RFID FAQ

The most frequently asked questions about Radio Frequency Identification, RFID Tags and RFID Readers

General RFID FAQs

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• What RFID means
• What is an RFID Tag?
• What are active and passive Tags
• How RFID Tags can be read
• What are the main frequencies used in RFID technology

UHF RFID FAQs

• What is the EPC Gen2 V2 standard
• What is RAIN RFID?
• How many UHF Tags can be detected at the same time?
• How UHF chips are classified?
• What is the memory capacity of a UHF chip?
• What is the reading distance of UHF Tags?
• What is the operating temperature of UHF Tags?
• What materials interfere with or hinder the reading of UHF Tags?
• What is the difference between Linear-polarized and Circular-polarized antennas?
• What are anti-collision systems?
• What kind of interfaces are available for UHF RFID readers?
• Are RFID radio waves harmful to the human body?

What RFID means

RFID stands for Radio-Frequency Identification. It is an identification technology (of a person, an animal, or an object) based on radio-frequency communication. The identification takes place via RFID Tag, or transponders equipped with a unique identification number and, depending on the models, also with additional memory. RFID tags, particularly passive ones, have a particularly low cost (about € 0.05) and do not require power. For this reason, they can be applied to individuals and things in different fields: logistics, inventory, supply chain, automation, marketing, and many others, including several applications in the Internet of Things.

What is an RFID Tag?

An RFID Tag is a chip, or transponder, with an antenna that amplifies the radio signal. In the most common form, an RFID Tag looks like a label with the circuit visible in transparency. It is also called wet inlay, when it is adhesive, or dry inlay when it is not.

What are active and passive Tags

Active tags have an internal battery, which is generally used to increase the transmission power and, consequently, the reading distance. A typical example of passive tags is the Bluetooth Beacon.

The passive tags, on the other hand, do not have an internal power supply: a capacitor is used which, once charged, generates the electromagnetic field that carries the information contained in the chip. The solicitation takes place through an RFID reader, which usually takes a fraction of a second to feed the Tag and read it. The most common tags are the passive ones, because of the great advantage of not needing a battery.

For completeness, there are also semi-active tags, therefore equipped with power supply. This power supply is not used for radio circuits, but is used for additional functions, such as temperature or movement sensors.

On RFID.it, we mainly deal with passive Tags.

How RFID Tags can be read

The RFID tags are read / detected by special fixed or mobile devices, called RFID readers, or RFID readers. These readers solicit the transponder by induction or electromagnetism, which activates and transmits the information it contains. RFID readers can have an integrated or external antenna. If the model supports it, more than one antenna can be connected to a reader, so as to identify tags in different points, or to cover a certain gap accurately.

What are the main frequencies used in RFID technology

Depending on the frequency of the chip, there are several RFID categories, with their own characteristics. Below, we report the most common, governed by ISO standards.

• 125/134 kHz - RFID LF (Low Frequencies), at low frequencies, encoded by the ISO -2 standard. They have a reading distance of a few centimeters, a low speed of data transmission, and are used above all for the identification of animals, but also for vending machines, burglar alarms, access control.
• 13.56 MHz - RFID HF (High Frequencies), at high frequencies, coded by the ISO -3 standard. The reading distance is always a few centimeters (up to 10) and the speed from low to medium. This particular frequency is also called NFC (Near Field Communication) and is spreading in recent years thanks to the fact that many smartphones can act as readers for these Tags, giving rise to various and innovative applications.
• 860-960 MHz - RFID UHF (Ultra High Frequencies), at very high frequency, encoded by the ISO -6 standard. This range is particularly widespread due to the reading distance that reaches several meters, always using passive tags. There are differences between UHF readers with US standards and those with European standards relative to the frequency used, but a standard called RAIN has been coded for tags that are compatible with both. Widely used for logistics, inventory, timekeeping, access control.
• 5.8 GHz - RFID SHF (Super High Frequencies), represents the highest RFID frequency range, encoded by the ISO -5 standard. It includes only active tags, therefore with an internal battery, which can reach a detection distance of hundreds of meters. A typical example is the ones used for the Electronic toll collection (ETC).

On RFID.it, we deal with RFID LF, HF and UHF technology.

What is the EPC Gen2 V2 standard

It is the second generation EPC (Electronic Product Code) protocol, designed to operate internationally. The EPC Gen is the center of attention because a convergence between the UHF Gen 2 standards and a revision of the ISO -6 seems likely, ie it applies only to UHF tags. The unification process could contribute to further acceleration in the global adoption of RFID.

The GS1 EPC Gen2 air interface protocol, first published by EPCglobal in , defines the physical and logical requirements for an RFID system with passive tags, operating in the UHF frequency range from 860 MHz to 960 MHz. In the last ten years, EPC Gen2 has established itself as a standard for UHF implementations in multiple industries and is at the center of increasingly RFID implementations.

In , Gen2X has been released, with many significant improvements in terms of performance, security and functionality. Learn more.

What is RAIN RFID?

RAIN RFID is a global alliance that promotes the universal adoption of RFID UHF technology in a similar way to other wireless technology organizations including NFC Forum, WiFi Alliance and Bluetooth SIG. RAIN uses the GS1 UHF Gen2 protocol which ISO/IEC has standardized as -63. The word RAIN - an acronym derived from RAdio Frequency IdentificatioN - is intended as a nod to the connection between UHF RFID and the cloud, where RFID-based data can be stored, managed and shared via the Internet. A RAIN RFID solution uses a reader to read and write a tagged item, manage data and act.

Historically, 2 slightly different operating standards have spread: one for the typically European market, operating at a frequency of around 860 MHz, and one for the American market, which operates at around 960 MHz. The ISO -63 standard distinguishes passive UHF Tags operating at both frequencies, so they can be used globally without problems.

The UHF RFID tags published on RFID.it are all compliant with the RAIN standard and ISO -63.

How many UHF Tags can be detected at the same time?

UHF technology allows to identify a very large number of transponders (over 700 units), using anti-collision systems (see below). The maximum number depends on the transit speed, the type of information to be collected for each transponder and the type of RFID controller that is used (memory buffer available).

How UHF chips are classified?

UHF chips can be classified in different ways, but mainly based on the size and characteristics of the EPC, TID and user memory. For more information on the technical characteristics of the chips, click here.

What is the memory capacity of a UHF chip?

The memory capacity (user memory) of a UHF chip is currently 512 bits (64 bytes) or bits (128 bytes). Chips with a capacity of 8 kbytes have recently been announced, but the costs are still very high.

What is the reading distance of UHF Tags?

The communication distance of UHF technology is one of the strengths of this particular frequency, as it allows a greater range than other technologies. The distance varies according to the readers and tags used. The mobile PDAs equipped with RFID UHF technology allow to communicate with the tags at distances of 4-6 meters, while the Long Range UHF type controllers detect the tags at 10/15 meters. With specific on-metal passive tags, communication distances of up to 30/35 meters are possible.

What is the operating temperature of UHF Tags?

For the most common tags, such as wet inlays (plastic labels with embedde chip and antenna), the operating temperature is between -20°C and +70°C. For extreme temperatures, special tags are made, with more insulating casings, suitable to resist in more hostile contexts.

If you are looking for more details, kindly visit UHF Rfid Reader Modules.

What materials interfere with or hinder the reading of UHF Tags?

Metal, carbon and all non-"radiolucent" conductive materials can create the Faraday Cage effect.

In particular, UHF frequencies are attenuated above all by liquids. However, there are transponders that can be applied to liquids with suitable insulating materials.

For metallic materials, on the other hand, special Tags have been designed, called shielded, or anti-metal, or even on-metal, which guarantee an optimal reading even when applied to metal surfaces.

What is the difference between Linear-polarized and Circular-polarized antennas?

A "linear polarization" antenna is a device that focuses the radio energy coming from the reader in a single orientation (or polarity). This allows to increase the reading distance, succeeding in increasing the penetration capacity of the emitted radio wave; "Circular-polarized" antennas instead emit radio waves in a circular way (as you can guess from the name): in this case the reader radius of action is smaller but there are more possibilities to "hit" the Tag; in fact this latter type of antenna is used in situations in which the tags applied to the products cannot be controlled, whereas instead in the case of readers equipped with a "linear-polarized" antenna, the labels must be aligned very precisely in the direction of the antenna itself.

What are anti-collision systems?

Anti-collision systems are procedures that are used to manage the reading of several tags simultaneously; technically these systems prevent the annoying episode of the overlapping radio waves, emitted by different tags, which end up disturbing each other. Within a single electromagnetic field generated by a single antenna of a reader, it is possible to manage the reading of different Tags thanks to algorithms called precisely anti-collision, which regulate the time intervals in which the Tags must be read: in this way no interference occurs and there is no risk of receiving incorrect or inaccurate information.

What kind of interfaces are available for UHF RFID readers?

The interfaces available on the host side are the most common and include: Ethernet RJ45, USB, RS232, RS485, TTL, Wi-Fi, GPRS, TTL / RS232. Various models of controllers are also available with Inputs, Outputs and relays, integrated microcontrollers for the development of embedded applications.

Are RFID radio waves harmful to the human body?

RFID devices emit radio waves, very low frequency electromagnetic waves, harmless to our body.

However, we live in a world pervaded by decades of electromagnetic waves, not least those of 5G, but consider that even a normal television or an old radio emit electromagnetic waves. It is therefore more than half a century that our bodies coexist with electromagnetic waves of any kind without ever having been certified for health damage.

FAQ for RFID Reader Modules

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Frequently Asked Questions: RFID Module for Building RFID Readers

What components are necessary to build an RFID reader with a module for prototyping?

Building an RFID reader with a module for prototyping involves several key components, including the RFID module itself, an antenna, power supply, microcontroller, and communication interface (such as USB, UART, or Ethernet). These elements are essential for data capture, processing, and transmission. Selecting compatible components ensures optimal performance during prototyping.

What frequency bands does the RFID module support?

Most RFID modules used for reader prototyping operate in either the High Frequency (HF) range of 13.56 MHz or the Ultra-High Frequency (UHF) range, typically between 860 MHz and 960 MHz. Depending on your application, it’s critical to choose the correct frequency that aligns with both the region of deployment and the RFID tags in use.

Can this module support multiple tag protocols?

Yes, modern RFID modules are often multi-protocol compatible, supporting common standards like EPCglobal Gen2 (ISO -6C), ISO A/B, and ISO . This versatility allows the RFID reader to communicate with a variety of tags, making it suitable for different applications from access control to inventory management.

What antenna considerations are there for my RFID reader prototype?

Antenna selection is crucial as it influences the read range and performance of your RFID reader. Factors like antenna size, gain, and polarization should be considered. GAO RFID offers a wide range of antennas compatible with our modules, ensuring you can tailor your setup for long-range or near-field applications.

How do I integrate the RFID module with a microcontroller or single-board computer?

The integration process depends on the communication interface provided by the module. Most modules can connect via UART, I2C, or SPI, enabling you to link them to a microcontroller or a single-board computer like a Raspberry Pi. GAO RFID’s modules come with detailed technical documentation to support this integration, along with expert advice to assist in the process.

What power supply options are needed for this module?

Typically, an RFID module requires a DC power supply, often between 3.3V and 5V, depending on the model. Some modules may offer power over Ethernet (PoE) options for ease of deployment. It’s important to ensure your power source is stable to avoid data loss or read failures.

Can I configure this module for specific applications?

Yes, RFID modules are designed with flexibility in mind. You can configure parameters like power output, communication protocols, and tag filtering through software commands. GAO RFID provides technical support to guide you through the configuration process, ensuring the module is optimized for your specific use case.

How do I troubleshoot connection issues between the RFID module and the host device?

First, verify that the communication interface is properly configured. Check for loose connections or incorrect wiring, and ensure that the baud rate and other communication settings match between the RFID module and the host device. GAO RFID provides troubleshooting guides and expert support to help resolve these issues swiftly.

What regulatory standards do I need to consider when building an RFID reader?

It’s important to comply with regional regulations. For example, in the U.S., the Federal Communications Commission (FCC) governs the operation of RFID devices, while in Canada, Industry Canada (IC) sets the standards. Our RFID modules meet stringent quality and regulatory standards, ensuring compliance in North America.

How does the module handle environmental factors such as temperature and humidity?

Most RFID modules are designed to operate in a wide range of environmental conditions, with temperature ranges from -20°C to +70°C and humidity tolerance between 10% to 95%. GAO RFID’s modules undergo stringent quality assurance testing to ensure reliability in various environments, whether indoor or outdoor.

How scalable is the RFID module for larger deployments?

Once the RFID reader is prototyped, it can easily be scaled for larger systems. GAO RFID’s modules are suitable for integration into scalable solutions, allowing businesses to expand their RFID infrastructure as needed.

Case Studies

• New York City – USA: A leading logistics company in New York integrated GAO RFID’s module into their custom-built RFID readers for warehouse management. The solution improved inventory accuracy and reduced labor costs.
• San Francisco – USA: A prominent university in San Francisco used GAO RFID’s module to prototype a reader for research purposes. The solution was deployed in their material tracking system to enhance their R&D operations.
• Toronto – Canada: A government agency in Toronto worked with GAO RFID to develop an RFID reader using our module for secure access control, increasing security efficiency across multiple facilities.

Our products are in stock and can be shipped overnight to Continental U.S. and Canada from one of our local warehouses. If you have any questions, our technical experts can help you. Please fill out this form or us.

If you want to learn more, please visit our website UHF RFID Printer Module.