P‐24: Terrain Texture and 3‐D Object Cues in the Control of Heading in Simulated Flight

Patterson, Robert; Akhtar, Shama C.; Geri, George A.; Morgan, William J.; Pierce, Byron J.; Dyre, Brian P.; Covas, Christine M.

doi:10.1889/1.1830978

Cited by 1 publication

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“…Whereas there is no distinction between object height and object width in the occlusion model of Equations 1-3, these two variables may be expected to have different effects on motion perspective and hence on altitude-maintenance performance. The available experimental evidence suggests that motion-perspective cues are affected by vertically extended contours (Patterson et al, 2003) but not horizontally extended contours (Covas et al, 2005). In Experiment 2, we varied the radius (width) of 3-D objects in order to determine whether increasing horizontally extended oc-clusions affected altitude-maintenance performance differently than did the increase in vertically extended occlusions, which was tested in Experiment 1.…”

Section: Purposementioning

confidence: 99%

“…In the case of movement over a textured surface or a scene containing 3-D objects, the most salient perceptual cue is the motion gradient formed by differential movement of the texture elements or the 3-D objects (Sedgwick, 1986). This motion gradient is a visual cue that could be used for altitude maintenance (Patterson et al, 2003). Horizontal motion perspective has been shown to be used for lateral control, such as in the control of heading (see, e.g., Li & Warren, 2000;Longuet-Higgins & Prazdny, 1980;Rieger & Lawton, 1985), and there is some evidence that vertical motionperspective cues may also be used for altitude control (Covas et al, 2005).…”

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confidence: 99%

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The role of visual occlusion in altitude maintenance during simulated flight.

Gray¹,

Geri²,

Akhtar³

et al. 2008

Journal of Experimental Psychology: Human Perception and Perfor

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The use of visual occlusion as a cue to altitude maintenance in low-altitude flight (LAF) was investigated. The extent to which the ground surface is occluded by 3-D objects varies with altitude and depends on the height, radius, and density of the objects. Participants attempted to maintain a constant altitude during simulated flight over an undulating terrain with trees of various heights, radii, and densities. As would be predicted if participants used occlusion, root-mean-square error was related to the product of tree height and tree density (Experiment 1) and to the product of tree radius and tree density (Experiment 2). This relationship was also found for simulated terrains with a more realistic mixture of tree heights (Experiment 4). The authors present a modification to an occlusion model (T. Leung & J. Malik, 1997) that can be used to approximate occlusion in the context of LAF, and they evaluate the modified model using the present LAF data. On a practical level, simulating 3-D objects is computationally expensive. The present results suggest that performance may be maintained with fewer objects if their size is increased. Keywords: aviation, perception and action, visual occlusion, simulationThe ability to effectively control movement through the environment is one of the most important perceptual-motor skills humans possess. Whether walking, cycling, driving, or flying we must control our rate and direction of travel in a manner that will allow us to reach our goal while avoiding collisions with obstacles. Safe performance of these actions frequently requires that we regulate our position relative to some object or feature in the environment-for example, maintaining a safe distance behind a lead car in driving or keeping a safe distance from the road edge when cycling. In the present article we consider a particular example of this ability: regulating height above the ground in simulated aircraft flight.Of all of the perceptual-motor tasks performed by military pilots, low-altitude flight (LAF) is one of the most demanding and potentially the most dangerous. LAF can involve maintaining an altitude of less than 40 m while traveling at speeds up to 232 m/s (450 knots). Not surprisingly, this flight task accounts for disproportionately high numbers of accidents relative to the total number of flight hours (Wiener, 1988). Given this high level of risk, flight simulators are now used extensively to provide a training environment for pilots to acquire LAF skills.In order for simulator training of any flight skill to transfer positively to the real world, it is critical that the simulation include the necessary visual cues. Owing to both computational and display limitations, current flight simulators cannot provide all of the cues associated with LAF. The questions then become, to what extent can LAF tasks be performed given the cues that are available, and to what extent can those cues be traded off so as not to exceed limited simulator capabilities? Answering these questions requires empirical research...

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confidence: 99%

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confidence: 99%