Spatial learning

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One of the major problems many animals must confront is how to find their way around their world—for example, to know where a particular resource is and how to get to it from their present location, or what is a safe route home to avoid a predator. Such spatial learning may cover only the highly restricted confines of an animal’s home range or territory, or it may embrace a migration route of several hundreds or even thousands of miles. Although some forms of navigational behaviour may be explicable in relatively simple terms, not necessarily requiring appeal to processes more complex than those of simple conditioning, others suggest some quite new principles.

Maze learning

In the psychologist’s laboratory, the primary method of studying spatial learning has been to put a rat in a maze and watch how it finds its way to the goal box, where it is fed. As befits the analytic (some would say sterile) approach so popular in experimental psychology, the elaborate and complex mazes used in earlier studies (the very first published experiment used a scaled-down replica of the maze at Hampton Court, London) soon gave way to something very much simpler, a T-maze or Y-maze. A rat placed at the end of one arm must run to the central choice-point, from where it has to enter one of the two remaining arms. Although extremely simple, even this apparatus allows for a number of possible modes of solution. One possibility is that the rat learns to execute a particular response, a left turn or a right turn, at the choice-point, because that response is followed by food. A second possible solution is that the rat learns that the two alternative arms differ in some particular way and further learns to associate one of the arms with food and hence to choose it. The third and most interesting possibility is that the rat learns to define the rewarded arm not in terms of its own intrinsic characteristics but by its spatial relationship to an array of landmarks outside the maze. Thus the rat might learn that the correct arm is the one pointing to the left of a window and away from a table with a lamp on it. Experiments show that whenever such landmarks are available, this third solution mode is the one used.

Perhaps the most convincing demonstration that rats can find their way to a particular location—one defined solely in terms of its spatial relation to various external landmarks—has been provided by experiments in which the animals are placed in a large circular tank of water and must swim to a transparent platform submerged somewhere in the middle of the tank. They can rapidly learn to do this, regardless of where they are initially put into the tank and even though the platform itself is invisible. (The invisibility of the platform is shown by the following: if the platform is moved, the rat will swim straight past it, heading instead toward the position it used to occupy.)

Rats in these experiments are not simply approaching a single landmark; they locate their goal by reference to its spatial relationship with a whole series of landmarks, no one of which is necessary. This can be established by using half a dozen arbitrary but easily identified objects as landmarks during maze training. Removal of any one or two of them in no way disrupts the rat’s behaviour. If all the landmarks are systematically rotated around the room, the rat will identify a new arm of the maze as correct (the one that has the same relationship to the landmarks as the initially correct arm). If, however, the landmarks are rearranged in such a way as to destroy their original spatial relationship to one another, the rat does not know which arm to choose.

The processes involved in this sort of learning are not well understood. Some psychologists have been sufficiently impressed by the rat’s flexibility in these experiments to argue that the animal is constructing a map of its environment—not, obviously, a written map but an internal, maplike representation that encodes a complete set of spatial relationships between major landmarks. The best evidence for such a maplike representation would be if a rat could take an unfamiliar route when its original route to a goal is blocked. Unfortunately, there is little evidence of such performance in rats, except in the not especially critical case where the goal, or a stimulus very close to it, is clearly visible from the choice-point. On the other hand, studies of long-range navigation have shown that some animals can do just this.