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Values of RSSI are measured in dBm, and a typical one meter calibration value for a beacon transmitter will be -59 dBm. Beacons must be calibrated by measuring the signal level (known as Received Signal Strength Indicator or RSSI) at this reference distance and then configuring the beacon to transmit reference value. As an example, when using iBeacon technology, the standard measurement is the signal level that an iPhone 5s (the latest model available when iOS 7 was released) will measure for a beacon at a distance of one meter. Reference Transmitter PowerĪ beacon transmission includes a transmitter power field that indicates how strong the signal should be at a known distance. This doesn’t mean that you can’t use beacon distance estimates directly - it just means you first need to understand the fundamentals of how they work and the limitations on the quality of information they can provide. Apple is vague at the definitions of these buckets, but experimentation shows that “immediate” means about 0.5 meters or less, “near” means about three meters or less, and “far” means more than three meters. The CLBeacon class also provides a second property called proximity which bucketizes the distance estimate into “immediate”, “near” and “far” groupings. The recommended approach is to use it only for comparison between beacons to see which is closest. But instead of calling this property distance, Apple called it accuracy, probably in an effort to discourage its use as a raw distance indicator. The CLBeacon class that provides access to beacon ranging information has a field that provides an estimate of the distance to the beacon in meters. When Apple introduced iBeacon technology in iOS 7, their documentation recommended against direct use of distance estimates. For this reason, a device that is within a few meters of a beacon can provide much more accurate distance estimates than a device that is 10 meters or more away.
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For strong radio signals (a high signal-to-noise ratio), noise is far less of an issue than with weak signals (a low signal to noise ratio). Background radio noise exists everywhere (it’s what causes the static seen on an old analog TV). Factors that influence the error in the estimate include reflections of the radio signal, obstructions that attenuate the radio signal, and orientation of both the phone and the beacon.īy far the biggest factor affecting error in distance estimates is radio noise. The reasons for these distance estimate variations and the steps that can be taken to reduce them are some of the most frequent questions we get about beacons. For a beacon that is 5 meters away, distance estimates might fluctuate between 2 meters and 10 meters. The most basic use of beacon technology is to determine how far a mobile device is from a beacon, but as anybody who has played with beacon ranging knows, these distance estimates can have a significant degree of uncertainty.