the company has also launched a contest to find the top five most inspiring and impactful IoT projects. Makers are encouraged to post their concepts to the Zymbit website, while the selected winners will each receive the first five Zymbit Orange devices to scale their projects.

Interested? Head over to Zymbit’s official site to learn more, and don’t forget to come swing by our Maker Faire Bay Area booth for a hands-on demo of the platform.

Building a realtime temperature sensor with Atmel and PubNub

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PubNub’s Bhavana Srinivas demonstrates how to build a realtime temperature sensor with PubNub and Atmel.

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With the buzzword being Internet of Things (IoT), PubNub recently wanted to build something simple, yet powerful, that could extend beyond the hackerspace and be applied to the real world. It had to combine software and hardware, and allow people at home to build it and try it themselves.

Arduino came to mind, but seeing as though the team has already written a great deal of realtime tutorials using the Arduino board, they sought out to try something a bit different. Instead, the group decided upon employing Atmel | SMART SAM D21 Xplained Pro and PubNub to devise a realtime temperature sensor.

Project Overview

The Atmel temperature sensor monitors temperatures and streams the data to a live-updating dashboard, in realtime, anywhere in the world. The temperature sensor measures the ambient temperature and publishes it as a data stream to a channel via the PubNub Data Stream Network. A web browser that subscribes to this channel displays the data stream on a live visualization dashboard.

The Concept

• The Atmel I/O1 Xplained Pro sensor measures the ambient temperature.
• This connects to the Wi-Fi using the ATWINC1500 module.
• The PubNub code running on the Atmel chip enabled the team to publish the temperature in realtime to anyone subscribing to the same channel as a data stream.
• Through the PubNub Developer Console, you can receive this stream of information from as many sensors as you like in realtime.

What Will You Need?

Hardware

• ATSAMD21-XPRO host MCU board
• OLED 1 Xplained Pro to provide the display on the chip
• I/O1 Xplained Pro for sensor and SD-card input to host MCU
• ATWINC1500 module. This is a Wi-Fi black box that contains the Wi-Fi stack, the TCP stack and the TLS stack.

Software

• Windows PC
• To get your unique pub/sub keys, you’ll first need to sign up for a PubNub account. Once you sign up, you can get your unique PubNub keys in the PubNub Developer Dashboard. PubNub’s free Sandbox tier should give you all the bandwidth you need to build and test your messaging app with the web messaging API.
• Install Atmel Studio 6.2
• Install updates to Atmel Studio as suggested during installation
• Install terminal software like putty or teraterm

A prerequisite is that you upgrade the firmware for SAMD21 using the .bat file provided with the PubNub Atmel example before you run this demo. Make sure no other software like putty or teraterm is using the com port). Close Atmel Studio and the putty terminal. The firmware upgrade is successful if you see a PASS sign on the terminal after running the code.

Connecting the Hardware, the Right Way

• Connect WINC1500 XPRO board to SAMD21 XPRO connector EXT1
• Connect I/O1 XPRO board to SAMD21 XPRO connector EXT2
• Connect OLED1 XPRO board to SAMD21 XPRO connector EXT3
• Connect SAMD21 XPRO to a free USB port on your PC (make sure no other USB port on your PC is in use)
• Connect the power to the port that says “DEBUG USB”

The Software

Open the PubNub example: pubnubAtmel/PubNub_EXAMPLE.atsln (included in the code download) in Atmel Studio and you will see the following page. Make sure you choose the debugger/programmer and interface as shown below.

Include the following lines in pubnubAtmel/src/main.h:

123	#define TEST_MODE_SSID “Enter-your-SSID” (choose THE Wi-Fi access point you want the chip to connect to) #define TEST_MODE_PASSWORD “Enter-the password-for-the-SSID” (enter the password for the same Wi-Fi connection) #define TEST_MODE_WITHOUT_PROVISION

In pubnubAtmel/src/main.c, add the channel name and pub, sub keys.

Build (F7 / Build -> build solution), run(continue/ green arrow/ F5/ debug -> continue).

Open PubNub Developer Console, use the same channel name and pub,sub keys as in the code and SUBSCRIBE.If all is well, you should see a constant stream of messages in the following format: {“columns”:[[“temperature”,”55.00″]]}

From there, the PubNub crew was able to collect and stream temperature data in realtime. But what’s next, you ask? Well, they needed to do something with that data, right? Visualize it!

Visualizing the Data Stream

Bhavana and the PubNub bunch didn’t just want to display raw data off the sensor as a live-updating number; instead, their partner-in-crime Tomomi built the beautiful temperature visualization, which mocks nursery or greenhouse monitor (a typical realworld use case for realtime temperature sensors).

The interface runs in the browser, and the technology behind is quite simple, using PubNub JavaScript APIs to subscribe the data sent from the Atmel chip. It’s simple, lightweight, built entirely in JavaScript, and accessible from anywhere in the world with any kind of device – mobile phones, tablets, and any smart device, as long as you have a web browser. The main purpose behind this is to present information in most efficient manner without losing its accuracy.

In this scenario, the UI shows the current temperature, also a simple line graph, updating in realtime so that you can tell the relative changes of the temperature, raising and dropping. This particular data is simple, but when you have multiple, more complicated data, data visualization plays more crucial role.

Go Conquer IoT

This demo is read-only and reads the ambient temperature, but in reality, you want to develop products that lets your users monitor and control, i.e, bidirectional communication between devices. For instance, if you have a smart A/C, not only monitoring the current room temperature, but you need to make it controllable from a remote devices.

“With the power of PubNub APIs, you can achieve this with no hassle. I hope I am leaving you guys with enough excitement to try this demo out, and also build cooler ones,” Bhavana concludes.

In the meantime, be sure to follow our friends at PubNub and Bhavana Srinivas on Twitter!

GoFar will help you save money on gas

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This smart device will help you improve your car’s efficiency and improve road safety. 

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While electric and even solar cars are gradually making their way to the market, for the vast majority of drivers, they are simply too expensive to justify — even despite the money that they may end up saving on gas. Fortunately, one Australian startup has devised a new solution that aims to reduce fuel costs, diminish carbon emissions and ultimately enhance driver safety, all without having to trade in that older ride.

Recently launched on Kickstarter, GoFar is a smart device that is installed on a dashboard and provides users with intuitive, real-time feedback so that they can find the most sustainable way to drive their vehicle. This is accomplished by identifying a car’s sweet spot — in other words, the optimum throttle position that maximizes power yet minimizes gas guzzling.

Aside from the aforementioned gadget (called Ray), the system is comprised of a dongle and an accompanying mobile. The dongle is plugged into an OBDII port, powered through the car’s battery and provides output on engine diagnostics. Meanwhile, Ray is situated on the dashboard and paired with a smartphone over Bluetooth Low Energy to receive the data, which is also logged in the cloud.

Embedded sensors precisely track and calculate an engine’s sweet spot and offer real-time metrics through subtle lights. For instance, blue means you’re saving while red means you’re not only burning fuel but money as well. This feature was inspired by Formula One racing, where drivers rely on a dashboard LED light display to determine the right shift points for the car so that they can achieve optimal speed.

Aside from improving vehicle efficiency, this latest smart solution brings that older car into the Internet of Things era with actionable analytics. So much so that GoFar technology can inform drivers of how much their aggressive acceleration, harsh braking and touch-and-go maneuvers actually cost them. Wondering which way to work is the fastest? The team will make it super easy to conduct experiments to test various routes or decipher which fuel type gets more miles for less.

So how much savings are we talking? According to its creators, it can be well over $500 per year for everyday commuters. Want one for yourself? Race over to its official Kickstarter campaign, where GoFar is currently seeking $50,000. Shipment is slated to begin this fall.

Zymbit wants to accelerate IoT development

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Get your real-world Internet of Things ideas to market in days, not months. 

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As the next frontier of the Internet approaches, the IoT represents a compelling opportunity across a staggering array of applications. That’s why the team behind Zymbit has developed an end-to-end platform of hardware and software devices that will enable Makers, engineers and developers alike to transform their ideas into real-world products in blistering speed.

In an effort to deliver secure, open and interactive gadgets for our constantly-connected era, Zymbit is hoping that latest set of solutions will help accelerate adoption and interface with our physical world in a more secure, authenticated manner. The company — who we had the chance to meet at CES 2015 and will be on display in our Maker Faire booth — recently unveiled its Zymbit 1 (Z1), which is being billed as the first fully-integrated piece of IoT hardware that provide users with local and remote live data interaction, along with a low-power MCU, battery-backed operation.

“Z1’s 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,” explained Zymbit CTO Alex Kaay.

Based on the Atmel | SMART SAM D21, the Z1 motherboard is electronically robust with enhanced security provided via an ATECC108 crypto engine and an ATWINC1500 Wi-Fi controller — meaning, no additional parts are necessary. Ideal for those developing next-gen IoT projects, the modular board is super customizable and compatible with Atmel Xplained Pro wingboards, Arduino shields, Raspberry Pi B+, as well as ZigBee, cellular and POE options. The Zymbit team has even implemented discretely controlled blocks to simplify coding and to secure remote device management, while advanced power management supports battery, solar and POE operations.

The Z1 integrates all of the key components required to support a generation of global IoT applications. This includes easily transitioning between Arduino, Atmel and Raspberry Pi designs, integrated open software tools for seamless innovation, as well as a choice of wireless communication. For instance, Makers can design and implement their programs using the Zymbit’s Arduino Zero app processor and take advantage of a vast number of Arduino shields. Or, developers can connect their Raspberry Pi to utilize the various Zymbit services via SPI bus, allowing their B+ module to interact with a wide-range of “things.”

The unique Zymbit architecture delivers three key pillars of security: authenticated data source with 72-bit ID serial number, protected data transmission with SHA 256 and private data transmission via a Wi-Fi embedded AES engine. This is accomplished through a dedicated hardware crypto engine that ensures only trusted data is exchanged between devices.

At the heart of Z1’s operation lies a network/Linux CPU, the Atmel | SMART SAMA5D4 MPU, tasked with its secure communication. Meanwhile, its security processes run within a supervisory, ultra low-power Atmel | SMART SAM L21 MCU, separately from its SAM D21 Cortex-M0+ I/O application MCU. This hardware is all housed inside a dynamically-constructed case, which features standard expansions and mounts perfect for any consumer, commercial or industrial applicable IoT product.

Adding to its already impressive list of capabilities, Zymbit comes with a remote manager that makes it easy to connect and manage gizmos both securely and with transparency. This service enables users to SSH to their devices, whether they are on your desk or across the country. Publishing through Zymbit’s Pub/Sub Engine lets developers collect and share data one-to-one or one-to-many, with or without subscriber authentication. As you can imagine, this opens up an assortment of project possibilities, which range from changing Philips Hue color lighting with data streams to monitoring key parameters of a refrigeration system.

“We are providing some standard dashboard widgets that allow you to quickly view your device performance metrics and data-channels. Initially we are supporting time series charting, together with plugin metrics for Raspberry Pi, and Arduino Yún,” the team writes.

Interested in learning more? You can stay up-to-date with the Zymbit team’s progress here, watch our latest interview with one of the company’s co-founders below, and swing by our booth at Maker Faire Bay Area!

10 (+1) invaluable steps to launching your next IoT product

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Let’s transition your products from a ‘dumb’ to ‘smart’ thing.

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Many enterprises, startups and organizations have already been exposed to the innovation land grab stemming from the rapidly evolving Internet of Things (IoT). What’s available in the product/market fit arena? This is the hunt to cease some segment of the multi-trillion dollar growth reported to gain from the IoT, enabling embedded system connectivity coupled with the ecosystem value-add of a product or service. Even for that matter, transforming a mere idea that centers around connectivity solutions can present an array of challenges, particularly when one seeks to bring to market disruptive ways for the end-user to adopt from the more traditional way of doing things (e.g. GoPro, PebbleWatch, FitBit, and even to as far as e-health monitors, tire subscriptions, self-driving vehicles, smart bracelets, connected medical apparatus or Industrial Internet devices, home automation systems and more).

All together, there’s one overlaying theme to these Internet-enabled products. They are all pervasively SMART technologies that help monetize the IoT. Now, let’s get your products to transition from a once ordinary, mundane object to a much smarter, more secure “thing.” When doing so, this too can often present a few obstacles for designers, especially as it requires a unique set of skills needed to interface systems with connectivity to the cloud or Internet.

To top it all off, there may already be various product lines in existence that have a mandate to leverage a connected ecosystem/design. In fact, even new ones require connectivity to the cloud, having designs set forth to enhance via customer usage then combining this user data with other associated data points. Already, the development to enable such devices require an assortment of skills. It’s an undertaking, one in which requires knowledge and expertise to command stable connectivity in the infrastructure and design a product with security, scalability, and low power.

Moving ahead, here are some recommendations developers and Makers should know:

1. Identify a need and market: The value of the smart device lies in in the service that it brings to the customer. Identify the need to develop a strong offer that brings value or enhances efficiency rather than creating a simple gadget. (See Marc Andreesen’s infamous blog on product/market fit for more tips).

2. Validate your ideation: Carry out market research. Do your due diligence. Determine whether the device you think of creating already exists. Can improvements be ascertained with testimonial as an enhanced or unique experience? Indeed, benchmarking will allow you to discover any competitors, find sources of inspiration, develop a network of ideas to pool and find other areas for improvement as well.

3. Prototype toward MVP: New device fabrication techniques, such as 3D printing, are the ideal creative validation for producing prototypes much faster and for less money. They also promote iteration, which is an integral process when designing the device towards MVP.

4. Connect the ‘thing’ then concert it into a smart ‘thing:’ Right now, there is no mandatory standard for interconnecting different devices. Selecting the right technology is essential, particularly if the device requires low-power (speaking of low-power….) and event and state controls, which highly optimize extended power and the services to enrich the information system and eventally enhance user experience with a roadmap toward an ecosystem.

5. Develop the application: Today, the primary smart devices are linked to an dedicated mobile app. Since the app transforms the smartphone into a remote control, it must be be easy to use for your end-users, and more importantly, simply upgraded via the cloud.

6. Manage the data: Fitted with a multitude of sensors, connected gadgets generate an enormous amount of data that need to be processed and stored with the utmost security across all layers even to as far as using cryptography in memory. (After all, you don’t want your design become a ‘Tales from the Crypt-O” horror story.) 

7. Analyze and exploit the data: By processing and analyzing the data, a company can extract the necessary information to deploy the right service in the right place at the right time.

8. Measure the impact of the smart device: Set up probes to monitor your devices and data traffic quality. Answer questions objectively as to how it would securely scale and evolve should there be an instant high volume success and usage. This will help you measure the impact of the smart device in real time and adapt its actions accordingly, and model into the product roadmap and MVP spec.

9. Iterate to fine-tune the device’s use: After launching the project, the process has only begun. Feedback needs to be taken into account in order to adjust and fine-tune the project. Due to its very nature, digital technology requires continuous adaptation and iteration. “Try and learn” and present riskier ideas to products are the fundamental principles behind transformation when imposing a new use.

10. Prototype again: Continuous adaptation and iteration means that your company needs to produce a new prototype.

Here’s 10 + 1 invaluable steps to launching your IoT project or product.

11. Take advantage of the hands-on training in your region.

As an application space, IoT sensor nodes are enabled by a number of fundamental technologies, namely a low-power MCU, some form of wireless communication and strong security. With this in mind, the newly revealed Atmel IoT Secure Hello World series will offer attendees hands-on training, introducing them to some of the core technologies making the Internet of Things possible, including Wi-Fi and CryptoAuthentication.

What’s more, these sessions will showcase Atmel’s diverse Wi-Fi capabilities and CryptoAuthentication hardware key storage in the context of the simplest possible use cases. This includes learning how to send temperature information to any mobile device via a wireless network and how to enable the remote control of LEDs on a SAM D21 Xplained Pro board over a Wi-Fi network using a WINC1500. In addition, attendees will explore authentication of IoT nodes, as well as how to implement a secure communications link — something that will surely come in handy when preparing to launch your next smart product.

As you can see, so far, everyone is LOVING the Hello World sessions — from hardcore embedded engineers to hobbyists. Here some recent social activity following the recent Tech on Tour events in both Manchester and Heathrow, UK. Need we say more? These tweets say a thousand words!

Connected and ready to go… all before lunch! (Yes, there’s food as well!)

 

Atmel’s Tech on Tour and proud partner EBV Elektronik proudly thankful for the successful event in Manchester, UK.

 

Atmel’s Tech on Tour just successfully completed a full house attendance training in Manchester, UK

 

BLE, WIFI, IoT, IOE, ToT, OMG! How does Big Bang Theory and IoT relate to Tech on Tour?

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What is real SAM V71 DSP performance in automotive audio?

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The integrated FPU DSP (into the Cortex-M7 core) is using 2X the number of clock cycles when compared with the SHARC21489.

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Thinking of selecting an ARM Cortex-M7-based Atmel SAM V70/71 for your next automotive entertainment application? Three key reasons to consider are the clock speed of the the Cortex-M7 (300 Mhz), the integration of a floating point (FPU) DSP, and last but not least, because the SAM V70/71 has obtained automotive qualification. If you delve deeper into the SAM V70/71 features list, you will see that this MCU is divided into several versions integrating Flash: 512 KB, 1024 KB or 2018 KB. And, if you compare with the competition, this MCU is the only Cortex-M7 supporting the 2 MB Flash option, being automotive qualified and delivering 1500 CoreMark — thanks to the 300 MHz clock speed when the closest competitor only reach 240 MHz and deliver 1200 CoreMark.

In fact, what makes the SAMV70/71 so unique is its FPU DSP performance. Let’s make it clear for the beginning, if you search for pure DSP performance, it will be easy to find standard DSP chip offering much higher performance. Take the Analog Device AD21489 or Blackfin70x series, for example. However, the automotive market is not only very demanding, it’s also a very cost sensitive market as well.

Think about this simple calculation: If you select AD21489 DSP, you will have to add external flash and a MCU, which would lead the total BOM to be four to five times the price associated with the SAM V71. (Let’s also keep this AD21489 as a reference in terms of performance, and examine DSP benchmark results, coming from third party DSP experts DSP Concept.)

Before analyzing the results, we need to describe the context:

• FIR is made on 256 samples block size
• Results are expressed in term of clock cycles (smaller is better)
• All DSP are floating-point except Blackfin
• Clock cycles count is measured using Audio Weaver

To elaborate upon that even further, this FIR is used to build equalization filter — the higher Taps count, the better. If we look at the “50 Taps” benchmark results, the SAM V71 (Cortex-M7 based) exhibits 22,734 clock cycles (about three times more than the SHARC21489). Unsurprisingly, the Cortex-M4 requires 50% more, but you have to integrate a Cortex-A15 to get better results, as both the Cortex-A8 and Cortex-A9 need 30% and 40% more cycles, respectively! And when looking at standard Analog Devices Blackfin DSP, only the 70x series is better by 35%… the 53x being 30% worst.

Now, if you want to build a graphic equalizer, you will have to run Biquad. For instance, when building eight channels and six stages graphic equalizer, your DSP will have to run 48 Biquad.

Again, the context:

• Biquad is made on 256 samples block size
• Results are expressed in term of clock cycles (smaller is better)
• All DSP are floating-point except Blackfin
• Clock cycles count is measured using Audio Weaver

In fact, the results are quite similar to those of the FIR benchmark: only the Cortex-A15 and the SHARC21489 exhibits better performance. The integrated FPU DSP (into the Cortex-M7 core) is using twice the amount of clock cycles when put side-by-side with the SHARC21489. If you compare the performance per price, the Cortex-M7 integrated in the SAMV71 is 50% cheaper! Using a SHARC DSP certainly makes sense if you want to build high performance home cinema system, but if you target automotive, it’s much more effective to select a FPU DSP integrated together with Flash (512KB to 2MB) and a full featured MCU.

The Atmel SAM V71 is specifically dedicated to support automotive infotainment application, offering Dual CAN and Ethernet MAC support. Other notable specs include:

• 10/100 Mbps, IEEE1588 support
• 12 KB SRAM plus DMA
• AVB support with Qav & Qas HW support for audio traffic support
• 802.3az Energy efficiency support
• Dual CAN-FD
• Up to 64 SRAM-based mailboxes
• Wake up from sleep or wake up modes on RX/TX

Don’t forget that when looking to construct an automotive high-end radio, you still need room for Ethernet MAC and AVB support… What’s more, the SAM V71 only consume 68% of the DSP resource, leaving well enough space for both AVB and Ethernet MAC.

Interested? Explore the Atmel | SMART SAM V ARM Cortex-M7 family here. More information about the the DSP benchmark can be also found on DSP Concept’s website.  Also, be sure the detailed DSP Concept’s audio processing benchmarks.

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This post has been republished with permission from SemiWiki.com, where Eric Esteve is a principle blogger as well as one of the four founding members of SemiWiki.com. This blog first appeared on SemiWiki on May 6, 2015.