Target-directed Orientation in Displaced Honeybees

Under sunny weather conditions, displaced honeybees (Apis mellifera) usually fly into the celestial compass direction and thus may be misled from their goal, or they are disorientated. Under cloudy conditions, they may determine the celestial compass direction from prominent landmarks. They may also fly directly toward their goal from a release site. In two experiments, we investigated the orientation of displaced bees when a landmark (target) was close to the goal under different weather conditions. It is shown that in sunny conditions, the celestial compass will override target orientation under most conditions. Under 100% cloud cover, the celestial compass direction retrieved from landmarks modulates target-orientated behaviour but is not by itself a primary orientation factor. The bees will fly toward a previously encountered landmark that signals the target, and in case of several similar landmarks which are visible to the bees, they will choose the one in the direction nearest the celestial compass direction. The results indicate that honeybee orientation is the result of a set of context-specific interdependent orientation mechanisms.     

Dung beetles ignore landmarks for straight-line orientation

Upon locating a suitable dung pile, ball-rolling dung beetles shape a piece of dung into a ball and roll it away in a straight line. This guarantees that they will not return to the dung pile, where they risk having their ball stolen by other beetles. Dung beetles are known to use celestial compass cues such as the sun, the moon and the pattern of polarised light formed around these light sources to roll their balls of dung along straight paths. Here, we investigate whether terrestrial landmarks have any influence on straight-line orientation in dung beetles. We find that the removal or re-arrangement of landmarks has no effect on the beetle’s orientation precision. Celestial compass cues dominate straight-line orientation in dung beetles so strongly that, under heavily overcast conditions or when prevented from seeing the sky, the beetles can no longer orient along straight paths. To our knowledge, this is the only animal with a visual compass system that ignores the extra orientation precision that landmarks can offer.     

Multiple sources of celestial compass information in the Central Australian desert ant Melophorus bagoti

The Central Australian desert ant Melophorus bagoti is known to use celestial cues for compass orientation. We manipulated the available celestial cues for compass orientation for ants that had arrived at a feeder, were captured and then released at a distant test site that had no useful terrestrial panoramic cues. When tested in an enclosed transparent box that blocked some or most of the ultraviolet light, the ants were still well oriented homewards. The ants were again significantly oriented homewards when most of the ultraviolet light as well as the sun was blocked, or when the box was covered with tracing paper that eliminated the pattern of polarised light, although in the latter case, their headings were more scattered than in control (full-cue) conditions. When the position of the sun was reflected 180° by a mirror, the ants headed off in an intermediate direction between the dictates of the sun and the dictates of unrotated cues. We conclude that M. bagoti uses all available celestial compass cues, including the pattern of polarised light, the position of the sun, and spectral and intensity gradients. They average multiple cues in a weighted fashion when these cues conflict.     

Orientation and navigation in Amphibia

Aquatic and terrestrial amphibians integrate acoustic, magnetic, mechanical, olfactory and visual directional information into a redundant-multisensory orientation system. The sensory information is processed to accomplish homing following active or passive displacement by either path integration, beaconing, pilotage, compass orientation or true navigation. There is evidence for two independent compass systems, a time-compensated compass based on celestial cues and a light-dependent magnetic inclination compass. Beaconing along acoustic or olfactory gradients emanating from the home site, as well as pilotage along fixed visual landmarks also form an important part in the behaviour of many species. True navigation has been shown in only one species, the aquatic salamander Notophthalmus viridescens. Evidence on the nature of the navigational map obtained so far is compatible with the magnetic map hypothesis.     

Adaptive Visually-Directed Orientation in Uca pugilator

Sand fiddler crabs are ill-equipped to inhabit either the terrestrialor permanently submerged littoral zones. They are obligate inhabitantsof the intertidal region in which, at any point, extremes ofconditions continually fluctuate. The crabs must constantlymove about to specific areas in order to carry out life-supportingprocesses while avoiding detrimental physical conditons. Forthis reason, directional orientation is basic to their existence. The typical activities of adult sand fiddlers during diurnallow tides have charateristic directional components. Some directedmovements have immediate survival value under conditions ofstress, such as the approach of a predator. For example, crabson the lower beach (well away from their burrow area) oftenrun landward and enter burrows or vegetation, thereby obtainingrefuge. Those which are chased offshore or inland are able toreorient to the beach. Experiments conducted both in the field and under controlledconditions indicate that these adaptive oriented movements areguided primarily by visual mechanisms. Adult crabs exhibit atime-compensated, menotactic orientation to the sun and polarizedsky-light that enables them to maintain a heading coincidentwith the landward compass bearing of their particular shoreline.New directional preferences can be induced by holding crabsin simulated habitats with specific shore-water spatial configurations. The crabs also exhibit a telotaxis toward gross landmarks, suchas mangroves or clumps of beach grass, that stand in opticalcontrast to the background. This orientation occurs in mostindividuals if celestial cues are obscured or if the animalsbecome desiccated. Upon reaching the object, crabs enter suitableinterstices affording refuge. Since they can orient by eithercelestial cues or landmarks, or both, there are probably fewtimes in nature when they are disoriented from lack of guidance-stimuli.     

The role of the sun in the celestial compass of dung beetles

Recent research has focused on the different types of compass cues available to ball-rolling beetles for orientation, but little is known about the relative precision of each of these cues and how they interact. In this study, we find that the absolute orientation error of the celestial compass of the day-active dung beetle Scarabaeus lamarcki doubles from 16° at solar elevations below 60° to an error of 29° at solar elevations above 75°. As ball-rolling dung beetles rely solely on celestial compass cues for their orientation, these insects experience a large decrease in orientation precision towards the middle of the day. We also find that in the compass system of dung beetles, the solar cues and the skylight cues are used together and share the control of orientation behaviour. Finally, we demonstrate that the relative influence of the azimuthal position of the sun for straight-line orientation decreases as the sun draws closer to the horizon. In conclusion, ball-rolling dung beetles possess a dynamic celestial compass system in which the orientation precision and the relative influence of the solar compass cues change over the course of the day.     

Central neural coding of sky polarization in insects

Many animals rely on a sun compass for spatial orientation and long-range navigation. In addition to the Sun, insects also exploit the polarization pattern and chromatic gradient of the sky for estimating navigational directions. Analysis of polarization-vision pathways in locusts and crickets has shed first light on brain areas involved in sky compass orientation. Detection of sky polarization relies on specialized photoreceptor cells in a small dorsal rim area of the compound eye. Brain areas involved in polarization processing include parts of the lamina, medulla and lobula of the optic lobe and, in the central brain, the anterior optic tubercle, the lateral accessory lobe and the central complex. In the optic lobe, polarization sensitivity and contrast are enhanced through convergence and opponency. In the anterior optic tubercle, polarized-light signals are integrated with information on the chromatic contrast of the sky. Tubercle neurons combine responses to the UV/green contrast and e-vector orientation of the sky and compensate for diurnal changes of the celestial polarization pattern associated with changes in solar elevation. In the central complex, a topographic representation of e-vector tunings underlies the columnar organization and suggests that this brain area serves as an internal compass coding for spatial directions.     

Memory and sun compensation by honey bees

Summary Experiments with two species of honey bees (Apis mellifera andA. cerana) have revealed that bees form a detailed memory of the spatial and temporal pattern of the sun's azimuthal movement, using local landmarks as a reference for the learning. These experiments were performed on overcast days, and consisted of removing a hive from one site in which bees had been trained to find food by flying along a prominent landmark, and displacing it to a similar site in which the landmark was aligned in a different compass direction. On overcast days, bees which flew along the landmark in the new site oriented their waggle dances in the hive as if they had actually flown in the training site. Thus, they confused the two sets of landmarks and set their dance angles according to a memory of the sun's position relative to the original landmarks. Furthermore, the dances changed in correspondence with the sun's azimuthal shift over several hours, even reflecting (approximately) the regular temporal variations in the rate of shift; such features of the sun's course must therefore be stored in memory. The primary mechanism underlying the learning of this pattern is probably similar to that proposed by New and New (1962): bees store in memory several time-linked solar azimuthal positions relative to features of the landscape, and refer to this stored array when they need to determine an unknown azimuth intermediate between two known positions.During the cloudy-day displacement experiments, celestial cues often appeared to bees in the new site, contradicting the stored information on which they had been basing their dances. Although most bees quickly adopted the dance angle reflecting their actual direction of flight relative to the sun, some later reverted to the original dance angle, indicating that the information on which it was based had remained in memory when the new information was being expressed; other bees performed bimodal dances which expressed both sets of information in alternate waggle runs. The separation in memory implied by these behaviors may reflect a neural strategy for updating a previously stored relationship between celestial and terrestrial references with new information presented by seasonal changes in the sun's course or by newly learned landmarks.     

Learning and time‐dependent cue choice in the desert ant,Melophorus bagoti

Foraging ants are known to use multiple sources of information to return to the nest. These cue sets are employed by independent navigational systems including path integration in the case of celestial cues and vision‐based learning in the case of terrestrial landmarks and the panorama. When cue sets are presented in conflict, the Australian desert ant species, Melophorus bagoti, will choose a compromise heading between the directions dictated by the cues or, when navigating on well‐known routes, foragers choose the direction indicated by the terrestrial cues of the panorama against the dictates of celestial cues. Here, we explore the roles of learning terrestrial cues and delays since cue exposure in these navigational decisions by testing restricted foragers with differing levels of terrestrial cue experience with the maximum (180°) cue conflict. Restricted foragers appear unable to extrapolate landmark information from the nest to a displacement site 8 m away. Given only one homeward experience, foragers can successfully orient using terrestrial cues, but this experience is not sufficient to override a conflicting vector. Terrestrial cue strength increases with multiple experiences and eventually overrides the celestial cues. This appears to be a dynamic choice as foragers discount the reliability of the terrestrial cues over time, reverting back to preferring the celestial vector when the forager has an immediate vector, but the forager's last exposure to the terrestrial cues was 24 hr in the past. Foragers may be employing navigational decision making that can be predicted by the temporal weighting rule.     

Changes in the short-term deflector loft effect are linked to the sun compass of homing pigeons

Despite being the most studied of all avian orientation systems, important questions still remain about the sun compass of homing pigeons, Columba livia. White it is well-documented that the sun compass is usually learned by young pigeons during the first 10–12 weeks of life, the mechanism by which it is calibrated to adjust for seasonal changes in the sun's azimuth is not known with certainty. Previous experiments using short-term deflector loft pigeons indicated that the sun compass may be calibrated by referencing celestial polarization patterns. The present paper describes important measurable changes in the previously reported orientation behaviour of short-term deflector loft birds, and suggests a correlation between these changes and the presence of a massive upper-atmospheric dust cloud of volcanic origin which significantly altered natural skylight polarization patterns in 1982 and 1983. Moreover, it is shown that when the short-term effect was absent (at times when data from previous years suggested it should be present), the birds were also not using sun compass orientation, as demonstrated by their failure to show the standard ‘clockshift’ response to a 6-h fast shift of their internal clocks. These results support the hypothesis that reflected light cues, rather than odours, are the basis of the deflector loft effect in pigeon homing.     

Orientation in a desert lizard (Uma notata): time-compensated compass movement and polarotaxis

Summary The diurnal escape response of fringetoed lizards (Uma notata) startled by predators demonstrates clear directional orientation not likely to depend on local landmarks in the shifting sands of their desert environment. Evidence that celestial orientation is involved in this behavior has been sought in the present experiments by testing the effects of (1) phase shifting the animal's internal clock by 6 h and (2) by training the lizards to seek shelter while exposed to natural polarization patterns. In the first case, 90° shifts in escape direction were demonstrated in outdoor tests, as expected if a time-compensated sun or sky polarized light compass is involved. In the second instance, significant bimodale-vector dependent orientation was found under an overhead polarizing light filter but this was only evident when the response data were transposed to match the zenithe-vector rotation dependent on the sun's apparent movement through the sky. This extends to reptiles the capacity to utilize overheade-vector directions as a time-compensated sky compass. The sensory site of this discrimination and the relative roles of sun and sky polarization in nature remain to be discovered.     

Integration of polarization and chromatic cues in the insect sky compass

Animals relying on a celestial compass for spatial orientation may use the position of the sun, the chromatic or intensity gradient of the sky, the polarization pattern of the sky, or a combination of these cues as compass signals. Behavioral experiments in bees and ants, indeed, showed that direct sunlight and sky polarization play a role in sky compass orientation, but the relative importance of these cues are species-specific. Intracellular recordings from polarization-sensitive interneurons in the desert locust and monarch butterfly suggest that inputs from different eye regions, including polarized-light input through the dorsal rim area of the eye and chromatic/intensity gradient input from the main eye, are combined at the level of the medulla to create a robust compass signal. Conflicting input from the polarization and chromatic/intensity channel, resulting from eccentric receptive fields, is eliminated at the level of the anterior optic tubercle and central complex through internal compensation for changing solar elevations, which requires input from a circadian clock. Across several species, the central complex likely serves as an internal sky compass, combining E-vector information with other celestial cues. Descending neurons, likewise, respond both to zenithal polarization and to unpolarized cues in an azimuth-dependent way.     

Interactions of the polarization and the sun compass in path integration of desert ants

Desert ants, Cataglyphis fortis, perform large-scale foraging trips in their featureless habitat using path integration as their main navigation tool. To determine their walking direction they use primarily celestial cues, the sky’s polarization pattern and the sun position. To examine the relative importance of these two celestial cues, we performed cue conflict experiments. We manipulated the polarization pattern experienced by the ants during their outbound foraging excursions, reducing it to a single electric field (e-)vector direction with a linear polarization filter. The simultaneous view of the sun created situations in which the directional information of the sun and the polarization compass disagreed. The heading directions of the homebound runs recorded on a test field with full view of the natural sky demonstrate that none of both compasses completely dominated over the other. Rather the ants seemed to compute an intermediate homing direction to which both compass systems contributed roughly equally. Direct sunlight and polarized light are detected in different regions of the ant’s compound eye, suggesting two separate pathways for obtaining directional information. In the experimental paradigm applied here, these two pathways seem to feed into the path integrator with similar weights.     

Honeybees Use Celestial and/or Terrestrial Compass Cues for Inter‐Patch Navigation

Foraging honeybees (Apis mellifera) are well known to fly straight from the hive, their primary hub, to distal goals as well as between familiar feeding sites. More recently, it was shown that a distal feeding site may be used as a secondary hub. If not fully satiated, the foraging bee may decide to depart the first feeding site in a new compass direction straight to one of many other feeding sites (inter‐patch foraging). Using a recently developed recording method, we discovered that the chosen departure direction at a secondary hub can be guided exclusively by either celestial or terrestrial compass cues. Given our data, we draw two theoretical inferences. First, the bees must be capable of learning and remembering multiple, spatially distinct, navigation vectors between the hive and among multiple feeding sites. Second, this documented and useful representation of multiple navigation vectors between multiple, identified target locations logically implies composite place‐vector mapping, stored in long‐term memory.     

Das Orientierungssystem der V?gel I. Kompa?mechanismen

Zusammenfassung V?gel stellen den Bezug zum Ziel indirekt über ein externes Referenzsystem her. Der Navigationsproze? besteht deshalb aus zwei Schritten: zun?chst wird die Richtung zum Ziel als Kompa?kurs festgelegt, dann wird dieser Kurs mit Hilfe eines Kompa?mechanismus aufgesucht. Das Magnetfeld der Erde und Himmelsfaktoren werden von den V?gel als Kompa? benutzt. In der vorliegenden Arbeit werden der Magnetkompa?, der Sonnenkompa? und der Sternkompa? der V?gel in ihrer Funktionsweise, ihrer Entstehung und ihrer biologischen Bedeutung vorgestellt. Der Magnetkompa? erwies sich als Inklinationskompa?, der nicht auf der Polarit?t, sondern auf der Neigung der Feldlinien im Raum beruht; er unterscheidet „polw?rts“ und „?quatorw?rts“ statt Nord und Süd. Er ist ein angeborener Mechanismus und wird beim Vogelzug und beim Heimfinden benutzt. Seine eigentliche Bedeutung liegt jedoch darin, da? er ein Referenzsystem bereitstellt, mit dessen Hilfe andere Orientierungsfaktoren zueinander in Beziehung gesetzt werden k?nnen. Der Sonnenkompa? beruht auf Erfahrung; Sonnenazimut, Tageszeit und Richtung werden durch Lernprozesse miteinander verknüpft, wobei der Magnetkompa? als Richtungsreferenzsystem dient. Sobald er verfügbar ist, wird der Sonnenkompa? bei der Orientierung im Heimbereich und beim Heimfinden bevorzugt benutzt; beim Vogelzug spielt er, wahrscheinlich wegen seiner Abh?ngigkeit von der geographischen Breite, kaum eine Rolle. Der Sternkompa? arbeitet ohne Beteiligung der Inneren Uhr; die V?gel leiten Richtungen aus den Konfigurationen der Sterne zueinander ab. Lernprozesse erstellen den Sternkompa? in der Phase vor dem ersten Zug; dabei fungiert die Himmelsrotation als Referenzsystem. Sp?ter, w?hrend des Zuges, übernimmt der Magnetkompa? diese Rolle. Die relative Bedeutung der verschiedenen Kompa?systeme wurde in Versuchen untersucht, bei denen Magnetfeld und Himmelsfaktoren einander widersprechende Richtungs-information gaben. Die erste Reaktion der V?gel war von Art zu Art verschieden; langfristig scheinen sich die V?gel jedoch nach dem Magnetkompa? zu richten. Dabei werden die Himmelsfaktoren umgeeicht, so da? magnetische Information und Himmelsinformation wieder im Einklang stehen. Der Magnetkompa? und die Himmelsfaktoren erg?nzen einander: der Magnetkompa? ersetzt Sonnen- und Sternkompa? bei bedecktem Himmel; die Himmelsfaktoren erleichtern den V?geln das Richtungseinhalten, zu dem der Magnetkompa? offenbar wenig geeignet ist. Magnetfeld und Himmelsfaktoren sollten deshalb als integrierte Komponenten eines multifaktoriellen Systems zur Richtungsorientierung betrachtet werden.

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The orientation system of birds — I. Compass mechanisms

Summary Because of the large distances involved, birds establish contact with their goal indirectly via an external reference. Hence any navigation is a two-step process: in the first step, the direction to the goal is determined as a compass course; in the second step, this course is located with a compass. The geomagnetic field and celestial cues provide birds with compass information. The magnetic compass of birds, the sun compass the star compass and the interactions between the compass mechanisms are described in the present paper. Magnetic compass orientation was first demonstrated by testing night-migrating birds in experimentally altered magnetic fields: the birds changed their directional tendencies according to the deflected North direction. The avian magnetic compass proved to be an inclination compass: it does not use polarity; instead it is based on the axial course of the field lines and their inclination in space, distinguishing “poleward” and “equatorward” rather than North and South. Its functional range is limited to intensities around the local field strength, but this biological window is flexible and can be adjusted to other intensities. The magnetic compass is an innate mechanism that is widely used in bird migration and in homing. Its most important role, however, is that of a basic reference system for calibrating other kinds of orientation cues. Sun compass orientation is demonstrated by clock-shift experiments: Shifting the birds' internal clock causes them to misjudge the position of the sun, thus leading to typical deflections which indicate sun compass use. The analysis of the avian sun compass revealed that it is based only on sun azimuth and the internal clock; the sun's altitude is not involved. The role of the pattern of polarized light associated with the sun is unclear; only at sunset has it been shown to be an important cue for nocturnal migrants, being part of the sun compass. The sun compass is based on experience; sun azimuth, time of day and direction are combined by learning processes during a sensitive period, with the magnetic compass serving as directional reference. When established, the sun compass becomes the preferred compass mechanism for orientation tasks within the home region and homing: in migration, however, its role is minimal, probably because of the changes of the sun's arc with geographic latitude. The star compass was demonstrated in night-migrating birds by projecting the northern stars in different directions in a planetarium. The analysis of the mechanism revealed that the internal clock is not involved; birds derive directions from the spatial relationship of the star configurations. The star compass is also established by experience; the directional reference is first provided by celestial rotation, later, during migration, by the magnetic compass. The relative importance of the various compass mechanisms has been tested in experiments in which celestial and magnetic cues gave conflicting information. The first response of birds to conflicting cues differs considerably between species; after repeated exposures, however, the birds oriented according to magnetic North, indicating a long-term dominance of the magnetic compass. Later tests in the absence of magnetic information showed that celestial cues were not simply ignored, but recalibrated so that they were again in agreement with magnetic cues. The magnetic compass and celestial cues complement each other: the magnetic field ensures orientation under overcast sky; celestial cues facilitate maintaining directions, for which the magnetic compass appears to be ill suited. In view of this, the magnetic field and celestial cues should be regarded as integrated components of a multifactorial system for directional orientation.

     

Evidence for calibration of magnetic migratory orientation in Savannah sparrows reared in the field

The orientation system of migratory birds consists of a magnetic compass and compasses based upon celestial cues. In many places, magnetic compass directions and true or geographic compass directions differ (referred to as magnetic declination). It has been demonstrated experimentally in several species that the innate preferred direction of magnetic orientation can be calibrated by celestial rotation, an indicator of geographic directions. This calibration process brings the two types of compass into conformity and provides the birds with a mechanism that compensates for the spatial variation in magnetic declination. Calibration of magnetic orientation has heretofore been demonstrated only with hand-raised birds exposed to very large declination (90° or more). Here we show that the magnetic orientation of wild birds from near Albany, New York, USA (declination = 14° W) was N–S, a clockwise shift of 26° from the NNW–SSE direction of birds raised entirely indoors. Hand-raised birds having visual experience with either the daytime sky or both day and night sky orientated N–S, similar to wild-caught birds. These data provide the first confirmation that calibration of magnetic orientation occurs under natural conditions and in response to modest declination values.     

Can the antCataglyphis cursor (Hymenoptera: Formicidae) encode global landmark-landmark relationships in addition to isolated landmark-goal relationships?

The antCataglyphis cursor was tested for its landmark-based homing in a laboratory setting. Workers were induced to go down a tube at the center of an arena to forage. On the periphery of the arena were four different black shapes serving as the only distinguishing visual landmarks, i.e., a cross, a circle, a triangle, and a square. The purpose was to show that the spatial memory of ants represents something of the overall arrangement of landmarks. When first released into the arena, the ants were not oriented toward home in their navigation. After 2 days of free access in the usual landmark setup, the ants learned to orient rapidly significantly goalward. When landmarks were all removed, they did not orient in any direction significantly. When the landmarks were rotated by 90°, their compass positions were changed but their relative positions maintained, and the ants rotated their heading by a similar amount. This rotated homing direction implies that the array of landmarks was used as the only source of directional determination. When the landmark nearest their home was absent, but the other three were in their usual places, the ants were slightly homeward oriented at one-quarter of the way, but not at one-half of the way when the other landmarks were behind them. When the landmarks were randomly permuted, both their compass positions and their overall spatial relationships were altered, and the ants were not significantly oriented in any direction. These results indicate that spatial memory in the antC. cursor encodes global landmark-landmark relations. Thus, ants can abstract certain topological properties of their environment.     

Perceptual Strategies of Pigeons to Detect a Rotational Centre—A Hint for Star Compass Learning?

Birds can rely on a variety of cues for orientation during migration and homing. Celestial rotation provides the key information for the development of a functioning star and/or sun compass. This celestial compass seems to be the primary reference for calibrating the other orientation systems including the magnetic compass. Thus, detection of the celestial rotational axis is crucial for bird orientation. Here, we use operant conditioning to demonstrate that homing pigeons can principally learn to detect a rotational centre in a rotating dot pattern and we examine their behavioural response strategies in a series of experiments. Initially, most pigeons applied a strategy based on local stimulus information such as movement characteristics of single dots. One pigeon seemed to immediately ignore eccentric stationary dots. After special training, all pigeons could shift their attention to more global cues, which implies that pigeons can learn the concept of a rotational axis. In our experiments, the ability to precisely locate the rotational centre was strongly dependent on the rotational velocity of the dot pattern and it crashed at velocities that were still much faster than natural celestial rotation. We therefore suggest that the axis of the very slow, natural, celestial rotation could be perceived by birds through the movement itself, but that a time-delayed pattern comparison should also be considered as a very likely alternative strategy.     

Kompass im Kopf

Ant compass – how desert ants learn to navigate Successful spatial orientation is a daily challenge for many animals. Cataglyphis desert ants are famous for their navigational performances. They return to the nest after extensive foraging trips without any problems. How do ants take their navigational systems into operation? After conducting different tasks in the dark nest for several weeks, they become foragers under bright sun light. This transition requires both a drastic switch in behavior and neuronal changes in the brain. Experienced foragers mainly rely on visual cues. They use a celestial compass and landmark panoramas. For that reason, naïve ants perform stereotype learning walks to calibrate their compass systems and acquire information about the nest's surroundings. During their learning walks, the ants frequently look back to the nest entrance to learn the homing direction. For aligning their gazes, they use the earth's magnetic field as a compass reference. This magnetic compass in Cataglyphis ants was previously unknown.     

昆虫定向机制研究进展

许多昆虫具有定向运动的行为。对部分社会性昆虫和迁飞性昆虫定向行为的大量研究已经初步阐明太阳、地磁场、天体、风及地面标志物等都可能成为昆虫返巢和迁飞定向的线索。社会性昆虫具有对不同定向线索进行整合而实现精确导航的能力。日间迁飞性昆虫利用时间补偿太阳罗盘进行定向的机制亦已明确,但夜间迁飞昆虫的定向机制尚需深入研究。迁飞性害虫定向机制的明确将有助于判断害虫迁飞路径及降落区域,为迁飞害虫的准确预测提供科学依据。本文对昆虫的定向机制研究进展进行了综述。