Honeybees join humans as the only known animals that can tell the difference between odd and even numbers

Honeybees join humans as the only known animals that can tell the difference between odd and even numbers

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“Two, four, six, eight; bog in, don’t wait”.

As children, we learn numbers can either be even or odd. And there are many ways to categorise numbers as even or odd.

We may memorise the rule that numbers ending in 1, 3, 5, 7, or 9 are odd while numbers ending in 0, 2, 4, 6, or 8 are even. Or we may divide a number by 2 – where any whole number outcome means the number is even, otherwise it must be odd.

Similarly, when dealing with real-world objects we can use pairing. If we have an unpaired element left over, that means the number of objects was odd.

Until now odd and even categorisation, also called parity classification, had never been shown in non-human animals. In a new study, published today in the journal Frontiers in Ecology and Evolution, we show honeybees can learn to do this.

Why is parity categorisation special?

Parity tasks (such as odd and even categorisation) are considered abstract and high-level numerical concepts in humans.

Interestingly, humans demonstrate accuracy, speed, language and spatial relationship biases when categorising numbers as odd or even. For example, we tend to respond faster to even numbers with actions performed by our right hand, and to odd numbers with actions performed by our left hand.

We are also faster, and more accurate, when categorising numbers as even compared to odd. And research has found children typically associate the word “even” with “right” and “odd” with “left”.

These studies suggest humans may have learnt biases and/or innate biases regarding odd and even numbers, which may have arisen either through evolution, cultural transmission, or a combination of both.

It isn’t obvious why parity might be important beyond its use in mathematics, so the origins of these biases remain unclear. Understanding if and how other animals can recognise (or can learn to recognise) odd and even numbers could tell us more about our own history with parity.

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Training bees to learn odd and even

Studies have shown honeybees can learn to order quantities, perform simple addition and subtraction, match symbols with quantities and relate size and number concepts.


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To teach bees a parity task, we separated individuals into two groups. One was trained to associate even numbers with sugar water and odd numbers with a bitter-tasting liquid (quinine). The other group was trained to associate odd numbers with sugar water, and even numbers with quinine.

Image shows a schematic of a honeybee being shown an array of odd vs. even quantities on a circular screen in three different trials.

Here we show a honeybee being trained to associate ‘even’ stimuli with a reward over 40 training choices.
Scarlett Howard

We trained individual bees using comparisons of odd versus even numbers (with cards presenting 1-10 printed shapes) until they chose the correct answer with 80% accuracy.

Remarkably, the respective groups learnt at different rates. The bees trained to associate odd numbers with sugar water learnt quicker. Their learning bias towards odd numbers was the opposite of humans, who categorise even numbers more quickly.

Honeybee standing on a grey plexiglass paltform ridge drinking a clear liquid (sugar water).

Honeybees landed on a platform to drink sugar water during the experiment.
Scarlett Howard

We then tested each bee on new numbers not shown during the training. Impressively, they categorised the new numbers of 11 or 12 elements as odd or even with an accuracy of about 70%.

Our results showed the miniature brains of honeybees were able to understand the concepts of odd and even. So a large and complex human brain consisting of 86 billion neurons, and a miniature insect brain with about 960,000 neurons, could both categorise numbers by parity.

Does this mean the parity task was less complex than we’d previously thought? To find the answer, we turned to bio-inspired technology.

We trained honeybees to choose even numbers. In this video we see the bee inspect each card on the screen, before making a correct choice on the card presenting an even number of 12 shapes.

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Creating a simple artificial neural network

Artificial neural networks were one of the first learning algorithms developed for machine learning. Inspired by biological neurons, these networks are scalable and can tackle complex recognition and classification tasks using propositional logic.

We constructed a simple artificial neural network with just five neurons to perform a parity test. We gave the network signals between 0 and 40 pulses, which it classified as either odd or even. Despite its simplicity, the neural network correctly categorised the pulse numbers as odd or even with 100% accuracy.

This showed us that in principle parity categorisation does not require a large and complex brain such as a human’s. However, this doesn’t necessarily mean the bees and the simple neural network used the same mechanism to solve the task.

Simple or complex?

We don’t yet know how the bees were able to perform the parity task. Explanations may include simple or complex processes. For example, the bees may have:

paired elements to find an unpaired element

performed division calculations – although division has not been previously demonstrated by bees

counted each element and then applied the odd/even categorisation rule to the total quantity.

By teaching other animal species to discriminate between odd and even numbers, and perform other abstract mathematics, we can learn more about how maths and abstract thought emerged in humans.

Is discovering maths an inevitable consequence of intelligence? Or is maths somehow linked to the human brain? Are the differences between humans and other animals less than we previously thought? Perhaps we can glean these intellectual insights, if only we listen properly.


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The Conversation

Scarlett Howard received funding from Australian Government Research Training Program (RTP) Scholarship, RMIT University, Fyssen Foundation, L’Oreal-UNESCO for Women in Science Young Talents French Award, and Deakin University. She is affiliated with Pint of Science Australia as the Media Manager volunteer.

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Adrian Dyer receives funding from Australian Research Council

Andrew Greentree receives funding from The Australian Research Council, Defence Science and Technology Group, SmartSat CRC, The US Air Force Office of Scientific Research, The Asian Office of Aerospace Research and Development, The US Office of Naval Research, and the Foundation for Australia-Japan Studies.

Jair Garcia does not work for, consult, own shares in or receive funding from any company or organisation that would benefit from this article, and has disclosed no relevant affiliations beyond their academic appointment.