The IoT, in which every device can communicate with every other device – even a smart bedcover can ‘talk’ with devices such as Philips’ Hue LED lighting system – is fast becoming a fact of life, like it or not. But how are the IoT technologies evolving, what are the benefits and how about the risks? And how about a wider context? James Hunt explains:

Internet and device growth…and the IoT could represent 200 billion devices by 2020. Some say even this is conservative! 

Mario Morales, IDC

The IoT is as of countless ‘things’ that are fitted with uniquely identifiable embedded devices that are wirelessly connected to the Net.  These ‘nodes’, as the ‘things’ are called, can send or receive information without human intervention. The nodes can even be fitted to animals (to track or find them), and indeed to people and their clothes – for a variety of reasons we may or may not like.

To achieve this, every ‘thing’ – which could be an LED light source or luminaire, or thermostat, or an industrial controller, for example – must be uniquely identifiable through its embedded computing system, yet it must also be able to interoperate within the existing Internet infrastructure. Such devices are proliferating fast.

With its myriad such devices, including sensors and actuators that ‘talk’ to each other wirelessly and on the Internet, the IoT brings with it an astonishing ability to measure, monitor, and analyse data. This includes, for example, consumer behaviours and buying habits – and not just consumers either, as all businesses can benefit.

Such monitoring and analyses can be used to determine future product developments that will revolutionise the ways in which we live and do business. For the vast majority of homes – made ‘smart’ by IoT devices – everyday life will be enhanced by technology, particularly in terms of entertainment and comfort.

To take just one example – Google and Philips Lighting have got together for Nest Lab’s intelligent wireless thermostat and home automation devices to work with Philips’ Hue IP-connected LED lamps – OSRAM is in on the act too.

Connectivity is the word

When the IoT is augmented with devices such as sensors and actuators, it can then encompass increasingly important technologies such as smart homes, buildings, grids and cities, as well as intelligent transportation. These devices collect useful data with the help of various existing technologies and then autonomously flow the data between other devices – such as those that use Wi-Fi for remote monitoring. But how, in brief, does such connectivity work?

Firstly, there are several types of connectivity used by the IoT. These are:

* Personal Area Networks (PAN)
* Local Area Networks (LAN)
* Neighbourhood Area Networks (NAN)
* Wide Area Networks (WAN).

PANs and LANs are those that most domestic and small business IoT installations are likely to use directly and these are also the ones that the majority of electrical contractors and installers will be involved with.

Those IoT devices that use a PAN with a smartphone will use the smartphone as the gateway to the Internet (WAN). Devices in a smart home or automated building can connect to a LAN and find their way to the Internet too.

So IoT devices use, as the name implies, Internet connectivity, but smart devices that are part of an overall IoT can also use other enabling technologies, such as RFID and near-field communication (NFC), optical tags and quick response codes (a now common example is the QR Code) and a whole range of wireless (Wi-Fi) topologies. The latter include Bluetooth Low Energy, low energy wireless IP networks, ZigBee, Z-Wave, LTE-Advanced (high-speed communication specification for mobile networks) and Wi-Fi Direct (Wi-Fi for peer-to-peer communication without needing to have an access point (AP).

It remains to be seen if any one of these becomes pre-eminent.

Important IoT issues

Away from IoT issues that will affect electrical wholesalers, contractors and installers directly – as opposed to regulators, data centre developers and owners, specifiers and IoT / network device manufacturers – there are a number of problems that will need to be addressed to ensure successful wide-scale take-up.

For example, thousands of IoT devices signaling and sending data to each another take both CPU consumption and a surprising amount of energy. This costs money and has carbon emission implications, so IoT devices should use the minimum energy possible. Though this will not normally affect electrical distributors, contractors and installers, ultra-low-power wireless chipsets should be used in IoT devices and low power networks – such as Bluetooth low-energy, ANT, ANT+, ZigBee, ZigBee RF4CE, Wi-Fi, Nike+, IrDA and the near-field communications (NFC) standard.

Bandwidth take-up is another IoT connectivity issue. Bandwidth on a cellular (mobile) network is expensive, especially with hundreds of thousands of IoT devices sending request/response signals to a server – the result is that the server farm will need to be large enough to handle all the data. With the potential for many billions of devices (possibly even trillions longer term), this will be a huge problem that must be addressed.

Another issue is presence detection of IoT devices. This provides the exact state of all IoT devices on a network and shows immediately when any device drops off the network – or when it comes back on. In this way, the IoT devices can be monitored (and fixed if a problem occurs).

And for those IoT devices that ‘live on their own’ – such as trackers – the connectivity to the wider Internet can be tricky.

Finally, it is important to note that the Internet is not simply one network, and heterogenous networks, proxy servers and security firewalls can all disrupt connectivity. So a fully functioning, all-encompassing IoT is not with us yet as many issues need to be sorted. Even so, the vast majority of Voltimum users will not need to confuse themselves with this level of granularity – most already available smart devices they install for domestic use as part of the IoT will be simple to install and commission. They are already.

At light speed!

Although Wi-Fi has not been in the public domain for too many years – apart from computer routers – it is now an established means of data communication. It is fast and increasingly reliable. Importantly, it is quick and easy to install because expensive and disruptive hard wiring is not needed.

However, there’s a new kid on the block that is even faster – far faster – and it has its own set of advantage and disadvantages. Let’s look at it briefly here:

This important newcomer is Li-Fi, which has as its analogue Wi-Fi, but being based upon light (which travels at 186,000 miles/s) is very much faster – many times faster than conventional Wi-Fi – and possibly up to 10 times cheaper.

Li-Fi (or Light Fidelity) is a form of visible light communication (it can also use infrared and near ultraviolet). It is bidirectional and fully networked and has been described as a ‘new era of wireless connections’. With claimed speeds of up to 224 GBps (though mostly lower), this new technology could enable a high-definition film to be downloaded in seconds.

The change to Li-Fi, when it comes, will be driven mainly by the electrical and lighting sectors through LED lighting. Li-Fi will turn every LED lamp into wireless access points (APs), which effectively allows any user to move between sources without losing the connection. The LED lamps act as the medium to deliver networked, mobile, high-speed communication in a similar manner to Wi-Fi (but much faster). All this then becomes another enabler and part of the IoT.

Li-Fi has the advantage of being suitable for use in areas sensitive to electromagnetic waves such as aircraft cabins, hospitals and nuclear power plants, because it does not cause electromagnetic interference. However, the light waves cannot penetrate walls, so reducing Li-Fi’s scope, and there may be problems in bright sunlight. Such difficulties will have to be addressed before there is widespread use of Li-Fi, but there’s no doubt that this new technology is creating great excitement.

Already there are examples of Li-Fi in the market. For instance, Philips Lighting has developed a system for shoppers in stores. They have to download an app on their smartphones, which then work with the lighting LEDs in the store. The LED light sources can pinpoint where the shoppers are located in the store and give them corresponding coupons and information based on which aisle they are on and what they are looking at.

Li-Fi is very likely, therefore, to change data communication; importantly for the electrical and lighting sectors, it will also generate much-needed new revenue.

Ethernet and Industrial Ethernet with the IoT

The IoT doesn’t only have domestic applications; it has a vast potential in commercial, retail, hospitality and public building sectors too. Then there’s industry – in particular, manufacturing and process plant. A connectivity protocol that is very widely used in IT is Ethernet and its industrial counterpart is the much more rigorous Industrial Ethernet. These, together with Wi-Fi are effectively enabling the Manufacturing Internet of Things – otherwise known more usually as the Industrial Internet of Things (IIoT).

The (IoT) has morphed from its RFID origins to one that encompasses all networked devices, both within and without a manufacturing operation. The big drive to adopt IoT in manufacturing has coincided – says Automation World – ‘with a concurrent enabling trend toward use of Industrial Ethernet and wireless (Wi-Fi) network technologies within the production environment’.

In addition to intelligent sensors and machines, the IIoT also takes in ‘Big Data’, cloud computing, analytics, mobility and what is termed universal visualisation. Manufacturers are aiming to implement the IoT or IIoT to optimise assets, increase production efficiencies and, therefore, improve business performance. This is achieved by gathering data from the many sensors, actuators, other devices, machines and controllers operating on the shop floor. This data is then made globally available via a cloud or similar infrastructure platform to those operators who have the authorisation (and for security’s sake, only them), so that they can monitor and analyse it – and act upon it if necessary.

The application of the IoT and IIoT to industry is really beyond the scope of this article, and relatively few Voltimum users are likely to be involved in the sector, but it is important to note, even so, how the IoT is having a crucial impact here already.

Security and safety will be crucially important

There’s that proverbial fly in the ointment, of course, and this is security, which will be of paramount importance if the future all-encompassing IoT is to work as intended, safely and securely. This is because just about everything (and everybody) will be connected together. The possibilities for hacking, denial of service, fraud and utility- and city-scale disruption are huge.

Indeed, security concerns are developing faster than even the IoT itself. This is especially so when it is considered that IoT devices will be (and already are) connected to smart grids, smart cities, water and gas utilities, energy organisations, transport etc. And domestic smart meters will connect homes to power utilities. Knowing this, the potential for catastrophe is certainly clear, whether by accident, by virus intrusion or via hacking.

So among the many considerations will be to ensure that when sending or receiving data, the IoT device or server must have proper authorisation for that (and every such) action. Also, an IoT device is dangerously vulnerable when it is listening to an open port out to the Internet – ports should not be open, despite the need for bidirectionality. End-to-end encryption between devices and servers will be crucial.

But security doesn’t just mean ensuring that your IoT system is secure from hacking; it also involves privacy and whether you can be spied upon, because the IoT holds the possibility that organisations will be able to intensify personal surveillance. And if they can, you can be sure they will try.

Issues include when someone sells a house with a smart thermostat or garage door, how does the new owner ensure former users can no longer access these devices? And how do manufacturers protect against intrusions into smart TVs and theft of data collected from device cameras and microphones? Such issues have to be addressed to make the IoT safe and secure, now and in the future.

Standards

It is clear that IoT and connectivity standards are already a crucially important, though already divisive topic. After all, how will devices connect to others without interoperability standards? Yet, many devices so far conform to a wide range of often non-interoperable standards.

Cross-industry open source organisation, the AllSeen Alliance  (among others) believes that the IoT cannot meet its full potential without an open platform to ensure interoperability between devices from different manufacturers.

Then there’s research by ON World, which finds that the wireless standard ZigBee, already being used by many IoT devices, continues to increase its share of the IEEE 802.15.4 and smart home markets. By 2020, the study claims, ZigBee standards will be used in eight out of 10 of the 802.15.4 chipset shipments.

Furthermore, the Thread Group announced last year that it had completed the specification and documentation for its IP-based wireless networking protocol for low-power connected devices in the home.

These represent just a very few examples of potential interoperability clashes for connected and IoT devices. Therefore, organisations such as the Institute of Electrical and Electronics Engineers (IEEE), the Industrial Internet Consortium (IIC), and the European IoT-A (Internet of Things – Architecture) project, among others, are looking to provide architectural frameworks that define relationships between IoT domains and devices, as well as appropriate security schemes.

As these few examples show, it’s clear that there is much work to do as far as standards and interoperability are concerned.

And finally….

For the future? Well, the World Economic Forum makes five predictions for the IoT, bearing in mind that in the past year alone, IBM has invested £2 billion in its IoT business unit, and AT&T announced a record 1.6 million connected device net additions, including one million IoT-enabled cars, in Q3. Earlier in the year, Samsung declared its commitment to connecting everything it sells by 2020, and GM stated that its OnStar 4G capabilities will generate £242 million in profit over the next three years.

The predictions are:

– That the ‘security of things’ will take centre stage.

– We will stop counting the ‘things’ in favour of more important success metrics to put a premium on the quantifiable impact of new services.

– For the first time, more new cars will be connected than not.

– Low-power wireless area network (LPWAN) technologies will not go mainstream because the technologies are still in their infancy.

– The IoT market will align around a more precise lexicon, meaning that ‘business savvy enterprises will demand accuracy and accountability, resulting in clearer definitions from IoT solution providers’.

internet connected lighting · internet of things · iot · iot led lighting · led lighting · lifi · Novel Energy Lighting · philips hue · wireless control

The first LED PL-C lamp designed to save energy and downsize costs

CorePro LED PL-C is the first PL-C lamp replacement for downlighters that provides up to 60% energy saving, three times longer lifetime (30,000 hours) and a robust, shatterproof plastic housing. A retrofit lamp that’s simple to install, fits fixtures with E.Mag or HF ballast and requires less maintenance and servicing. So you can downsize your downlighting costs with energy efficient LED.

Application areas:

Focus on general circulation areas in downlight luminaires as key applications

Saving energy without compromising on light quality:

• CorePro LED PL-C lamps save >50% energy by directing the light so that none is wasted above the luminaire.

• Therefore the CorePro LED PL-C lamp also requires less light (lumen) to reach the same lux levels.

• In addition, the rotating end-cap feature ensures lamps can always be rotated in the ideal direction.

• The rotating functionality (from -45˚ to +90˚) offers the possibility to optimise light distribution and fit of the lamps, whatever type of luminaire they are being installed in.

Range build-up

Compatible with all Electro Magnetic ballasts

• Recognisable by 2 connector pins on socket base

• Available in two socket types:
– G24d-2 to replace 18W / G24d-3
– to replace 26W conventional PL-C lamps.

Compatible with Electronic / HighFrequency ballast

• Recognisable by 4 connector pins on socket base

• Available in two socket types:

– G24q-2 to replace 18W

– G24q-3 to replace 26W conventional PL-C lamps.

 Key benefits

Energy efficient

• More than 60% more efficient compared to fluorescent PL-C lamps, saving on energy costs

Long lasting & robust

• With lifetimes up to 30,000 hours (vs. 10,000 hours Fluorescent PL-C), reducing maintenance costs

• PL-C LED Lamps are made of shatter-proof plastic instead of glass

Simple lamp for lamp replacement

• Easy upgrade from current conventional downlight fixture to LED PL-C (hassle free)

• Re-using the existing fixture without major modifications, using a similar PL-C form-factor

High quality of light

• No flickering or stroboscopic light

• Instant 100% light

Product specifications

Philips CorePro LED PL-C 2-pin range:

• Two wattage positions for G24d-2 and G24d-3 socket holders

• 3000 K & 4000 K

• Efficiency up to 112 Lumens / Watt

• < 2 years pay-back, at affordable initial price point

• Rotating end-caps, to rotate light in the ideal direction

• Perfect fit dimensions, to enable optimal fit with existing luminaires

Philips CorePro LED PL-C 4-pin range:

• Two wattage positions for G24q-2 and G24q-3 socket holders

• 3000 K & 4000 K

• Efficiency up to 100 Lumens / Watt

• < 2 years pay-back, at affordable initial price point

• Rotating end-caps, to rotate light in the ideal direction

• Perfect fit dimensions, to enable optimal fit with existing luminaires

Visit www.novelenergylighting.com to browse the selection of Philips Corepro PL-C lamps today, or call us for volume pricing, tel: 0208-540-8287

led g24d · led g24q · led lighting · led plc · Novel Energy Lighting · philips corepro led · philips corepro plc · philips led

Megaman UK has launched an invaluable, simple to use online service to assist home owners, contractors, specifiers or anyone involved in lighting to calculate the potential savings that can be achieved when switching from standard light sources to Megaman’s energy saving LEDs. 

The new online tool, which is focused on the end user, uses quick and simple calculations to provide annual cost savings, payback and energy usage in kW and CO2. Different lamp types can also be compared at any given time to clearly show the savings involved in changing one room, two rooms or even a whole house to LED lamps using a mixture of Megaman’s LED lamps such as GU10, Classic or Candle ranges. This clever tool is also capable of generating a series of results that can be downloaded immediately or saved for assessment at a later stage.

energy calculator · energy savings · led cost of ownership · low energy lighting · megaman gu10 · Megaman LED · megaman lighting · megaman MR16 · megaman spots · Novel Energy Lighting

energy efficient lighting · hotel led · hotel lighting · led financing · led lighting · LED retrofit · led upgrade · Novel Energy Lighting

led candle · LED Candle Lights Benefits

benefits led gu10 · led GU10 · led gu10 lamps

No tags

Halogen Lamp · led lighting

LED lights are the latest technology in energy efficient lighting. LED stands for ‘Light Emitting Diode’, a semiconductor device that converts electricity into light.

LED lamps are light bulbs that use light-emitting diode technology. These lamps are far superior to incandescent, fluorescent, or halogen lamps in terms of lifespan and energy efficiency, which makes them a perfect retrofit. LED lamps are at full brightness the moment you switch them on, and do not flicker. LEDs produce directional light and not distributed light, so lamps are designed with specific beam angles, from which customers can select depending on application. High temperature has an effect on LED durability, so these lamps have heat dissipation elements like heat sinks and cooling fins – the more efficient the heat dissipation, the longer the lamp life.

Benefits of LED Lighting

1. Long Life

2. Energy Efficiency

3. Ecologically Friendly

4. Durable Quality

5. Zero UV Emissions

6. Design Flexibility

7. Operational in Extremely Cold or Hot Temperatures

8. Light Dispersement

9. Instant Lighting & Frequent Switching

10. Low-Voltage

It’s time you switched to these environmentally-friendly lamps.

For more information, reach us on www.novelenergylighting.com or contact us on 0208-540-8287.

led benefits · LED lamps · led lighting · LED lights · what is led