FAQs

Radio Frequency Identification (RFID) is an automatic identification method that stores and remotely retrieves data via an RFID tag or transponder.

An RFID programmer encodes information onto a tiny microchip within a thin RFID tag that looks much like a normal pressure-sensitive carton label.

This tag is attached to a carton as it begins its supply chain journey from manufacturing plant to retailer.

RFID readers that work on the same protocol as the tag are distributed at key points throughout the supply chain. These readers activate the tag, causing it to broadcast high frequency radio waves within bandwidths reserved for RFID usage by individual governments. These radio waves transmit identifiers or codes that reference unique information about products inside the carton.

Readers relay the codes to a host computer as the carton passes through an RFID portal or moves along a conveyor anywhere in the supply chain.

The computer parses this information and makes it readily available to anyone who needs to know where a product is at any given moment.

Another important difference is that RFID is a read/write technology. So if desired the data can be written (or programmed) after it has been attached to the product. This offers a higher level of flexibility to track and update the data as the product goes through the supply chain, into the end use application or beyond.

• Bar Code labels must be seen to be read.
• RFID Labels or Tags do not have to be seen to be read.
• Bar Code labels may not be readable if they are incomplete or dirty.
• RFID Label or Tag integrity is maintained as it is underneath the actual label, inserted within the packaging or incased in a durable material.
• Bar Code labels must be placed on the outside of the product/packaging.
• Each RFID Label or Tag can be read even when multiple tagged products are sealed inside a carton (for example).
• Bar codes must be orientated on the product/packaging so the bar code is in-line with the scanner.
• RFID Labels and Tags are often orientation-insensitive, meaning the tagged item not only does not have to be seen to be read, can be in any orientation.
• Bar Code labels provide only one ID for each package of a carton, pallet or individual package of a product – for example: a 12 ounce bottle of your favorite soda will have the same bar code on every 12 ounce bottle of that same soda.
• RFID Labels and Tags provide a unique ID for each and every product and can be associated with individual information such as the manufacturing location; date shipped, lot number, etc.
• Bar Code labels are printed, or written, once and cannot be changed at any time throughout the supply chain without another bar code label attached over the original label.
• RFID Labels and Tags provide read/write technology. The data can be written (or programmed) can be changed or updated at any time in the supply chain and even into the end use application or beyond.

As with any project you need a well-defined problem statement.

• What problem are you trying to solve and what are the necessary elements required to solve the problem?
• How will you measure success?
• Does the solution offer an attractive ROI?

If this is your first RFID project, it is important to work with an experienced RFID Systems Integrator to help lay out the framework for the project and offer guidelines on the type of solutions that should be considered.

We work with many highly qualified RFID Systems Integrators. Find one in your area now.

An inlay is the functional portion of the RFID label. It is made up of the antenna to which a microchip is attached. The inlay is typically supplied on a substrate or carrier and is called a dry inlay, or if adhesive is added, it is called a wet inlay. In both cases the inlay is often supplied to a converter where it is inserted into a label or tag or whatever type of construction is required for the application.

The first difference is the operating frequency. UHF (Ultra High Frequency) is 860 – 960 MHz depending on the country of use and HF (High Frequency) works at 13.56 MHz.

Generally the operating range for HF is less than 1 foot while UHF can operate at significantly longer distances.There are also differences in performance related to the types of products the inlays or labels are attached to as well as the operating environment.

For this reason, it is always important to consult with an Avery Dennison sales or technical representative or qualified Avery Dennison RFID partner to review your products and requirements and, if warranted, perform a site survey.

A UPC only identifies object classes or generic categories of product — such as a pack of Wrigley’s Spearmint gum. An EPC uses a unique serial number to identify each individual pack of gum and makes it possible to automatically track products from manufacturer to store shelf.

The EPC, or Electronic Product Code, is the next generation of automatic product identification. EPCglobal, an organization leading the development of industry standards for EPC, refers to the EPC as a “simple, compact ‘license plate’ that uniquely identifies objects (items, cases, pallets, locations and so on) in the supply chain.”

UPC stands for Universal Product Code, which has been used to auto-identify items via machine-readable barcodes for a number of years.

Like all wireless communications devices, RFID tags and readers operate under assigned frequencies. In the United States, these frequencies are assigned by the Federal Communications Commission (FCC). The European Union’s frequency assignments are governed by the European Telecommunications Standards Institute (ETSI).

Most of the world uses frequencies defined within the ETSI or FCC designations. The FCC allows several frequency bands to be used for RFID including the 125kHz, 13.56MHz , and 902 to 928 MHz bands. Low Frequency (LF) tags operate in the 125kHz range. Tags operating in the 13.56 MHz range are referred to as high frequency (HF) tags. RFID tags operating 902 to 928 MHz band are referred to as ultra high frequency (UHF) tags. In North and South America, for example, 902-928 MHz band is commonly used for asset management. The ETSI recommended UHF RFID operational frequencies for Europe are between 865-868 MHz.

While there are many differences between UHF and HF tags, the most relevant differences are the following:

• UHF tags have longer ranges and are thus more suitable for supply chain applications (i.e. reading cartons and pallets at a distance of tens of feet).
• HF and LF tags have shorter ranges and have therefore been the technology of choice for proximity applications such as library book tagging and security access control (i.e. reading at a few feet).

Many applications like retail apparel tagging and supply chain applications are based on the 902-928 MHz frequency band. Applications for payment cards and library book tagging use the 13.56 MHz band.

Avery Dennison’s RFID inlay portfolio is based on UHF – 860-960 MHz – and HF technology – 13.56 MHz  – depending on application need.

An RFID tag is a label that has an RFID inlay inserted between the label facestock and liner.

An RFID tag has a protective/printable facestock, a layer of adhesive, then the RFID inlay, another layer of adhesive, and finally a removable liner.

The RF inlay provides the RFID functionality. The inlay consists of a carrier sheet that holds an RF antenna, to which is bonded a tiny microchip. The liner and facestock are typically made of paper, but may also be made from other materials such as plastic films.

The selection of materials determines how well the tag will survive and whether it will be compatible with printers, applicators and other system hardware. Material selection may also have to accommodate FDA regulations. In addition, there are mechanical considerations, such as selecting an adhesive that will ensure the tag will remain adhered to the carton.

RFID tags can be encoded with a stand-alone reader/antenna setup. However in a typical real-world application that function is accomplished within an RFID-enabled printer or printer/applicator.

Active tags broadcast under their own power, using an onboard battery. As a result, they can have very long read ranges. They are more expensive than passive tags, so they’re normally used to tag very high-value items.

Passive tags are the most economical RFID tags and the most common tag used in supply chain applications. They don’t have onboard batteries like active tags, because they get their power from RFID readers. The RFID reader sends electromagnetic waves to the tag’s antenna. Using energy from these waves, tags broadcast a signal back to the reader.

Semi-passive tags are a small and light-weight hybrid of active and passive tags. They generally use a battery to power the electronic logic (like active tags), but can also transmit data using power generated from RFID readers (like passive tags).

Functionally, an inlay consists of an antenna and a microchip.

The antenna drives tag performance and governs how well the tag will work in a particular application. Precision-designed to receive and broadcast RF signals, the antenna is made from a conductive material (such as silver, copper or aluminum). The antenna makes contact with an RF reader over a distance determined in large part by the amount of metal and size of the antenna. Contacts attached to the microchip make the circuit between the microchip and antenna.

The chip design determines the protocol or class of the tag’s operation. Different microchips have different features that can also affect performance. RFID microchips contain circuitry capable of handling a variety of functions from power conversion to data storage and retrieval.

An inlay is the functional portion of the RFID label. It is made up of the antenna to which a microchip (IC) is attached. The “dry” inlay is typically supplied on a substrate (or carrier). If adhesive is added, it is called a “wet” or “pressure-sensitive” inlay.

In both cases the inlay is supplied to a converter where it is inserted into a label or tag or whatever type of construction is required for the application.

A strap consists of a microchip with two oversized contact pads on a carrier sheet to facilitate high-speed roll-to-roll manufacturing. In conventional flip-chip manufacturing, the microchip is a very small component, less than 1mm square, with tiny contact pads that must be placed very precisely on the antenna. This can be a relatively slow process. To overcome this problem, Avery Dennison RFID has developed an innovative high-speed strap attach process that substantially improves yield rates.

Traditionally, RFID antennas were etched from copper — a relatively slow, relatively wasteful process. Today’s antennas tend to be produced with more efficient methods such as etching or stamping.

Avery Dennison RFID produces standard products that comply to international RFID communication protocol standards:

For UHF Products: EPC Class 1, Gen 2 and ISO-18000-6C

For HF Products: ISO-15693 and ISO-18000-3

Avery Dennison RFID products are available in several configurations.

• Dry Inlays – a polyethylene terephthalate (PET) substrate with an RFID chip and antenna bonded to it and then sandwiched with another protective PET lamination layer and delivered in roll form.
• Pressure Sensitive Inlays – same as Dry Inlay above, with the addition of a “wet” adhesive backing and liner.
• Encapsulated or Durable Finished Transponders – an inlay with the addition of a durable encapsulate for longer tag life.

Avery Dennison RFID supplies inlays and pressure-sensitive inlays to label converter partners. Avery Dennison RFID also supplies encapsulated tags to Systems Integrators.

Tests performed in free space (i.e. performance tests of unattached tags conducted in a controlled environment) are the starting point for performance tests. Although these tests provide good baseline information, they provide insufficient information on which to select tags for specific applications. Carton contents, the orientation of the tag toward the reader antenna, and other environmental issues such as radio frequency noise and physical object interference can impact performance.

Component testing assures that the inlay’s electronic portions will perform as expected. Different test protocols must be followed for different classes of microchips to evaluate near-field performance. This testing protocol includes a “writing to chip” test performed on Class 0+ and Class 1 inlays (including Gen 2).

Another component of the testing protocol is the read sensitivity test. This is performed on all inlays to make sure they meet far-field requirements.

RFID testing provides necessary data on both component quality and expected performance in real-world conditions. Avery Dennison RFID employs an “end-to-end” testing approach, challenging the quality of our inlays from prototype to delivery. Our Atlanta Technical Center simulates the real-world of the supply chain with conveyor, portal and RFID printer and printer/applicator hardware.

An RFID label is a fairly sophisticated communications device. It contains a microchip which could be subject to physical damage, data corruption and damage from electro-static discharge (or ESD).

An RFID tag is also a pressure-sensitive label subject to the same environmental challenges as any self-adhesive label, including physical impact, abrasion, moisture and excessive temperatures.

In RFID applications, size and form factor matter. Generally speaking, all other things being equal, the larger the tag antenna, the more cross section it has to receive and broadcast signals so the “better” it performs. That said, bigger antennas cost more and they may be over-engineered for a given application. Package space limitations also impose parameters on tag size.

The inlay’s form factor, or size, must also match the type of insertion equipment used in the label converting process, as well as the physical specifications and capabilities of the RFID encoders/printers/applicators being utilized.

As tagged cartons and pallets move through the supply chain, they interact with readers mounted in a variety of locations. They must be able to reliably broadcast all the way back to each reader. However, tags offering too much read range can cause serious operational problems if they’re seen by the wrong reader.

Far-field performance rates how well a tag is read over the distance to the reader. Near-field performance rates how well the tag performs in an encoder/printer/applicator, where the reader antenna is only inches away from the tag at most. These performance rates must be balanced to tune tags to be read well both near and far.

Many inlays, especially those with a small vertical profile, have an antenna read field pattern that resembles a donut, meaning that they cannot be read from the direction of the antenna tips. This can cause null spots (no reads) when trying to read the tag end-on. That is why Avery Dennison RFID designed our AD-831 inlay to be read from any orientation, with no null spots allowing it to be read from any direction.

Carton contents can also influence read range and there are many examples of a tag that reads well in one place on a carton and not at all when moved a few inches. Carton contents and their arrangement inside the carton can create hot spots and dead spots on the cardboard surface. Avery Dennison developed our Sweet Spot tester to determine the optimal RFID tag position on a carton relative to the contents inside.

A carton’s contents can alter tuning and interfere with the tag’s ability to receive energy from the reader.

Certain substances, especially metals and liquids, can often have a dramatic effect on the RF performance of tags. For this reason, these materials are often called “difficult” or “RF-unfriendly.” Aside from de-tuning, these materials can cause other problems like absorption, shielding and reflections.