Connecting Everything Internet of Things: Connecting Everything

Internet of Things: connecting everything Internet of Things: connecting everything

Technologies to connect your products to the internet We live in a new age. A time when everything and everyone is connected and smart devices can communicate with us and each other. This is the age of the Internet of Things. Think of a refrigerator that knows when your milk has expired and automatically orders a new bottle, or a water faucet that automatically detects leaks, shuts off the water supply and then contacts the water company. The developments are moving fast. In 2016, 6.4 billion devices all over the world were connected to the internet. That was 30% more than in 2015. According to the research agency Gartner, this number will grow to more than 20 billion by the year 2020.

At the moment, many organisations are experimenting with connecting their products, for example because they want more insight into their usage or because they are looking to realise more efficient processes, save energy or maximise usability. What is the best way to go about this? Which technology should you choose? How can you use this technology to gather exactly the information you need? In this whitepaper, we will explain the technological background of connectivity and outline the specifications, possible applications and pros and cons of WLAN, Bluetooth Low Energy, LoRa, cellular M2M and other technologies. You can use this information to make your plastic product smarter and take full advantage of the Internet of Things.

Internet of Things: connecting everything Connectivity Whitepaper 2 1 What is connectivity?

“Connectivity” means that objects are connected. Said object can be a smartphone or a satellite navigation system, but also a razor blade stand or even a cow in a field. In the context of the Internet of Things, “connectivity” means that objects connected to the internet communicate with each other.

How it works Here is how this communication works. The object Example: elevator maintenance contains sensors that measure certain values, e.g. weight, speed, temperature or quantity. A Sensors in an elevator measure how processor then processes this data and sends long it takes for the doors to close. If this it via the internet to another device, which then process is faster or slower than usual, executes or controls certain actions based on the the elevator might not be performing data it receives. optimally. The elevator sends this information to a special system that determines the right course of action The possibilities of the Internet of Things based on the data, e.g. “I will monitor the The Internet of Things offers limitless possibilities. situation. If it gets worse, I will schedule Think of, for example: maintenance for next week. For now, the elevator can continue to the third • Real-time inventory monitoring and automatic floor, because there is someone waiting reorders; up there.” This method of preventative • Real-time location tracking for vehicles or maintenance reduces the occurrence of objects; malfunctions. • Executing predefined tasks in a predetermined situation: e.g. automatically cutting off the water supply to a field after three days of rain; • Machines that learn and adapt based on usage data; • Monitoring consumers’ purchasing behaviour and gaining insight into where and how often certain consumers order products; • Insight into a product’s costs, energy consumption or lifecycle; • Updating software via the internet, so any faults can be resolved in the field.

Internet of Things: connecting everything Connectivity Whitepaper 3 Seven technologies to connect 2 your product to the internet

There are several technologies that you can use to connect your product to the internet, so it can communicate with other connected devices. In this chapter, you can read more about connecting devices via WLAN, Bluetooth Low Energy, cellular M2M and the four main types of LPWAN: LoRa, Sigfox, NB-IoT and LTE-M.

Frequency Range Pros Cons Examples*

WLAN Licence-free 2.4 GHz Max. 32 m Large quantities of Very limited range Parking metres, street and 5 GHz ISM data in a short time lights, energy meters

Bluetooth Licence-free 2.4 GHz to Max. 100 Switching Limited range, small Audio and mobile Low 2.48 GHz ISM m bandwidths to quantities of data applications, wearable Energy prevent interference devices

Cellular Licensed radio 16 km Global coverage High energy Order button on a razor M2M frequencies. Dependent from the with transmitter consumption blade stand: order new on location. The transmitter masts blades with a single Netherlands: 800 mast press of a button. MHz – 2.6 GHz. United States: 700 – 1900 MHz. Africa: 1.800 – 2.300 MHz. Asia 800 – 2600 MHz.

LoRa Licensed LoRa network. Max. 16 Coverage in the No direct connection A trap that signals when Europe: 868 MHz. US: km wilderness and between devices an animal is caught in it. 902 MHz. China: 779 underground A sensor that measures MHz the aridity of the soil, so a farmer knows when to use his sprinklers

Sigfox Licensed Sigfox Max. 40 Low energy Small quantities of data A water or gas pipe that network. km consumption can be opened or shut Europe: 868 MHz. US: remotely 902 MHz

NB-IoT Licensed radio Max. 40 Strong signal, low At the moment, A light that turns green frequencies. km energy consumption relatively expensive when a parking spot is

LPWAN Europe: 868 MHz. US: and excellent compared to other available and red when 902 MHz. China: 779 security LPWAN technologies it is occupied. An app in MHz your car tells you exactly where the available spaces are

LTE-M Licensed radio Max. 100 Larger bandwidth, At the moment, Smart meters, mobile frequencies. km 1 Mbps per second. relatively expensive payment terminals and Europe: 868 MHz. US: Twice the bandwidth compared to other fleet management that 902 MHz. China: 779 of LoRa LPWAN technologies requires more data MHz and expected to be traffic than NB-IoTw more expensive then NB-IoT in the future

* In certain cases/situations, the examples may also be applicable to other technologies.

Internet of Things: connecting everything Connectivity Whitepaper 4 1 Wireless Local Area Network 3 Cellular M2M (WLAN) Cellular M2M (machine-to-machine) uses radio WLAN, commonly called WiFi, is a wireless waves in the same way that a phone uses a network that is mainly used for internet SIM card. The range depends on the presence connections at home or in the workplace. The of transmitter masts; from a mast, the range is network runs on the globally licence-free 2.4 16 kilometres. Because of the large density of and 5 GHz frequency bands. The relatively high transmitter masts, this technology offers global bandwidth allows users to send large coverage. You need a SIM card to connect quantities of data in a short an object to cellular M2M. Once connected, time. Its range is circa 32 the object will retain its connection through metres, which means WLAN roaming. Audio, text messages and data can is not suitable for long- be transmitted continuously, which means range connectivity. the energy requirements are relatively high. This makes cellular M2M mainly suitable for wearable and easily chargeable devices. The 2 Bluetooth Low Energy costs per minute or MB can be high, because Like WLAN, Bluetooth is a short-range you use a different network. solution. Bluetooth operates on licence-free frequencies between 2.4 and 2.485 GHz and it can switch between different frequencies to limit interference from other devices. This technology is energy efficient, which also limits the available bandwidth. This means users can only transport small quantities of data. Bluetooth is perfectly suited to link small electronic devices, e.g. connecting a smartphone to a wireless speaker to play music.

Furthermore, Bluetooth can be used in combination with a mobile phone that serves as a gateway. If the right app is installed on the phone, devices can exchange data with the internet via the phone. This method – known as Bluetooth Low Energy – is characterised by its extremely low energy requirements and its relatively low implementation costs. Many common devices use this technology, from toothbrushes and washing machines to kitchen appliances and even toys.

Internet of Things: connecting everything Connectivity Whitepaper 5 5 NarrowBand – Internet of Things Low Power Wide Area Network (NB-IoT) (LPWAN) NB-IoT is comparable to LTE (commonly Information is transmitted between referred to as the 4G network). The technology battery-powered devices using the utilises the advantages of the 4G network: wireless LPWAN network. LPWAN is infrastructure, range and security. This suitable for long-range connections and technology is characterised by its excellent offers excellent coverage, even in hard- coverage and wide range, even underground. to-reach areas and underground. The NB-IoT can connect millions of devices to downside is its slow data transfer rate. each other. A downside is the low bandwidth, LPWAN utilises advanced energy-saving which means it is not possible to transmit technology. The three main types of large quantities of data in a short time. On the LPWAN are NB-IoT, LoRa and Sigfox. It is other hand, the battery will last a long time; up important to consider which network is to fifteen years with a usage of 200 bytes per available in which countries. day. The technology makes use of an existing network and licensed frequencies, such as 3G and 4G, which makes it impossible for others to interfere on the network. There is also no 10 years How long the legal limit on data usage. battery will last NB-IoT was designed to keep the costs per 10K module as low as possible. These costs are The number 10 km of devices The minimal expected to drop below $2 per module in the controlled by LPWAN range each cell future. Because of its small memory (a cheap devices of the future PSRAM variant) and its single antenna, NB- IoT is cheaper than cellular M2M. There is no need for full duplex features (transmitting 10 bytes $10 and receiving data at the same time, e.g. as The data sent The cost of the per hour device used by a phone to allow you to talk and listen simultaneously). Because this is not required for NB-IoT, the costs are lower than those of 4G.

4 LTE-M LTE-M, also known as LTE Cat M1, is a variant of the existing 4G networks and it is comparable to NB-IoT. Compared to the other LTE networks, LTE-M is available for a wider bandwidth, although it offers reduced coverage. LTE-M is designed to frequently transmit data at a lower speed than what is common for 4G networks. The advantage of LTE-M is that it can provide real-time information. This technology is currently very popular in the United States.

Internet of Things: connecting everything Connectivity Whitepaper 6 6 Long Range (LoRa) 6 Sigfox LoRa connects battery-powered devices to Sigfox can be used to exchange small each other via a regional, national or global quantities of data without frequent network at a low cost. This does require a communication. Sigfox offers a range of 40 network point, like WLAN or cellular M2M. kilometres and very low energy consumption. LoRa has a range of 16 kilometres, even in the In the stand-by mode, two AA batteries will wilderness and underground. The technology last for two years. Like LoRa, Sigfox utilises the utilises the licence-free ISM network. A licence-free ISM network. Others can also use downside of LoRa is the possible interference this network for free. This negatively affects the from other users on the network. There is also performance of this technology, e.g. by slowing a legal limit on the data usage: you may not down the data transfer rate. Data usage is transmit more than 12 bytes per hour. legally limited to 12 bytes per hour.

NB-IoT, LoRa, Sigfox or LTE-M? Out of these four WPLAN technologies, comparable to NB-IoT. It offers a larger NB-IoT is currently in the lead. NB-IoT bandwidth, so you can transmit more offers better coverage, no limitations data, at the cost of slightly limited to output, the highest download and coverage. upload rates (up to ten times higher than LoRa and Sigfox), the longest Another advantage of NB-IoT and battery life, a relatively cheap module LTE-M is that there are several LTE and exceptional security. NB-IoT also network providers, including AT&T and utilises the existing LTE network. Vodafone. Sigfox and LoRa only have Contrary to LoRa and Sigfox, NB- one provider each. Sigfox is a company IoT does not require a new network that developed its own form of LPWAN, infrastructure made up of gateways, while LoRa is supported by the members masts and repeaters. LTE-M is of the LoRa Alliance.

Internet of Things: connecting everything Connectivity Whitepaper 7 Choosing the right technology 3 for your application

All connectivity technologies have their respective pros and cons. If you want to know which technology is best suited for your application, you should first determine exactly what you want to know. If you have a courier service and want to track your drivers, a WPLAN connection is a good option. If you want to enable consumers to order new razor blades with a single press of a button once their current blade becomes dull, it is better to go for a continuous connection using cellular M2M.

What to look out for when choosing a technology?

1 Design The size of the required batteries may affect your product’s design. A device with a cellular connection and a ten-year lifecycle, for example, may need three AAA batteries. LPWAN requires a much smaller watch battery, which offers more design options.

2 Costs Hardware, e.g. a SIM card, and software cost money. From the perspective of hardware costs, there are virtually no differences between the various technologies. If you go for cellular M2M with a SIM card, you will need a data provider, which comes with its own costs. LoRa, Bluetooth, Sigfox and WLAN utilise existing networks, so you do not have to pay data costs. Of course, the requisite infrastructure for these networks has to be available. If that is not the case, creating this infrastructure will lead to more costs. A provider may also charge you for e.g. the maintenance or expansion of the network. These costs are often billed per device per year.

Internet of Things: connecting everything Connectivity Whitepaper 8 3 Security Good data security is becoming increasingly important, especially when you want to transmit large quantities of (confidential) data. A cellular M2M connection offers many advantages in this regard. A SIM card is technically a microprocessor that mostly handles encryption and decryption. This encryption makes it impossible for unauthorised third parties to access the data. The user can turn a device off remotely and access or block the SIM card. If you want to transmit highly confidential data, it is advisable to use a private Access Point Name (APN). This means data is only transferred via a private network connection. LoRa also encrypts its data traffic, while Sigfox does not. Out of the LPWAN technologies, NB-IoT is the most secure because it utilises both network- and device-side authentication. Furthermore, NB-IoT encrypts the data traffic between devices on the network.

4 Future-proof Technological developments occur at a dazzling rate. Ask yourself whether the technology and application you choose today will still meet your requirements in ten years’ time. Perhaps you will want to collect more or other relevant data by then. Will the technology of your choice let you do that?

5 Location Finally, the location is an important consideration. Not every technology is available everywhere yet.

• WLAN is available in virtually every country in the world. According to the research agency Statista, the number of public hotspots will grow from 90 million in 2016 to more than 500 million by 2021. • Devices with Bluetooth Low Energy (BLE) can be used anywhere in the world. BLE does not rely on any existing infrastructure, since the devices form their own network once they are connected. • LoRa is available in parts of North and South America, Africa, Europe, Asia and Australia, although the bandwidths differ per location. Europe uses 867-869 MHz and North America uses 902-928 MHz, while the frequency in Asia differs per country (ranging from 40 MHz to 925 MHz). • Sigfox is available in most European countries, as well as in Australia, Japan, Tunisia, Oman, Madagascar, Laos, South Africa, Iran, Brazil, Argentina, Colombia, Mexico and the United States. • NB-IoT and LTE-M utilise existing 3G and 4G networks, which offer virtually global coverage. LTE-M is very popular in the United States.

Internet of Things: connecting everything Connectivity Whitepaper 9 4 Rompa and connectivity

The developments pertaining to connectivity we produce a wide range of devices for both are a core focus for our organisation as well. consumers and industrial applications. Whereas Rompa started out as a producer of plastic products with a specialisation in Rompa produces all electronics that provide injection moulding and thermoforming, the the connectivity in house. This is possible company has expanded to become a full- because of our own SMT line (surface-mount service supplier of plastic products with technology). Our software engineers ensure electronic components that are connected to that the hardware is controlled by software. the internet. From products with On/Off and In our special ESD room, we can assemble charging features to connected devices that electronic components and plastic products can be monitored via an app; protected against static electricity.

Need help with connectivity? Rompa is a medium size flexible hands-on organisation. Our experts would love to sit down with you to discuss and resolve your connectivity issue. From the initial idea to the final delivery of your connected plastic product: we are your perfect partner in connectivity. No issue is too complex for us.

This is what we can do for you: • Partnership for the complete production process, including plastics; • Design and assembly of PCBAs (circuit boards) and plastics; • Purchase of all necessary components, for example sensors; • Assembly of electronic components and injection moulded plastic products into finished products; • Testing (semi-) finished products; • Multiple thermoforming packaging solutions; • Worldwide delivery.

When you collaborate with us, you can take advantage of our complete dedication and the full- service partnership we offer. Our goal is to take matters entirely out of our customers’ hands. We possess all relevant certifications and have multiple production sites all over the world.

Feel free to contact us If you would like to know more about the possibilities, contact our salesoffice in the Netherlands, via +31 13 594 20 20 or [email protected]

Internet of Things: connecting everything Connectivity Whitepaper 10 Your worldwide production partner With our production sites spread across three continents, we are in a great position to provide local for local production. This advantage leads to increased efficiency, more flexibility and low transport costs. As a result of our global quality standards, our customers can benefit from the same excellent service levels and quality no matter where they are.