Free Example Beacon Data Set

There’s a new, free Zenodo real-world BLE indoor localisation dataset collected in a multi-room home under non-line-of-sight conditions. It contains RSSI measurements from 8 BLE beacons at 28 known reference points, stored across 28 CSV files, plus a floor-plan PDF showing beacon and measurement locations. Each record includes beacon MAC address, timestamp and RSSI value, and the full dataset contains 31,978 samples.

It is a labelled set of Bluetooth signal readings showing how signal strength changes from place to place inside a realistic building with walls, obstacles and multipath effects. That makes it useful for indoor positioning work because it links known physical positions to noisy real signal data rather than idealised simulation data.

For specifying systems, the data helps set realistic requirements, such as expected positioning accuracy, likely signal variability, beacon coverage and acceptable performance in rooms separated by walls. For designing systems, it can be used to choose beacon layouts, tune filtering, compare fingerprinting or modelling approaches, and study the effect of different beacon power settings. For testing systems, it provides a repeatable benchmark for checking localisation error, room-classification accuracy, robustness to noisy RSSI and regression performance across known points.

Affordable Indoor Tracking Using Bluetooth for Care and Asset Monitoring

A new paper describes a system that helps track people or objects inside buildings. It uses Bluetooth LE signals to estimate where something is located indoors.

The main idea is to place beacons around a building and use devices like Raspberry Pi receivers to pick up their signals. By measuring how strong the signal is, the system estimates how far away each beacon is, and from that works out the position of a person or object.

A problem with this approach is that Bluetooth signals indoors are unreliable. Walls, people, and other objects can interfere, making the signal jump around and giving inaccurate results. To fix this, the system uses a mathematical method, a Kalman filter, to smooth out the signal and reduce noise, making the readings more stable .

It also improves accuracy by constantly adjusting how it converts signal strength into distance, based on real measurements taken in the environment. This means the system adapts to different indoor conditions rather than relying on fixed assumptions.

In testing, the system was set up in a small 5 by 5 metre area with three Bluetooth beacons and many test points arranged in a grid. Data was collected at each point and processed to calculate positions. The final location is worked out using a method that gives more weight to closer signals.

The results showed that the system could locate objects very accurately, with errors of only a few centimetres (around 0.3 metres or less), and could update positions in real time every second. It also significantly reduced signal noise, making the tracking more reliable.

Beacon-Based Spatial Signal Mapping for Indoor Navigation

New research involves an indoor positioning system in which Bluetooth beacons are not used to directly calculate position, but instead provide a spatial signal structure that supports localisation.

BLE beacons are installed throughout the hospital and continuously transmit signals. A smartphone receives these signals as RSSI values while the user moves. During an initial setup stage, these measurements are collected across the environment to build a radio map, which represents how signal strength varies over space. Rather than storing isolated readings at specific points, this map captures a continuous spatial distribution of signals.

As the user walks, the phone combines inertial sensing with ongoing BLE measurements. Instead of relying on individual RSSI readings, the system accumulates them along the user’s estimated path to form a User RSSI Surface (URS). This surface represents the pattern of signal strength experienced over the trajectory, effectively encoding how the environment looks in terms of radio signals.

Localisation is achieved by comparing this user-generated signal surface with the pre-built radio map. The system searches for the position where the two patterns best align using surface correlation. In this way, the beacons enable localisation through pattern matching rather than through direct distance estimation or simple fingerprint lookup.

The beacon data also plays a key role in correcting errors from inertial tracking. Since pedestrian dead reckoning gradually drifts, the system tests multiple possible trajectory orientations and selects the one whose signal pattern best matches the beacon-based map. This allows the system to continuously adjust the user’s path and reduce accumulated error.

Is it Possible to Use One App to Manage All Beacons?

There are lots of brands of iBeacon and Eddystone beacon. Each brand has its own management app. We have often been asked,

“Is it possible to have just one app to manage different brands of beacon?”

While it’s technically possible, there’s no incentive for anyone to create such an app. Creating just one app to manage one beacon brand, across iOS and Android is significant effort in itself.

Google identified this problem and created the Eddystone Configuration GATT Service. The idea is that if manufacturers used just this, apps and beacons would be inter-operable. However, people want to configure iBeacon as well as Eddystone. Manufacturers also want to allow users to configure and read sensor data. Also, using Eddystone Configuration GATT Service software in all future beacons does nothing to help manage the large number of beacons that are already out there.

As of writing this, in 10 years since Eddystone Configuration GATT Service was published, no apps have been published that work with the Eddystone Configuration GATT Service. However, the Nordic nRF Connect app does understand some of the Bluetooth Characteristics to better read these kinds of beacons. There hasn’t been a rush for manufacturers to use Eddystone Standard GATT.

Back to the question. It looks like there will be a separate app per manufacturer for the foreseeable future.

How Far Can a Bluetooth Beacon Measure Distance?

A common misconception is that beacons can measure distance. In reality, beacons, with the exception of some specialist social distancing beacons and sensor beacons with an additional distance sensor, are designed to send signals rather than receive them.

Distance is determined on the receiving device rather than by the beacon itself. Devices such as smartphones are able to detect the signals transmitted by nearby beacons. When a beacon emits its Bluetooth radio signal, the receiving device measures the received signal strength indicator (RSSI), which can then be used to estimate how far the device is from the beacon.

Within a range of a few metres, changes in RSSI are usually noticeable enough to allow the distance to be estimated with reasonable accuracy. As the distance grows, however, these changes become much smaller and less reliable. This means the system can usually identify whether a beacon is nearby or further away, but calculating the exact distance becomes much more difficult.

For instance, Apple’s iOS programming interface CoreBluetooth categorises detected beacon signals into broad proximity groups such as ‘immediate’, ‘near’, and ‘far’. Rather than providing a precise measurement in metres or feet, these categories simply indicate the general closeness of the beacon.

The maximum detection range varies depending on the beacon hardware, but signals can often be picked up from around 50 metres and sometimes up to 100 metres. At these longer distances, however, the RSSI value becomes much less useful for estimating exact distance and instead only suggests whether the beacon is relatively close or relatively distant.

A Decade of Beacon Technology Research

A new paper A Scientometric Analysis of Beacon Technology Publications examines global research trends in beacon technology between 2015 and 2024, using 869 records retrieved from the Web of Science database.

The year-wise analysis shows a steady growth in research output over the decade. Publications increased from 4.60 per cent in 2015 to a peak of 14.27 per cent in 2024, indicating rising academic interest, with only a slight dip in 2023. Articles form the dominant document type, accounting for 89.53 per cent of the total, followed by review articles at 9.90 per cent, while other formats such as book chapters, editorials and data papers contribute only marginally.

Research is concentrated primarily in Engineering Electrical and Electronic (32.11 per cent), Telecommunications (23.02 per cent) and Computer Science Information Systems (21.29 per cent), highlighting the technology-driven and interdisciplinary nature of beacon research.

Country-wise distribution reveals that China leads with 28.31 per cent of publications, followed by the United States at 17.72 per cent and South Korea at 9.67 per cent. Other notable contributors include Spain, India, Italy and England. Among journals, Sensors publishes the highest number of papers, followed by IEEE Access and Electronics.

Overall, the study concludes that beacon technology research has expanded consistently over the past decade, is heavily concentrated in engineering and computer science disciplines, and is significantly driven by Chinese institutions, researchers and funding bodies, with strong international collaboration and growing global interest.

A Framework for Accurate Multi-Floor Indoor Localisation

New research presents RELoc, a WiFi fingerprinting indoor localisation framework designed to work reliably in multi-floor buildings where conventional 2D approaches often struggle because they cannot properly resolve vertical (between-floor) ambiguity. The method combines Recursive Feature Elimination with Cross-Validation (RFECV) to select the most informative WiFi access point signals, and an Extremely Randomised Trees regressor to predict positions as either 2D coordinates or full 3D coordinates including floor information. The trees model is tuned using Bayesian hyperparameter optimisation via Optuna’s Tree-structured Parzen Estimator, with the aim of improving accuracy while keeping computation manageable for practical deployments.


The authors evaluate RELoc on two public datasets, SODIndoorLoc and UTSIndoorLoc, and report that the 2D version achieves mean absolute errors of 1.84 m (SODIndoorLoc) and 4.39 m (UTSIndoorLoc). When floor level is incorporated for 3D prediction, performance improves markedly compared with the corresponding 2D setup, reducing error by about a third on SODIndoorLoc and by just over a quarter on UTSIndoorLoc, which the paper attributes to 3D modelling’s ability to separate locations that look similar in WiFi signal strength in the horizontal plane but lie on different floors. Across both datasets, the reported results show RELoc outperforming a range of baseline machine learning, ensemble, and deep learning methods, while also training faster than heavier neural approaches in their experiments.


The paper concludes that combining cross-validated feature selection with an efficient tree ensemble and automated tuning produces a strong balance of accuracy and computational efficiency for multi-floor indoor positioning.

What are the Estimated Distances for Tx Powers?

Beacons allow you to set the transmit power to levels such as -30dBm, -20dBm, -16dBm, -12dBm, -8dBm, -4dBm, 0dBm and +4dBm. The number of actual setting values depends on the beacon. 0dbm is the default power recommended for normal use. Our article on Choosing the Transmitted Power explains these values and how they relate to distance.

We are often asked ‘What are the Estimated Distance/s for Tx Powers?’. This depends on the beacon, the environment and the receiver. An analogy is someone shouting a word. How loud does someone have to shout to be heard a certain distance? It depends on how clear the person shouts, how much noise there is and how well the person listening can hear. With beacons it depends on the beacon (mainly antenna) design, how much radio frequency (RF) noise there is, the degree of RF reflections, the receiving ability of the device (smartphone or gateway) you are using and even the weather.

The only way to determine the relationship between distance and power is experimentally and it will likely change over time as the environment changes.

Improving Data From Bluetooth Beacons

A new paper addresses a core limitation of beacon-based indoor localisation systems, unstable and noisy RSSI measurements that degrade distance estimation and, by extension, location accuracy. The work focuses on Bluetooth Low Energy beacon deployments as a primary use case, alongside Wi-Fi and Zigbee, within Indoor Spatial Temporal Systems that rely on trilateration from RSSI values .

In Bluetooth beacon systems, RSSI values fluctuate significantly indoors due to multipath effects, attenuation from walls and furniture, human movement and device interference. The paper shows that conventional approaches, where RSSI filtering is performed in the cloud using Kalman or adaptive Kalman filters, introduce unacceptable latency for real-time beacon applications such as indoor navigation, proximity detection and safety monitoring. Moving filtering closer to the beacons at the edge reduces transmission delay but introduces a new problem. Adaptive filters such as robust self-adaptive Kalman filters are computationally expensive and unsuitable for resource-constrained edge devices commonly used with Bluetooth beacons .

To address this, the authors propose a lightweight edge-Kalman Filter designed specifically for noisy RSSI streams like those produced by Bluetooth beacons. Instead of continuously updating noise parameters, the filter only updates when a statistically significant change is detected between consecutive RSSI windows using density ratio estimation. This reduces unnecessary computation while still responding to real environmental changes, making it well suited to beacon receivers such as Raspberry Pis or mobile devices operating at the edge .

Experimental results using multiple Bluetooth beacon datasets show that the proposed approach substantially reduces distance estimation error compared with raw RSSI, standard Kalman filtering and robust self-adaptive Kalman filtering. In beacon scenarios with real-world noise, the edge-based approach achieves lower mean squared error while requiring fewer computations, which directly improves responsiveness and quality of service for Bluetooth beacon applications. The paper also demonstrates that cleaner, filtered beacon RSSI significantly improves downstream machine learning models for indoor location prediction, increasing classification accuracy to near-perfect levels in tested scenarios .

Which Beacons Support AltBeacon?

Our past post explains how AltBeacon fits into the range of advertising beacons can send and a further post describes the actual data format.

The following beacons support AltBeacon:

https://www.beaconzone.co.uk/FSC-BP101
https://www.beaconzone.co.uk/Feasycom/FSC-BP108
https://www.beaconzone.co.uk/Feasycom/FSC-BP109

The following beacons support custom advertising so can therefore also be set to send AltBeacon advertising:

https://www.beaconzone.co.uk/ibeacon/M52Plus
https://www.beaconzone.co.uk/Meeblue/H1Wristband
https://www.beaconzone.co.uk/Meeblue/m52aplus
https://www.beaconzone.co.uk/Meeblue/M52SAPLUS
https://www.beaconzone.co.uk/Meeblue/M52-SAPlusWaterproof
https://www.beaconzone.co.uk/Meeblue/S1USB

Note however that iBeacon has advantages over AltBeacon as explained in our article.