Abstract
The ability to orientate and navigate is critically important for the survival of all migratory birds and other animals. Progress in understanding the mechanisms underlying these capabilities and, in particular, the importance of sensitivity to the Earth’s magnetic field has, thus far, been constrained by the limited number of techniques available for the analysis of often complex behavioral responses. Methods used to track the movements of animals, such as birds, have varied depending on the degree of accuracy required. Most conventional approaches involve the use of a camera for recording and then measuring an animal’s head movements in response to a variety of external stimuli, such as changes in magnetic fields. However, video tracking analysis (VTA) will generally provide only a 2D tracking of head angle. Moreover, such a video analysis can only provide information about movements when the head is in view of the camera. In order to overcome these limitations, the novel invention reported here utilizes a lightweight ( $20.3\times 12.7\times 3$ mm) system can be programmed and calibrated to provide measurements of the three rotational angles (roll, pitch, and yaw) simultaneously, eliminating any drift, i.e., the movement of the pigeon’s head is determined by detecting and estimating the directions of motion at all angles (even those outside the defined areas of tracking). Using an existing VTA approach as a baseline for comparison, it is demonstrated that the IMU technology can comprehensively track a pigeon’s normal head movements with greater precision and in all three axes.
Highlights
T HE ability of birds to migrate accurately over large distances is, in part, due to their capacity to use the Earth’s magnetic field for orientation
We have developed a novel method that is based on the use of an inertial measurement unit (IMU) with 9 degrees of freedom (DOF), i.e. a triple axis gyroscope (G) measuring angular velocities around Gx, Gy, and Gz; a triple axis accelerometer (A) measuring acceleration along Ax, Ay, Az; and a triple axis magnetometer (M) measuring magnetic field along Mx, My and Mz, all of which are required for the IMU unit to be able to detect and measure the orientation of the pigeon’s head in 3D space
The present study describes the novelty of using inertial measurement technology to detect behavioral responses in pigeons
Summary
T HE ability of birds to migrate accurately over large distances is, in part, due to their capacity to use the Earth’s magnetic field for orientation. An example of one such response is the optocollic reflex (OCR), a sequence of head movements often observed in birds that is analogous to the optokinetic eye movements seen in humans when viewing the world through the window of a moving train. This response in birds comprises an alternation between a ‘slow’ phase following head movement and a ‘quick’ saccadic reset head movement. Just as is possible in the study of human eye movements, the intricate dynamics of bird head movements can be used to investigate many aspects of their natural perceptual capabilities These might include their ability to discriminate different wavelengths of light, motion, different levels of contrast, and changes in magnetic flux (i.e. magnetoreception). Such studies are useful in understanding the many visual adaptations evident in birds, which have continued implications for human technological advancements (biomimicry), such as the development of advanced optical systems for use in drones [4]
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