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Selecting the correct RFID (Radio Frequency Identification) frequency is very crucial for the successful implementation of an RFID system. RFID operates on different frequency bands, and each frequency has its own characteristics and applications. The three main RFID frequency bands are as follows: Low Frequency (LF) bands, High Frequency (HF) bands, and Ultra High Frequency (UHF) bands.
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Here's a guide to help you to select the correct RFID frequency for your application:
1. Understand the RFID Frequency Bands:
Low Frequency (LF - 125 kHz):
Short read range.
Good for proximity applications.
Less affected by water and metal.
Commonly used in access control and animal tracking.
High Frequency (HF - 13.56 MHz):
Medium read range.
Good for applications requiring data transfer (e.g, payment cards).
Used in access control, contactless payment, and NFC.
Ultra High Frequency (UHF - 860-915 MHz):
Long read range.
Well-suited for supply chain management and logistics.
Can be affected by water and metal.
2. Consider Application Requirements:
Read Range:
If you need a longer read range, UHF may be preferable.
Environment:
Consider the presence of water, metal, and other materials that may affect signal performance.
Data Transfer Speed:
HF is often used for applications requiring faster data transfer.
Regulatory Considerations:
Check regional regulations and standards that may influence the choice of frequency.
3. Regulatory Compliance:
Different regions may have regulations governing the use of specific frequency bands. Ensure that your chosen frequency complies with local regulations.
4. Interference and Collisions:
Consider the potential for interference from other electronic devices operating on the same frequency.
5. Cost Considerations:
UHF RFID systems are often more cost-effective for large-scale deployments due to their longer read range.
6. Testing and Pilots:
Conduct small-scale tests or pilots to assess the performance of different frequencies in your specific environment.
7. Future Scalability:
Consider the scalability of the RFID system. Will your needs change in the future? Choose a frequency that aligns with potential future requirements.
8. Consult with RFID Experts:
Seek advice from RFID experts or consultants who can provide insights based on their experience.
9. Check Industry Standards:
Some industries may have specific standards or recommendations for RFID frequency use. Verify if there are any applicable standards for your application.
10. Power Requirements:
Different frequencies may have different power requirements. Consider the power source available and choose a frequency that aligns with your power constraints.
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RFID, which stands for Radio Frequency Identification, represents a wireless communication method that harnesses electromagnetic or electrostatic coupling within the radio frequency segment of the electromagnetic spectrum. Its primary purpose is to provide a distinct means of identifying objects, animals, or individuals.
How does RFID work?
In every RFID setup, you've got three main parts: a scanning antenna, a transceiver, and a transponder. When you put the scanning antenna and transceiver together, they make what's called an RFID reader or interrogator. Now, there are two kinds of RFID readers - fixed ones and ones you can move around (mobile readers). The RFID reader is like a device that's connected to a network, and it can be either something you carry around or something fixed in place. It uses radio waves to send signals that wake up the RFID tag. Once the tag wakes up, it sends a signal back to the antenna, and this signal gets turned into data.
The transponder is basically inside the RFID tag itself. How far the RFID tags can be read depends on things like what type of tag it is, what kind of reader is being used, the RFID frequency, and if there's any interference around from other RFID tags or readers. Tags with a stronger power source can be read from a greater distance.
Fig:- Working Diagram of RFID
§What do RFID tags and smart labels refer to?
RFID tags are made up of an
integrated circuit (IC), an antenna and a substrate. The part of an RFID tag
that encodes identifying information is called the RFID inlay.
There are two main types of RFID tags:
Active RFID - An active RFID tag has its own power
source, often a battery.
Passive RFID - A passive RFID tag receives
its power from the reading antenna, whose electromagnetic wave induces a
current in the RFID tag's antenna.
There are also semi-passive
RFID tags, meaning a battery runs the circuitry while communication is powered
by the RFID reader.
Low-power, embedded
non-volatile memory plays an important role in every RFID system. RFID tags
typically hold less than 2,000 KB of data, including a unique identifier/serial
number. Tags can be read-only or read-write, where data can be added by the
reader or existing data overwritten.
The read range for RFID tags
varies based on factors including type of tag, type of reader, RFID frequency,
and interference in the surrounding environment or from other RFID tags and
readers. Active RFID tags have a longer read range than passive RFID tags due
to the stronger power source.
Smart labels are simple RFID
tags. These labels have an RFID tag embedded into an adhesive label and feature
a barcode. They can also be used by both RFID and barcode readers. Smart labels
can be printed on-demand using desktop printers, where RFID tags require more
advanced equipment.
RFID Tags
§What are the types of
RFID systems?
There are three main types of
RFID systems: low frequency (LF), high frequency (HF) and ultra-high frequency
(UHF). Microwave RFID is also available. Frequencies vary greatly by country
and region.
·Low-frequency
RFID systems. These range from 30 KHz to
500 KHz, though the typical frequency is 125 KHz. LF RFID has short
transmission ranges, generally anywhere from a few inches to less than six
feet.
·High-frequency
RFID system. These range from 3 MHz to
30 MHz, with the typical HF frequency being 13.56 MHz. The standard range is
anywhere from a few inches to several feet.
·UHF RFID
systems. These range from 300 MHz to 960 MHz, with the typical
frequency of 433 MHz and can generally be read from 25-plus feet away.
·Microwave
RFID systems. These run at 2.45 Ghzand can be read from 30-plus
feet away.
The frequency used will depend on the RFID application, with
actual obtained distances sometimes varying from what is expected. For example,
when the U.S. State Department announced it would issue electronic passports
enabled with an RFID chip, it said the chips would only be able to be read from
approximately 4 inches away. However, the State Department soon received
evidence that RFID readers could skim the information from the RFID tags from
much farther than 4 inches -- sometimes upward of 33 feet away.
RFID Frequiencies and Range
§RFID
applications and use cases
RFID dates
back to the 1940s; however, it was used more frequently in the 1970s. For a
long time, the high cost of the tags and readers prohibited widespread
commercial use. As hardware costs have decreased, RFID adoption has also
increased.
Some common uses for RFID applications
include:
·pet
and livestock tracking
·inventory
management
·asset
tracking and equipment tracking
·inventory
control
·cargo and supply
chain logistics
·vehicle
tracking
·customer
service and loss control
·improved
visibility and distribution in thesupply chain
·access
control in security situations
·shipping
·healthcare
·manufacturing
·retail
sales
·tap-and-go
credit card payments
Passive RFID tags do not require batteries. In this example
of passive RFID from Honeywell, battery-free tags in vehicles are used to
collect tolls on highways.
RFID Vs. Barcodes
Using
RFID as an alternative for barcodes is increasing in use. RFID and barcode technologies
are used in similar ways to track inventory, but there are some important
differences between them.
RFID tags
Barcodes
Can identify individual objects without direct line of sight.
Direct line of sight required for scanning.
Can scan items from inches to feet away, depending on type of
tag and reader.
Require closer proximity for scanning.
Data can be updated in real time.
Data is read-only and can't be changed.
Require a power source.
No power source needed.
Read time is less than 100 milliseconds per tag.
Read time is half a second or more per tag.
Contain a sensor attached to an antenna, often contained in a
plastic cover and more costly than barcodes.
Printed on the outside of an object and more subject to wear.
RFID vs. NFC
Near-field
communication (NFC) enables data to be exchanged between devices by using
short-range, high-frequency wireless communication technology. NFC combines the
interface of a smart card and reader into a single device.
Radio frequency ID
Near-field communication
Uni-directional
Bi-directional
Range up to 100 m
Range less than 0.2 m
LF/HF/UHF/Microwave
13.56 MHz
Continuous sampling
No continuous sampling
Bit rate varies with frequency
Up to 424 Kbps
Power rate varies with frequency
<15 milliamperes
RFID challenges
RFID is
prone to two main issues:
·Reader collision. Reader collision, when a signal from one RFID reader
interferes with a second reader, can be prevented by using an anti-collision
protocol to make RFID tags take turns transmitting to their appropriate reader.
·Tag collision.Tag collision occurs when too many tags
confuse an RFID reader by transmitting data at the same time. Choosing a reader
that gathers tag info one at a time will prevent this issue.
RFID security and privacy
A common
RFID security or privacy concern is that RFID tag data can be read by anyone
with a compatible reader. Tags can often be read after an item leaves a store
or supply chain. They can also be read without a user's knowledge using
unauthorized readers, and if a tag has a unique serial number, it can be
associated to a consumer. While a privacy concern for individuals, in military
or medical settings this can be a national security concern or life-or-death
matter.
Because
RFID tags do not have a lot of compute power, they are unable to accommodate
encryption, such as might be used in a challenge-response authentication
system. One exception to this, however, is specific to RFID tags used in
passports -- basic access control (BAC). Here, the chip has sufficient compute
power to decode an encrypted token from the reader, thus proving the validity
of the reader.
At the
reader, information printed on the passport is machine-scanned and used to
derive a key for the passport. There are three pieces of information used --
the passport number, the passport holder's birth date and the passport's
expiration date -- along with a checksum digit for each of the three.
Researchers
say this means passports are protected by a password with considerably less
entropy than is normally used in e-commerce. They key is also static for the
life of the passport, so once an entity has had one-time access to the printed
key information, the passport is readable with or without the consent of the
passport bearer until the passport expires.
