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Barcode Types
Introduction to commonly used barcode types and barcode sample pictures
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Barcodes are a method of
representing data in a visual, machine-readable form.
There are two main types of
barcodes: 1D Barcode (linear) and 2D
Barcode(matrix).
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Code 128 |
Full ASCII-Character set
with Code128 ABC autoselection |
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Code 128A |
Char Set A: Capital letters and
special characters |
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Code 128B |
Char Set B: Letters in upper and
lower case |
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Code 128C |
Char Set C: Optimized for
numbers |
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EAN 128 |
Special form of the Code 128
also known as UCC/EAN
128 |
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EAN 13 |
European-Article-Number
with 13 digits |
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EAN 8 |
European-Article-Number
with only 8 digits |
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EAN 5 |
Add on
price code for ISBN |
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EAN 2 |
Add on
found on newspapers |
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ISBN |
International
Standard Book Number |
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ISSN |
International
Standard Serial
Number |
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UPC A |
Universal
Product Code with
12 digits |
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UPC E |
Universal
Product Code with
6 digits |
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Code 39 |
Also known as Code 3 of 9.
Digits, uppercase letters
and _. *$/+% |
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Code 39 Extended |
Full ASCII-Character set. Also
known as Code 3 of 9
Extended. |
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Codebar |
Numeric code. Often used on
medical equipment. |
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Code 25 |
Numeric code. |
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Interleaved Code 25 |
Numeric code. Compact. |
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POSTNet |
Numeric code. Used by post
offices. |
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Post 2/5 |
Numeric code. Flavor of
Interleave 2of5. Also known as
Identcode or Leitcode. |
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Code93 |
Full ASCII-Character set. |
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Plessey |
Numeric and chars A to F. |
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PDF 417 |
2-Dimensional full ASCII
barcode. |
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Code11 |
Numbers and '-' . |
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PLANET |
Postal code |
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4State |
Postal code |
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ITF-14 |
The ITF-14 barcode is used to
create the Shipping Container
Symbol. This code is used to
mark cartons and palettes |
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EAN-14 |
EAN-128 derived
code used to mark trade goods. |
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DataMatrix |
2D
full ASCII barcode. |
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QR Code |
QR code (abbreviated from Quick
Response Code) is the trademark
for a type of matrix barcode (or
two-dimensional barcode) first
designed for the automotive
industry in Japan. A barcode is
a machine-readable optical label
that contains information about
the item to which it is
attached. A QR code uses four
standardized encoding modes
(numeric, alphanumeric,
byte/binary, and kanji) to
efficiently store data;
extensions may also be used. |
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IATA |
Used inaviation industry. |
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USPS Intelligent Mail |
US Postil Servide
Intelligent Mail
Barcode |
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FAQ: |
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1. What is the
difference between 1D barcode and 2D barcode?
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1D barcodes
consist of lines and spaces of varying widths that create
specific patterns.
Common examples
include:
UPC: Used
extensively in North America for retail items.
EAN: More common in
Europe and other parts of the world.
Code 39: Widely used
for many types of applications.
Code 128: Can encode
all ASCII characters and is excellent for many applications.
2D barcodes can
store more information than 1D barcodes by using patterns of
squares, dots, hexagons, and other geometric shapes. Examples
include:
QR Codes: Can encode
a significant amount of data and are used in a wide range of
applications.
Data Matrix: Often
used for marking small items, as it can encode a lot of
information in a small space.
PDF417: Used for
documents and postage. |
The choice between
1D and 2D barcodes depends on the amount of data you need to
encode and the space available on the item to be marked.
With the new GS1
Sunrise 2027 initiative, there’s a shift towards 2D barcodes
like QR codes and Data Matrix due to their increased data
storage capacity and improved scanning capabilities. |
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2. Why are there
so many barcode types?
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The diversity of
barcodes is to meet the needs of different industries and
application scenarios. Each barcode type has its own unique
features and benefits, such as:
EAN-13 code: a
globally accepted product barcode that supports 13 digits and is
suitable for retail.
UPC-A code: Product
barcode mainly used in the United States and Canada, supporting
12 digits.
Code-128 code: can
represent a total of 128 characters from ASCII 0 to ASCII 127,
suitable for a variety of applications.
Code-39 code:
supports numbers, uppercase letters and some special characters,
used for logistics tracking, etc.
ITF-14 code: used in
the storage, transportation and wholesale of goods, supporting
14 digits.
Different barcode
types can encode different types of information as needed, such
as numbers, letters, and even Chinese characters and images.
In addition, with
the development of technology, the functions of barcode software
continue to become more powerful, making the application of
barcodes more extensive and flexible.
In short, the
diversity of barcodes ensures that they can provide effective
automatic identification and tracking solutions for various
commercial and industrial processes worldwide. |
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3. Is it possible
that one type of barcode, such as QR Code, will replace all
other barcode types in the future?
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In the long term, QR
codes are likely to gradually replace one-dimensional barcodes.
According to GS1's "Sunrise 2027" project, starting in 2027,
two-dimensional barcodes similar to QR codes will replace the
standard 12-digit one-dimensional barcodes. This change is
designed to meet the changing needs for information
transparency, product certification and global supply chain
traceability.
However, this
transformation won't happen immediately. Although 2D barcodes
offer more information storage capacity and higher scanning
efficiency, 1D barcodes still play a role in many applications,
especially those where there is no need to store large amounts
of information or where there is a limit on the size of the
barcode. Additionally, the widespread deployment of existing 1D
barcode systems and devices means that a full transition to 2D
codes will take time and resources.
Therefore, while QR
codes may gradually become mainstream, in the short term, 1D
barcodes and QR codes may coexist, each exerting its advantages
in different application areas. |
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4. Will RFID replace
barcodes?
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RFID (Radio
Frequency Identification) technology and barcodes each have
their own advantages and application scenarios. RFID technology
can provide contactless identification, batch reading, larger
storage capacity, and greater durability and anti-interference
capabilities.
These
characteristics make RFID more advantageous than traditional
barcode systems in certain areas, such as supply chain
management, inventory tracking, and Internet of Things
applications.
However, barcode
technology still has certain advantages in terms of cost,
simplicity and popularity. The widespread deployment and mature
infrastructure of barcoding systems means they remain the first
choice across many industries and applications.
So while RFID
technology may be more advanced in some aspects, it won't
completely replace barcodes. Instead, the two are likely to
coexist, each bringing its strengths to bear in different
application areas.
Overall, RFID and
barcoding will continue to exist as complementary technologies,
working together to support the needs of modern business and
industry. |
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CONTACT |
autobaup@aol.com cs@easiersoft.com |
If you have any question, please
feel free to email us,
we will reply as soon as
possible. |
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D-U-N-S Number:
554420014 |
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