The abacus is one of the oldest calculating devices, used by ancient civilizations globally. This comprehensive guide will explain what an abacus is, how it works, its fascinating history, why it remains popular today, and how learning abacus calculation can improve your math skills!
What is an Abacus?
An abacus is a manual calculating tool used for adding, subtracting, multiplying, and dividing. It consists of a frame with rods strung with movable beads. Each rod represents a place value, with the rightmost rod representing the ones place. You can visualize numbers and calculate by manipulating the beads along the frame.
Abacuses typically have between 9 and 13 parallel rods. Each rod has two beads, separated by a bar. The bead above the bar has a value of 5, while the lower bead has a value of 1. By sliding the beads up and down, you can represent any number and perform arithmetic through a place value system.
A traditional Chinese abacus called a suanpan
How Does an Abacus Work?
Using an abacus relies on manipulating beads on rods to represent numbers and calculate results. Here‘s how it works:

Each rod represents a place value, with the rightmost rod representing the ones place. Rods to the left have higher place values of tens, hundreds, thousands, etc.

Beads above the separator bar have a value of 5. Beads below have a value of 1.

Pushing beads towards the center frame represents adding that value. Pulling them away represents subtracting.

You form numbers by pushing the appropriate number of beads on each rod to match the digit in that place value.

To add, simply push the beads representing the addend towards the frame.

To subtract, pull the beads representing the subtrahend away from the frame.

You can perform other operations like multiplication and division through repeated addition/subtraction.

The abacus minimizes errors by keeping all place values visually separated.

You can clearly see the numbers and results represented by the bead positions.
Overall, an abacus provides a straightforward way to calculate and teach arithmetic using visual and spatial representations. It was one of the first true calculating devices.
Adding 25 + 38 on an abacus
History and Origins of the Abacus
The exact origin of the abacus is unknown, but bead calculating devices emerged independently across many ancient civilizations. Both the Roman Empire and Ancient Greece used abacuses, but evidence dates back thousands of years earlier to Mesopotamia and Egypt. However, China and Japan have the longest history of consistent abacus use and development.
Mesopotamia – The earliest archaeological evidence of a counting board device dates back to 2700–2300 BCE from the Sumerian civilization in ancient Mesopotamia. These early abacuses paved the way for the development of the Roman abacus many centuries later.
Egypt – Ancient Egyptians used a primitive device involving a slab of stone covered with sand for making calculations as early as the 2nd millennium BCE. This marked an early step towards the abacus.
China – The earliest known Chinese abacus dates back to the 2nd century BCE, based on archaeological finds. These early Chinese abacuses had 2 beads per rod. Over the following centuries, the abacus evolved into a 2:5 type with 5 beads above and 2 below the bar. This flexible system allowed representation of decimal numbers. Chinese abacuses were often called suanpans.
Japan – Japanese abacuses called sorobans likely came from China in the 14th century CE. However, by the 17th century, Japan modified the abacus into its own unique 1:4 type with 1 bead above and 4 below the bar. Sorobans remain very popular in Japan today.
Russia – Russia adopted the abacus in the form of schoty around the 13th century CE. Russian abacuses were typically a 1:4 system.
Europe – Roman and Greek abacuses date from around the 4th century BCE. Early European abacuses used grooved channels and stones instead of beads. Europeans later adopted more efficient beadandrod abacuses.
So while the exact origin is uncertain, abacuses developed across Eurasia over thousands of years as an efficient calculation tool. From Greece and Rome to Russia, China, and Japan, abacus design and precision evolved.
Types of Abacuses
There are various types of abacuses used throughout history, differing primarily in the number of beads per rod:

Chinese/Asian Abacus – Also called a suanpan, these typically have 2 beads above and 5 below the bar in a 2:5 configuration, allowing decimal representation.

Japanese Soroban – The soroban is a 1:4 abacus with 1 bead above and 4 below the bar. Sorobans are compact and efficient.

Russian Schoty – Russian abacuses were also 1:4 types like the soroban.

Roman Abacus – Early Roman abacuses used grooved channels with stones instead of beads on rods.

Cranmer Abacus – The Cranmer abacus is a modern 13rod device modified from the soroban for use by blind students.

Hexadecimal Abacus – Some abacuses use hexadecimal numbering with 16 beads per rod instead of 10.
While the 2:5 and 1:4 systems have proven most popular, many variations exist with different benefits. However, all abacus types rely on the same place value system.
Abacus Calculation Methods
Experienced abacus users can perform calculations remarkably fast. Research shows practicing with an abacus improves math skills in several key ways:

VisualSpatial Mapping – Arranging beads spatially maps numbers visually in the mind.

Mental Math – Abacus math relies on mental manipulation versus writing, improving working memory.

Number Sense – The tactile reinforcement of place value develops intuitive number sense.

Speed – Faster mental math speed is achieved through abacus practice. Experts add and subtract quickly.

Focus – The abacus limits displayed calculations, encouraging focus on one computation at a time.
Together, these benefits make abacus calculation faster, more intuitive, and less prone to careless errors. Using both sides of the brain builds excellent math skills.
Abacus calculation takes practice but follows clear steps:

Understand the place values – each rod is a place value, with the rightmost rod the ones place.

Clear the abacus – start with all beads pushed to the bottom.

Set the addend – push beads on each rod to match the addend number.

Set the summand – push beads to represent the number you are adding.

Combine the results – mentally add bead values on each rod.

Read the result – the final bead position on each rod gives the sum.
Here is an example of adding 25 + 38 on an abacus:

Clear the abacus so every bead is at the bottom

Set the addend (25) – push 2 beads on the tens rod and 5 beads on the ones rod

Set the summand (38) – push 3 beads on the tens rod and 8 beads on the ones rod

Combine the results – there are 5 beads on the tens rod and 3 beads on the ones rod

Read the result – 53
Subtraction, multiplication, and division follow similar logic. With practice, abacus calculation becomes quick and intuitive!
Culture of the Abacus in Asia
Despite digital calculators, the abacus remains culturally significant and regularly used in parts of Asia today:

In Japan, around 1.75 million elementary school students learned the soroban abacus as recently as 1970.

Japanese abacus champions can perform addition in as little as 1.7 seconds and multiplication in under 3 seconds!

Abacus clubs exist at many Asian schools, especially in Japan, Korea, Taiwan, and China.

Japan alone has around 5 million active abacus users today.

Competitions test mental abacus skills, with champions demonstrating calculation speeds of nearly 13,000 calculations per hour!

Top Abacus Masters can add up to 27 numbers with a combined total of 10 digits in under 5 seconds.

The All Japan Soroban Association holds large national competitions to find the fastest abacus users.

Champion abacus users are called sorobanists in Japan after the soroban abacus.
So in many Asian countries, the abacus remains a point of cultural pride and mathematical skill. Abacus mastery is a high honor.
Why the Abacus Still Matters
While less universally used today, the abacus remains historically significant and educationally useful:

As one of the earliest mathematical tools, it paved the way for later calculating devices.

It continues to teach place value, manual dexterity, and visualspatial skills.

Using an abacus boosts math skills like mental math, even for those adept with computers.

Blind students utilize Cranmer abacuses as an educational tactile tool.

The abacus binary system relates to binary numbers in modern computing.

Abacus calculation engages both sides of the brain through visualspatial and kinesthetic learning.

Champion abacus users demonstrate incredible feats of mental math and memory.
So this ancient calculating device continues to build valuable skills relevant today. While less common in most of the world, it remains ingrained in Asian culture.
The Future of the Abacus
Looking forward, the abacus may find new popularity as a visualtactile teaching tool. Recent studies show using an abacus enhances math skills and mental math ability even in children already comfortable with computers.
As topperforming Asian education systems like Japan have demonstrated, the abacus can play an expanded role globally as a learning device. Digital devices need not replace manipulative tools like the abacus that build mathematical thinking.
Ultimately, while not as universal today, the abacus transformed mathematical understanding and paved the way for computing. This ancient calculating tool remains a powerful representation of number relationships that continues to intellectually engage users around the world today.