All posts tagged: ip

Continuing from our previous articles which are focusing on a range of currently-available Internet-of-Things systems, we now move forward and explore another addition to the Internet-of-Things marketplace in more detail – the system known as “ThingSpeak”. Considered to be one of the first openly-available IoT platforms, ThingSpeak operates on their own free server platform, or you can run the software on your own personal servers – and as the entire system is open-source, it’s easier to work with and customise.

As with the other systems examined, ThingSpeak gives your devices the opportunity to interact with a server for simple tasks such as data collection and analysis, to integration with your own custom APIs for specific purposes. Due to the open-source nature the start-up cost can be almost zero, and unlike other systems ThingSpeak is hardware agnostic – giving your design team many hardware options. However as always, let’s consider the main two components in more detail.

thinghard

Hardware – You don’t need to purchase special base units or proprietary devices. As long as your hardware is connected to the Internet and can send and receive HTTP requests – you’re ready to go. For rapid prototyping, examples are given using many platforms including netduino, Arduino, mbed, and even with the competitive Twine hardware. This gives you a variety of MCU platforms from Atmel and ARM Cortex providers to work with, and as these development platforms are either open-source or inexpensive, your team can be up and running in a short period of time.

Furthermore creating your own devices can be quite inexpensive – a simple device based on an Atmel AVR and Ethernet interface can be manufactured for less than $20 in volume, and doesn’t require any software licensing expenses. To save on hardware costs, it could be preferable to have various sensors in a group communicate back to one connected device via inexpensive Nordic NRF24L01 wireless transceivers – and the connected device can thus gather the data into the require fields for transmission back to ThingSpeak.

Software – Thanks to the open-source nature of ThingSpeak either working with the existing server software or creating your own APIs isn’t a challenge. Interaction is easy with simple HTTP requests to send and receive data, which has a useful form. Each data transmission is stored in a ThingSpeak “channel”. Each of these channels allows storage and transmission of eight fields with 255 alphanumeric characters each, plus four fields for location (description, latitude, longitude and elevation – ideal for GPS), a “status update” field and time/date stamp. Data sent over the channels can be public or private – with access via your own devices and software finalising the security.

thingsoft

Once sent to the server this data can be downloaded for further analysis, or monitoring using various HTTP-enabled entities – from a simple web page, mobile application or other connected device. Various triggers can be created to generate alerts for various parameters, and can be sent using email, twitter, or other connected services such as an SMS gateway. After being in operation for almost three years, the platform has matured to a reliable service that has exposed many developers to its way of doing things, so support and documentation is becoming easier to find.

Overall the ThingSpeak system offers your organisation a low barrier to the Internet of Things. Creating a proof-of-concept device or prototype hardware interface can be done with existing or inexpensive parts, and the use of ThingSpeak’s free server can make an idea become reality in a short period of time. And once you device on the service, by internalising the server software, you can have complete control and security over your data.

If you’re interested in moving forward with your own system based on the ThingSpeak, we have a wealth of experience with the required hardware options, and the team to guide you through the entire process – from understanding your needs to creating the required hardware interfaces and supplying firmware and support for your particular needs.

Our goal is to find and implement the best system for our customers, and this is where the LX Group can partner with you for your success. We can create or tailor just about anything from a wireless temperature sensor to a complete Internet-enabled system for you – within your required time-frame and your budget. For more information or a confidential discussion about your ideas and how we can help bring them to life – click here to contact us, or telephone 1800 810 124.

LX is an award-winning electronics design company based in Sydney, Australia. LX services include full turnkey design, electronics, hardware, software and firmware design. LX specialises in embedded systems and wireless technologies design. https://lx-group.com.au

Published by LX Pty Ltd for itself and the LX Group of companies, including LX Design House, LX Solutions and LX Consulting, LX Innovations.

Muhammad AwaisLX Group examines the ThingSpeak IoT Platform

When fighting a warehouse fire in extraordinary temperatures, you don’t want to worry about the two-way radio breaking down. If a police car is broadsided during a high-speed chase, the on-board computer can’t be torn free to become a dangerous projectile. When staking out a remote location in the desert or on or drilling for oil in the North Sea, electronic equipment needs to withstand the extreme weather.

When designing projects for extreme environments such as the previous examples, you need rugged electronic designs. To make sure your clients and end users in the field have technology they can rely on, a number of organisations have developed stringent industry testing standards and procedures. This has an impact on product design as engineers are required to know, design and test their equipment to comply with set standards. The desired end here is for the products to survive “Torture Tests” and gain compliance certificates.

Ruggedisation is defined as “designed or improved to be hard-wearing or shock-resistant. There are four categories of rugged electronic equipment; commercial-grade; durable; semi-rugged and fully rugged. Today’s most widely used ruggedness standards include those from four highly respected sources: the International Electrotechnical Commission (IEC), the European Committee for Electrotechnical Standardisation (CENELEC) which publishes the European IP (Ingress Protection) standards for electrical equipment, and the United States military.

Most standards provide exceptionally detailed instructions and procedures for product testing. Major tests normally performed include:

  • Water Intrusion: When water or rain penetrates a device, they can cause short circuits and corrosion. Many manufacturers test their rugged products against both MIL-STD-810F and IP54, IP64, IP66 water and rain intrusion standards. Testing for rain intrusion is normally done in a rain chamber that drenches products with jets of water of varying intensities from all possible angles, as well as for dripping water for different periods of time. Fully rugged models are also tested with full immersion, to IP68 and MIL-STD-810F, Method 512.4.
  • Salt and Fog: In coastal and marine environments, salt and fog can cause electronic equipment to short circuit or rust, affecting performance both short and long-term. Engineers normally test to the MIL-STD-810F Method 509.3 standard using the specified five percent saline solutions.
  • Humidity: Conditions of extreme humidity can cause electronic devices to corrode and malfunction over time. Typical tests are to MIL-STD-810F Method 507.3 specifications, which specify 95 percent relative humidity and worst-case scenario high temperatures up to 75°C.
  • Dust Intrusion: Dust and sand intrusion in deserts, shorelines, mines, construction sites, or other environments can cause movable parts like buttons and keypads to clog and malfunction. Often manufacturers test to both MIL-STD-810F, Method 510.3 for sand and dust testing and IP standards for blowing dust.
  • Drop Testing: In the field, it’s common for handheld devices to be knocked over or dropped. Manufacturers test to MIL-STD-810F Method 516.5 with around 90- to 120 cm free-fall drops to concrete, and also with tip-over tests. The equipment is expected to remain fully operational after multiple drops.
  • High and Low Temperatures: Manufacturers test their technology under operating conditions of minus 35°C (MIL-STD-810F Method 502.3) and plus 60°C (MIL-STD-810F 501.3). In addition, equipment is often stored under extreme temperature conditions, and is expected to work to specification when put into service. Many manufacturers tests equipment storage in extreme low temperatures down to minus 57°C (also MIL-STD-810F Method 502.3) and high temperatures up to 85°C (also MIL-STD-810F 501.3).
  • Temperature Shock: Equipment is often transported by aeroplane, or used outdoors and brought inside, meaning it can be under extreme cold for long periods of time, then deposited or stored in extreme heat. Equipment is tested under these precipitous temperature fluctuations to MILSTD- 810F Method 503, testing equipment that has gone from storage of minus 57°C to 80°C and vice versa.
  • Sun Exposure: Equipment that is installed in, or must work in, unrelenting sunshine is tested to MIL-STD-810F Method 505.4 standards for enclosure and performance damage from solar radiation. Tests normally last from three to seven days, and are conducted in a specially designed solar chamber.
  • Shock and Crash Testing: Mobile and vehicle mounted products are tested to make sure they are installed correctly by subjecting them to worst-case scenario accident impact tests. MILSTD- 810F Method 516.4 tests are exceptionally stringent. Equipment must continue to operate correctly under 75Gs, or 75 times the force of gravity. Drop tests of varying heights to a steel floor are also conducted. Equipment must stay intact, mounted and continue to be 100 percent functional.
  • Vibration: Vibration testing to MIL-STD-810F Method 514.5 measures how equipment reacts to different levels of vibration, which can cause wire chafing, intermittent electrical contacts, display misalignment and other issues. Tests are conducted in both standard vehicles such as cars and trucks and under the more severe vibrations caused by more vibration-prone vehicles such as motorcycles, tanks and others.
  • Low Pressure: High altitudes and dropping pressure, such as in aircraft or on mountains, can cause membranes in parts such as speakers, microphones and keypads, to malfunction. Manufacturers conduct low-pressure performance tests to MIL-STD-810F Method 500.3 that ensure 100 percent equipment functionality

To ensure that products go to market quickly and don’t suffer costly delays, engineers should include relevant testing consideration as part of the design process. By confirming assumptions of the product’s compliance—such as the market and classification of the area in which the equipment will be used (Class I, Division 1, Class I, Zone 0 etc.), determining the appropriate protection concept (intrinsic safety, flame-proof, etc.), and establishing the indicative environmental considerations (enclosure ratings, extended ambient temperature range and so on) product development will be smoother and not require reworking to meet aforementioned standards.

The recommendation is for engineers proceeding into research and development stages to keep the submission for final certification in mind. This could mean reaching out to consultants who will help you through your submission process and follow their advice and guidelines.

At the LX Group we can carry out product testing, verification and compliance certification. We also partner with a number of NATA-certified local and international partners to provide independent product compliance and environmental testing.

LX has a range of equipment to support environmental and certification testing including an environmental test chamber, EMC test equipment, ESD simulator (CE testing), and various electrical input simulation devices such as environmental testing, design verification and compliance testing.

Some common compliance standards include:

  • EMC emissions and immunity testing (including C- Tick, FCC and CE)
  • Electrical safety (mains certification)
  • UL certification
  • RoHS and WEEE compliance
  • Industry-specific standards (including medical and mining)
  • Ingress Protection (IP) rating
  • Packaging and labelling requirements

For more information or a confidential discussion about your ideas and how we can help bring them to life – click here contact us, or telephone 1800 810 124.

LX is an award-winning electronics design company based in Sydney, Australia. LX services include full turnkey design, electronics, hardware, software and firmware design. LX specialises in embedded systems and wireless technologies design. www.lxgroup.com.au

Published by LX Pty Ltd for itself and the LX Group of companies, including LX Design House, LX Solutions and LX Consulting, LX Innovations.

Muhammad AwaisDesigning embedded hardware to withstand rugged environments