A Real-time Location System (RTLS) allows you to identify, track, oversee, examine, utilize, and otherwise harness the data about the whereabouts of assets or individuals. Picture the capability to monitor individuals and assets on a local, national, or even international scale. Merchants, armed forces, police, emergency responders, medical sectors, educational institutions, and virtually every industry - even domestic settings - can all gain, or already benefit, from employing RTLS solutions.
Location denotes where an object or person is, well, situated. With a Real-time Location System (or RTLS), you pinpoint and monitor individuals and assets by linking a tag, a compact wireless gadget, to each entity or person. Assets refer to things like computers, apparatus, and heavy machinery. For instance, you might affix a tag to a vehicle (an asset) to track its position within your facility; or you might have an identification card, allowing someone to find you inside a structure.
To pinpoint individuals and assets instantaneously, an RTLS persistently observes the tag's positions. Subsequently, the RTLS conveys this locational data to software that processes and utilizes this information. Here are a handful of methods to employ RTLS tags to identify individuals and assets: Fasten tags to PCs, equipment, and transport vehicles; mandate individuals to possess tags (like ID cards, bracelets, anklets, clip-ons) or integrate tags into gadgets people already have, such as mobile phones.
When you're keen to discern the tangible location of an asset or individual, based on your requisites, you might desire to know the absolute location, relative location, or symbolic location. The absolute location refers to the exact coordinates (like latitude, longitude, and elevation). Relative location denotes the span in three dimensions in relation to a stationary point. Symbolic location signifies being in a designated zone like a safety chamber or cafeteria.
To cater to the demands of diverse applications, be it pinpoint location or broader room-level location, several RTLS solutions convey the position of tags in one of these manners:
Presence-oriented locating (an individual entered the premises), room-level locating (an individual accessed a particular chamber within the structure), sub-room-level locating (an individual is positioned at a distinct area within a chamber), choke point locating (an individual passed by an ingress or egress point of a structure or chamber and proceeds in a certain trajectory), proximity-based locating (an individual is near another tag), and precise locating (an individual is identified at a specific spot within the premises).
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The location concept will determine which technology is best suited for a specific business solution. In most cases, the more RTLS reference points that are installed, the better the location accuracy - within the limits of the selected technology. In general, the location of a transponder can be detected either by passing objects or by triangulation. The first possibility uses gates or choke points to monitor the flow of tags and with the help of directional antennas, the direction of the movement is received. In this case, you know if an object is still in the room or not, when it entered or left and where it went. The second possibility is to pinpoint the position of a transponder by triangulation (or other methods of calculating the position), using several readers that receive the transponder signal. The accuracy of the computed location depends on the technology, and the surroundings of the transponder and readers: walls, furniture, or various materials (like metal) can distort the estimated range.
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Numerous systems and innovations have been crafted over time by scholars and business enterprises to pinpoint the location of individuals, machinery, and other valuables. Nowadays, an RTLS can be implemented using illumination, visual cameras, infrared, acoustics, ultrasonic waves, Bluetooth, Wi-Fi, radio frequency identification (RFID), ZigBee, Ultra Wideband, GPS, and Cellular, among other technologies (see also: RTLS chip).
Various technologies employ distinct methods, and each method addresses a somewhat different challenge or caters to different uses. These systems differ in several aspects, like the physical mechanisms used for pinpointing location, the design of the tag and location detectors, energy needs, distance, suitability for indoor versus outdoor, and temporal and spatial precision. Some technologies pinpoint location at a room's scale, some can only detect presence, and some can locate with high accuracy. Certain technologies excel outdoors, while some are specifically designed for indoor settings. Some are apt for a corporate setting, while others are ideal for a manufacturing backdrop. Some necessitate extra location detectors, while others utilize pre-existing facilities, like power or Wi-Fi, in a structure.
In certain setups, the tag whose position is being identified calculates its own coordinates (often referred to as tag self-determining); whereas in others, the tag's position is ascertained by identifying the location of a neighbouring tag (commonly known as tag indirect-determining).
However, all RTLS technologies converge on the shared objective of determining the location of valuables and individuals with the precision required by the use case, and each achieves this in its unique manner.
When many individuals think of an RTLS, their minds instantly go to the RTLS tags, which are the most visible elements of an RTLS that most individuals interact with. However, an RTLS encompasses much more than just tags. It also consists of location detectors, positioning technology and techniques, location engine software, intermediary software, and the user application. Each of these elements needs to be adaptable to cater to businesses with varied settings, diverse requirements, and distinct applications. For the moment, let's delve into RTLS tags.
An RTLS tag is a compact gadget equipped with location-based technology. These tags can be used to pinpoint both assets and the individuals who possess them. Tags should be diminutive enough to be affixed to assets or to be held by individuals.
When you fasten a tag to assets, like vehicles, you usually adhere or bolt the tag onto the asset. At times, some opt to integrate the tag within assets. The positioning of assets is essentially the positioning of these tags. If the tag gets detached from the asset, the asset's tracking becomes impossible.
Depending on the tag's mode of communication with the rest of the RTLS, tags are categorized as passive, semi-passive, or active.
Passive tags are generally passive radio frequency identification (RFID) tags. A standard passive RFID setup comprises tags (or responders) and interrogators (or transceivers or scanners). The interrogator emits a radio wave that's picked up by the passive tags situated in the RF (radio frequency) zone of the interrogator. Tags capture the wave through their antennae and then relay their saved information.
Semi-passive tags (or battery-assisted passive tags) bear a resemblance to passive tags. They don't commence any communication, must be within the RF zone of the interrogator to be detected, and relay data to the interrogator using the identical backscatter method as passive tags. Nonetheless, semi-passive tags possess a minor battery. This battery primarily serves to either track environmental factors or to provide an extended range and dependability compared to passive tags. It's crucial to note that the battery in semi-passive tags doesn't produce RF energy.
Active tags, in contrast to passive or semi-passive tags, house an internal radio and are generally powered by an inbuilt battery. Owing to their internal radio, they often have an extended range and can communicate without external triggers. For this reason, these tags can be pinpointed in real-time, perhaps every couple of seconds; however, the lifespan of the battery is heavily reliant on its usage. If you aim to attach tags to mobile projectors to ascertain their whereabouts, you'd prefer these tags to broadcast only once the projector ceases movement. In this manner, you're always informed of the projector's last known location. Conversely, if you also wish to use the tags to not merely determine the position of projectors but also to receive a notification if a projector exits the premises, you'd desire this tag to broadcast continuously at rapid intervals, enabling real-time location tracking and immediate responsive actions. Such tags are typically bulkier and pricier than passive or semi-passive tags. Given that these tags contain batteries, battery longevity is a vital consideration.
RTLS is a well-used concept throughout many different industries. Here is a list of different operational areas for real-time location systems:
Such scenarios will determine the technology and the set-up of the RTLS. Also with RTLS, there are limitations. Some technologies may not be suited in certain environments, for instance in hospitals where sensitive equipment is operating and lives are depending on them. This said every single case must be tested for a better understanding, especially the range of the signal and its strength. Placing readers in utility rooms or above doors between hospital wings to monitor assets is not a problem.
RTLS may consist of various technologies used at the same time, e.g. RFID, UWD and NFC combined in one system to perform different tasks. It is important therefore to make a proper choice to avoid wrong design decisions already at the early stages. To solve this problem a special methodology for RTLS design space exploration was developed. It consists of such steps as modelling, requirements specification, and verification into a single efficient process.
What is RTLS and how does it work?
RTLS, or Real-time Location System, is a technology used to automatically identify and track the location of objects or people in real-time. It primarily operates by attaching tags to the items or individuals to be tracked, and these tags then communicate their position to a network of sensors. The system then processes this data to determine the precise location of each tagged item or person, often displayed on a software interface. The technology behind RTLS can vary, including radio frequency identification (RFID), Wi-Fi, infrared, and ultrasound, among others.
In what industries or applications is RTLS commonly used?
RTLS has a wide range of applications across various industries. Some of the most common include:
What are the main differences between passive, semi-passive, and active RTLS tags?
The primary distinctions among these tags lie in their power sources and communication methods:
Real-time Location System (RTLS) is a cutting-edge technology designed to automatically identify and track the location of assets or individuals in real-time. At its core, RTLS operates by attaching tags, which are compact wireless devices, to the items or people being monitored. These tags then communicate their position to a network of sensors, which is processed to determine the exact location. The applications of RTLS span across various sectors, including healthcare, manufacturing, retail, and logistics, among others. The technology behind RTLS can range from radio frequency identification (RFID) to Wi-Fi and infrared. Tags can be categorized as passive, semi-passive, or active based on their power sources and communication methods. While RTLS offers numerous benefits, it's essential to choose the right technology and setup for specific environments and needs to ensure optimal performance.
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