ART923X1015YZ10

RFID Tags and Readers RFID Tagging  RFID tagging is an ID system for identification and tracking purposes that uses radio frequency identification devices.  An RFID tagging system consists of the tag, a read/write or only read device, and a system application for data collection, processing, and transmission.  RFID tags consist of minimum two parts: an integrated circuit and an antenna for receiving and transmitting the signal. The tag information is stored in a non-volatile memory. 2 Types of RFID Tags  RFID tags that include power source are known as active tags versus those without a power source which are passive tags.  A passive tag is activated momentarily by the radio frequency ( RF ) scan of the reader. The electrical current is just enough for transmission of an ID number.  Abracon’s RFID Tag series includes variety of passive ceramic tags without chip which have to be matched with a compatible IC to be utilized. Advantages ACTIVE RFID Reads long distance Higher data bandwidth Iniciates Communications Expensive Disadvantages Can't function without battery Large in size, not for small applications PASSIVE RFID Tag's function doesn't rely on battery Inexpensive Variety in size including small sizes More resistant to damage and harsh environments Communication depends on antenna size and shape Read range is limited Difficulty reading through metal or liquid 3 RFID System Applications Some of the many applications of RFID tagging are as following:  Supply chain management: In fast paste manufacturing, shipping, and distribution environments, RFID tagging can provide real-time data on the status of individual items. Unlike bar code stickers, RFID tags don't require line-ofsight between the tag and the reader.  Material Management: In large scale construction projects, material management is often the largest project expense. RFID tracking system can significantly reduce search related expenses and time.  Gas and oil drilling and pipeline management  Toll collection and contactless payment 4 RFID Tag Types  Tag's material and structure are different depending on the end application and environment  There are three main categories known for RFID Tags.  Inlay Tags occupy 70% of the market. This type of Tag is mainly used in clothing and merchandise management, and can be replaced by bar code. They are low cost and easy to use but can be employed only in metal free and normal temperature.  Composite tags occupy 20% of the market. This type of tag is mainly applied in storage and pipeline management. They can be used in metal environment but have poor performance.  Ceramic Tags occupy 10% of the market. This type of Tag is used in medical equipment, oil and gas pipeline and drilling management which relate to harsh environment. They are small, high temperature and high pressure resistant. However they have narrow bandwidth and long manufacturing cycle. Inlay Tags Composite tags Ceramic Tags 5 RFID Ceramic Tag Built  The passive RFID contains two parts: The tag antenna and the chip.  The Tag antenna is made of a dielectric base and a conductive area.  The main characteristics of RFID tags are frequency, recognition distance, and the chip agreement and capacity.  Abracon’s RFID tag series are without the chip and need to be matched with their compatible chip before being utilized in end application. 6 How does communication occur?  Data between reader and tag are transmitted in half-duplex mode.  The reader continuously generates a RF carrier wave. When the passive tag is within its read range, this signal powers it.  The tag responds to the reader by backscatter and the detected electromagnetic field indicates the presence of the tag.  The time taken for the tag to become fully functional is called the setup time. After this time, the reader requests for read/write access by sending instructions to the tag.  The demodulator recovers the received data stream.  After demodulation of the received instructions and handshaking, the information stored in the tag is transmitted back to the reader by backscattering.  After all of the read/write operations are completed, the reader acknowledges the successful completion of the communication and the tag shuts off. 7 RFID Tag Installation methods  TAG antenna should be installed in a housing. 3M adhesive tape or screw can be used way fix the housing on the end product.  All pictures shown are the finished TAG antenna installed in casing.  Injection molding is another method for installing the tag antennas. The inject material is mostly resin. The type of resin depends on the project requirements. Different resin requires different injection temperature which depends on the finished product. Double faced Adhesive Tape Plastic housing installation Injection Molding Installation 8 Chip Types to be accompanied by Abracon Tags  The Chip type that is compatible with Abracon’s RFID tag antenna is international main agreement, EPC Gen 2 (ISO180006C) and the capacity depends on the chip package.  International main chips Impinj (M4QE ), Alien (H3) and NXP are the chip types used with the Abracon ceramic tags. H3 and M4QE are the market mainstream which are utilized on 90% of Abracon RFID tags. 9 Gen 2 RFID Tag Memory Types  Gen 2 RFID tags are built of an antenna and a chip (IC). The ICs for Gen 2 tags contain four types of memory.  Reserved Memory stores the kill password and the access password (each are 32 bits). The kill password permanently disables the tag (very rarely used), and the access password is set to lock and unlock the tag’s read/write capabilities.  EPC Memory stores the EPC code, or the Electronic Product Code. It has a minimum of 96 bits of writable memory. The EPC memory is what is typically used in most applications if they only need 96 bits of memory.  TID Memory is used only to store the unique tag ID number by the manufacturer when the IC is manufactured. Typically, this memory portion cannot be changed.  If the user needs more memory than the EPC section has available, user memory can be utilized. Typically, the extended memory is no more than 512 bits. 10 Mounting the Chip on the Ceramic Tag  Bonding, SMT and Flip Chip are the three types of technologies currently being utilized to mount a chip on ceramic RFID tags.  Abracon’s ceramic RFID Tag series are passive and they have to be matched with their compatible chip to be utilized.  Bonding technology is the most used method to mount a chip on ceramic TAGs. Bonding offers high stability and high reliability, but the highest temperature limit is 180˚C.  SMT technology is rarely used. It is temperature resistant up to 220˚C. The reliability is not as good as Bonding method and the cost is higher because of special silver material requirement.  Flip chip technology is the mainstream technology for PET flexible ceramic TAGs. The advantage is higher temperature resistance which can reach up to 300˚C. However the reliability is the worst of all three methods. 11 ART923X855406TX02 Size: 85*54*0.635mm Frequency: 865~868MHz /902~928MHz Recognition distance: 8.5m（Fixed reader） Agreement: EPC Capacity: EPC - 96bits User - 512bits TID - 64bits The ceramic type used in this type of tag is microwave material with dielectric constant of 10. This type of tag is electronic card which is suitable for the long distance management, vehicle management, license plate management, ETC charges and etc. 12 ART868X130903TX13 Size: Frequency: Identification Distance: Agreement: Capacity: 13*9*3mm 865~868MHz /902~928MHz 1.5m（Fixed reader） EPC EPC - 96bits User - 512bits TID - 64bits Microwave ceramic material with dielectric constant of 130. A label applied to electronic control of small items can be attached to the metal surface or embedded within the metal. This model is suitable for mold management, firearms management and office management. 13 ART868X2117225TX21 Size: 21*17*2.25mm Frequency: 865~868MHz /902~928MHz Recognition distance: 2.2m（Fixed reader） Agreement: EPC Capacity: EPC - 96bits User - 512bits TID - 64bits Microwave ceramic matrix material with dielectric constant of 92. Suitable for valuables management, can be attached to a metal surface or embedded within the metal. For example: pipes crossing under ground management, water table management, license management, office management, and etc. 14 ART868X25275YZ25 Size: 25*25*2.75mm Frequency: 865~868MHz /902~928MHz Recognition distance: 3.0m（Fixed reader） Agreement: EPC Capacity: EPC - 96bits User - 512bits TID - 64bits Microwave ceramic matrix material with dielectric constant of 68. This type of tag can be attached to a metal surface or be embedded within the metal. For example: container management, warehouse management and oil and gas pipeline management. . 15 Notes  RFID Tag can not be completely wrapped by metal. At least one side should be exposed to non-metal material to be used for signal transmission. The top side of the tag can be covered by not metal housing.  Along with the increase of dielectric constant, the thickness increases and the frequency decreases.  RFID Tag is attached to a metal surface, the frequency will increase along with the increase of metal surface.  RFID Tag cannot radiate signal if it is in the liquid or when the surface is covered by liquid.  Either the earth or human could absorb radiation signal of the Tag.  The surrounding area of the Tag should not have any other strong radiating device with mutual interference. 16 Passive RFID Reader Applications  Built in antenna in portable hand held read and write device. The features of this type of device are portability, high performance and small size.  Built-in antenna in semi-fixed read and write devices. Semi-fixed read and write devices are between handheld and fixed. They can be easily dismounted and have high demand for passive RFID Readers.  Built-out antenna in multiport read and write devices. The antenna has built-out structures and one read and write device can connect to several antennas. 17 ARRUN5 Size: Frequency: Bandwidth: VSWR: Gain: Polarization: 80*80*6mm 865~868MHz /902~928MHz 26MHz