Traditional AI programs lack the versatility and adaptability of human intelligence. For example, they cannot come into a new home and cook, clean and do laundry.

In artificial general intelligence (AGI), which is a new field within AI, scientists try to create computer programs with a generalised type of intelligence, enabling them to solve problems in vastly different areas.

No Pre-Existing Knowledge

‘We have developed a program that can learn for example basic arithmetic, logic and grammar without any pre-existing knowledge,’ says Claes Strannegård, a member of the research team together with Abdul Rahim Nizamani and Ulf Persson.

The best example of general intelligence that we know of today is the human brain, and the scientists’ strategy has been to imitate, at a very fundamental level, how children develop intelligence. Children can learn a wide range of things. They build new knowledge based on previous knowledge and they can use their total knowledge to draw new conclusions. This is exactly what the scientists wanted their programme to be able to do.

Children Learn Based on Experience

‘We postulate that children learn everything based on experiences and that they are always looking for general patterns,’ says Strannegård.

A child who for example is learning multiplication and who knows that 2 x 0 = 0 and 3 x 0 = 0 can identify a pattern and conclude that also 17 x 0 = 0. However, sometimes this method backfires. If the child knows that 0 x 0 = 0 and 1 x 1 = 1, he or she can incorrectly conclude that 2 x 2 = 2. As soon as the child realizes that a certain pattern can lead to incorrect conclusions, he or she can simply stop applying it.

Identify Patterns

The child can in this way create a large number of patterns not only in mathematics but also in other areas such as logic and grammar. The patterns in a certain area can then be combined with each other and make it possible to solve entirely new problems. The program developed by the Gothenburg scientists works in a similar manner. It can identify patterns by itself and therefore differs from programmes where a programmer has to formulate which rules the programme should apply.

‘We are hoping that this type of program will eventually be useful in several different practical applications. Personally, I think a versatile household robot would be tremendously valuable, but we’re not there yet,’ says Strannegård.

The research team included Claes Strannegård, Associate Professor at the Department of Philosophy, Linguistics and Theory of Science, University of Gothenburg, and at the Department of Applied Information Technology, Chalmers University of Technology.