Western philosophy has traditionally separated mind from matter and brain from body. In recent years, however, cognitive scientists have turned the assumption on its head that we can study the mind based on the brain alone.
Many now view the brain as part of a larger “mind” – a cognitive system embodied in the organism’s physical structure and embedded in its surrounding environment. These twin concepts of embodied and embedded cognition are challenging the way we understand human intelligence, and in the process transforming neuroscience, robotics, philosophy, and a host of other fields concerned with the mind.
When we think of intelligence, we often focus on skills specific to humans, such as mathematical reasoning and critical thinking. But the ability of animals (including humans) to navigate their environment and process sensory information is an equally impressive feat – one that has in many ways proven harder to understand and replicate than more intellectual endeavors such as playing chess.
Tackling these more basic abilities has required cognitive scientists to rethink their assumptions about how organisms engage in movement and behavior. Walking, for example, is not a matter of the brain computing all the positions a leg must pass through and then giving the command to take the next step forward. It requires exquisite timing across the entire organism, as nerves and muscles coordinate to exploit the physical properties of legs that function as pendulums.
The brains of more advanced organisms have evolved over time to exert precise control over such motions, but this ability is still built on a foundation of information and feedback from across the body.1 The brain exploits large quantities of information continuously streaming through the senses.(a) It took millions of years of evolution to get to the point where a bipedal organism could coordinate its vision, its sense of balance, and its sense of bodily position so that it only rarely fell over when chasing dinner.
Exploitation of the physical properties of bodies and environments is an important way in which animals reduce the computational load on the nervous system. An animal’s nervous system does not have to compute or represent exact positions and speeds for its legs before initiating an action, but can rely on the fact that the physics of the swinging leg can provide the sensory feedback needed to make small motor corrections on the fly.
In a similar way, crickets use information from unique bodily structures to facilitate hearing. Biorobotics professor Barbara Webb and her colleagues have shown how the physical transmission of sound through tracheal tubes in a cricket’s body simplifies the task of orienting toward a sound source.2 Sound waves entering through different portals in the tracheal tubes will be amplified or cancelled depending on the location of the sound source. Without this physical system, the cricket’s neurons would have to determine direction using only the small timing differences of sound waves reaching the eardrums on different sides of the head.
The embodied nature of cognition applies not only to basic animal activities like walking and hearing, but also to higher-level capacities of human intelligence. Findings about how the physical environment can affect thought offer a fascinating look at this phenomenon. Recent studies3 have shown the impact of wearing a white coat on decision making and the effect of holding a heavier clipboard on rating the “weight” of certain decisions.(b)
Intriguing as such studies may be, they focus on only one direction of the mind-body loop: how physical conditions (i.e. what you wear or what you are holding) have an effect on human thought and behavior. More significant for understanding the physically embodied and embedded nature of cognition are the various ways in which cognitive problems are offloaded onto physical processes, making two-way bodily interactions with the environment essential to cognitive success.
An early example of this kind of research was the finding that experienced Tetris players don’t just imagine the shapes rotating and fitting into the available space, but they actually rotate the images on the screen as part of the process of figuring out where they should go, and they solve the problems more quickly and efficiently by doing so.4 Cognition is also facilitated by directing attention around one’s spatial environment. Studies of eye movements show that cognitive success is partly due to learning complex gaze patterns governing when and where to focus visual attention, such as where to look on a counter full of ingredients when cooking, so as to obtain information “just in time.”5
Similarly, scientists are slowly beginning to understand how teachers and learners rely on gestures to scaffold their understanding of arithmetic and algebra. Children begin to learn math by counting and manipulating objects and observing how quantities change when objects are added or taken away. More experienced mathematical reasoners exploit the physical characteristics of symbolic notation systems to simplify problems in ways not explicitly taught. For example, when adding or subtracting a value on both sides of an algebra equation so that it disappears on one side and appears on the other, we may imagine physically moving the number across the equal sign.
These findings show the limitations of the classical separation between the inner mental world and outer physical world. In this traditional view, the inner representations accessible to the human mind are only weakly connected to the physical world through fallible senses.(c) The latest developments in cognitive science are demonstrating that the mind is not so decoupled from the world it seeks to understand and that brain, physical body, and environment work in tandem to produce thought.
In my next article, I will explore how this growing understanding of the embodied nature of cognition is influencing the quest to develop artificial intelligence.
This article is part of a series on robots and their impact on society.