OSRAM EINSTONE: Beacons combined with light
Learn more about the OSRAM Beacon technology
OSRAM EINSTONE brings the offline and online worlds together using intelligent transmitter units known as beacons, thereby enabling the implementation of location-based services. The lighting installation provides a stable, secure and low-maintenance beacon infrastructure for these services. With EINSTONE Smart Infrastructure and EINSTONE Smart Retail we can supply everything you require for your individual applications – from single components right through to complete solutions.
Definition: What is Beacon technology
Beacons act very much like lighthouses – they send out signals just to show they are there. Bluetooth Low Energy beacons are transmitters that continuously emit Bluetooth signals in default frequencies to relay information on the transmitter's identifier, location or status.
Beacons allow virtual, wireless interaction with consumers who are using mobile end devices such as smartphones, tablets and smartwatches. When a person with a mobile device and a matching app approaches a transmitter, the device picks up the beacon signal. The app can then trigger individual information or offers (location-based services) depending on the person’s location.
This is how OSRAM EINSTONE beaconing works
Permanently supplied with power, the OSRAM EINSTONE beacon modules give you a stable and secure solution that is directly connected to the lighting installation. EINSTONE provides the basis for implementing a whole range of location-based applications in indoor facilities.
We support your projects with options ranging from single beacons and their integration in a variety of luminaires right through to complete solutions.
Frequently asked questions (FAQ)
The signals broadcast by the Bluetooth Low Energy beacons can be received by mobile end devices such as smartphones, tablets and smartwatches. The receiving device estimates the approximate distance to the transmitter by measuring the strength of the signal it has detected and, depending on the estimated distance, triggers an action stored in an app on the device. The shorter the transmission interval of a beacon, the lower the latency with which an action is triggered on the end device
If the beacon signal contains location information or ID data that allows the end device to determine the transmitter’s bearings, the position of the end device can be calculated by means of trilateration or fingerprinting.
Depending on transmitter power and receiver sensitivity, beacon signals have a range of up to 100 meters.
The benefits lie in being able to address the customer personally and directly in the local brick-and-mortar store. In addition, combined with retail analytics, the technology offers retailers the possibility of specifically steering customer flows and providing customers with personalized information tailored to their respective location.
Beacons are mostly used for indoor location detection. For example, in fashion and food retail, in shopping malls, in smart cities, in the industrial sector and in public buildings such as train stations, airports, museums, hospitals and so forth.
There is no limit to the range of possible applications. Successful use cases include: mobile advertising, proximity marketing, indoor navigation, asset tracking, product-related content messaging such as product details, recipes, gamification, process automation, and much more.
Beacons connect the online and offline worlds with each other. The ever-increasing growth in online sales is intensifying the pressure on in-store retailing. To benefit from the growing trend, retailers need to network their sales channels more strongly with each other – whether online, offline or mobile. A good way to do this is to use beacons. With their help, in-store retailers can address customers individually and provide them with relevant, personalized offers directly at the point of sale (POS). The range of the transmitters also makes it possible to address customers on the street and lure them into the store with interesting offers or product information.
Location-based services provide information tied to a specific geographical position. They are used to send selected, digital information tailored to a specific user at a specific location: For example, marketing campaigns such as advertising, discounts, coupons as well as navigation, locating objects and much more.
Users need a switched on mobile device with activated Bluetooth and location services. Many of the latest generation devices, such as wireless headsets or hands-free phones in cars, already have Bluetooth activated as a default setting. The user also needs a beacon-compatible app. When installing the app on the mobile device, the user must agree to receive push notifications or advertisements. Consent can be revoked at any time.
A mobile app is essential for use of the numerous functions and full potential offered by the Bluetooth low energy transmitters. OSRAM supports the integration of beacon functionality. In this way, an existing app can quickly be beacon-enabled using a Software Development Kit (SDK). Moreover, with its EINSTONE Smart Retail solution, OSRAM offers the possibility to set up a digital customer card as a smartphone app – in the customer's very own “Corporate Design” of course. The digital customer card not only opens up a new communication channel to the customer but can also attract further numerous mobile-oriented users as new customers.
With EINSTONE Smart Infrastructure, OSRAM offers the opportunity to purchase EINSTONE beacon modules only. Numerous use cases are possible based on the beacon infrastructure, such as indoor navigation, proximity marketing services, asset tracking and much more.
The heart of the EINSTONE Smart Retail solution is the EINSTONE Suite. This retail analytics platform clearly structures and links the data from all sales channels (online, offline, mobile) in a web-based user interface. In-store retailers obtain a holistic understanding of their end customers with the EINSTONE Suite and can design appropriate purchase incentives.
The EINSTONE Suite offers solutions to diverse questions through the link with the beacon technology: What is the buying history of an individual customer or a customer group? Which campaigns were shown to the user? Which vouchers did the customer use? Which stores did the customer visit and how long did she or he spend in the store in question? Which products does the customer prefer – and much more.
BLE is an extension of Bluetooth wireless technology, optimized for low energy consumption through small data packets and limited transmission performance. As a result, BLE is particularly suitable for mobile and battery-powered terminals and also for IoT sensors. BLE is a standard today in almost all mobile devices with iOS or Android operating systems.
The advantage of BLE is its low energy consumption and lower hardware costs compared to Bluetooth Classic. Using BLE, small data packets are transmitted at predetermined intervals. Bluetooth Classic allows a larger data rate and is therefore used to transmit data and sound.
Near Field Communication, or NFC for short, has a very short range; up to 10 centimeters at the most. When NFC is being used, the transmitter and the receiver must be very close to each other for the data to be transmitted. Beacons offer a range of up to 100 meters and therefore, depending on local conditions, a greater diversity of options.
A beacon management platform keeps track of large projects and monitors the beacons in use. A beacon manager is used to configure the beacons and assign specific actions to them.
Beacons are configured with a beacon manager. Every beacon has its own individual settings, so that each one triggers different actions on the smartphone. Each beacon is assigned a unique identification number. This identifier is defined in a data package on the basis of predefined main information components. All these factors define the beacon so precisely that it can be unequivocally identified in later use. Example:
- UUID (Universally Unique Identifier) = 16-byte number for the assignment of beacons to a group, such as a corporate group. Each beacon in this group has the same UUID.
- Major = 2-byte number, for example to identify a particular company within the corporate group.
- Minor = 2-byte number to precisely identify individual beacons within the company.
If you would like to use the OSRAM configurator, please send an email to firstname.lastname@example.org.
Depending on the manufacturer, a variety of beacon signals can be processed with just one beacon. OSRAM can use EINSTONE beacon technology to trigger and process up to five different signals per beacon.
There are three major Beacon standards in use around the globe. The first standard is based on Apple's iOS operating system: iBeacon. iBeacon is a proprietary and closed standard with which various actions can be triggered. The second standard comes from Google: the Eddystone format is an open-source beacon standard. There is also the open source format AltBeacon.
OSRAM caters to all three standards with EINSTONE.
In this article, we will provide you with an overview of the technology and explain the data-privacy aspect of it to you. After all, OSRAM is committed to applications that comply with data privacy law and encourage conformity.
Technology: The word “beacon” is derived from the English term “signal fire.” Beacon technology is based on the principle of sender-receiver. For instance, small transmitters (beacons) are placed in a room or location with the sole purpose of sending a particular signal at defined intervals. These signals consist of combinations of numbers and letters.
Let's say that a department store customer has installed the store's app on his or her smartphone. It is an app that is configured to receive the beacon signal. When the phone enters the range of a beacon transmitter, the phone will receive the signal and transmit it to the app. The app will then perform an action defined by the store operator, such as providing information about a sale.
Data privacy aspect: The beacon itself is just a transmitter. It cannot receive or process data. The transmitter is also not assigned to a particular individual. It is simply placed in a location or room. Under these conditions, the use and operation of the transmitter are irrelevant in terms of data privacy law. Unlike the beacon, the installed app can receive and process information. If the app is connected to a user account (f.e. part of a customer loyalty program), personally identifiable information is created for the provider of the app.
As a result of this personally identifiable information, data may be processed as a rule only with the consent of the user. Because the user must actively install the app on his or her smartphone, the individual must receive a data privacy statement before the app is installed. This statement will inform the user about data processing and authorizations related to the app in a manner that complies with data privacy law.
Conclusion: The beacon itself has no data privacy consequences because it generally does not receive or process personal data. Any person who intends to offer and use the beacon function as part of an app has the ability to collect and use personal information (particularly by linking user accounts). As a result, this individual is obligated under data privacy law to inform users/customers about the planned data processing in a data privacy statement. (Last update: 05/2017)