### Q101: What illusion can occur when visual references are lost during a prolonged coordinated turn? ^t40q101 - A) the impression of no longer being in a turn (wings level) - B) the impression of being in a descent - C) the impression of being in a climb - D) the impression of being in a greater bank angle than is actually the case **Correct: A)** > **Explanation:** During a prolonged coordinated turn at constant rate, the fluid in the semicircular canals gradually matches the rotation speed and stops deflecting the sensory hairs, causing the vestibular system to signal "no turn" even though the aircraft remains banked. The pilot perceives wings-level flight. If the pilot then levels the wings, they experience the sensation of turning in the opposite direction and may re-enter the original turn — this is the mechanism behind the deadly graveyard spiral. Option B, Option C, and Option D describe different illusions not associated with vestibular adaptation during steady turns. ### Q102: Your passenger wishes to ease their fear of flying by drinking a strong alcoholic drink just before departure. What effect has to be expected at high altitude? ^t40q102 - A) at high altitude, the psychological effects of alcohol decrease - B) alcohol is eliminated more slowly at high altitude than on the ground - C) alcohol is eliminated more rapidly at high altitude than on the ground - D) oxygen deficiency at high altitude amplifies the effects of alcohol **Correct: D)** > **Explanation:** At altitude, the reduced partial pressure of oxygen (hypoxia) acts synergistically with alcohol to amplify its impairing effects on the central nervous system. Both hypoxia and alcohol independently degrade cognitive function, and together they produce a combined impairment far greater than either alone — sometimes described as a multiplier effect. Option A incorrectly claims that alcohol effects decrease at altitude. Option B and Option C concern the elimination rate, which is primarily determined by liver metabolism and does not change significantly with altitude. The combination of altitude and alcohol is particularly dangerous for passengers who may need to respond in an emergency. ### Q103: Which is the correct technique for seeing at night? ^t40q103 - A) stare directly at distant, faintly lit objects as directly as possible - B) do not stare directly at objects but look slightly to the side - C) stare directly at all objects as directly as possible - D) scan objects with rapid large eye movements **Correct: B)** > **Explanation:** At night, the central fovea of the retina — used for direct vision — contains only cone cells, which require more light to function effectively. The rod cells responsible for low-light sensitivity are concentrated in the retinal periphery. Looking slightly to the side of an object (off-centre viewing) places its image on the rod-rich area, making it visible in dim conditions. Option A and Option C (staring directly) use only the foveal cones, which are essentially blind in low light, causing the object to disappear. Option D (rapid large eye movements) disrupts the fixation time needed for the rods to detect faint light. ### Q104: Your passenger complains of middle ear pressure equalization problems. How can you help them? ^t40q104 - A) stop the climb, if possible descend until the pain subsides, then climb again at a lower rate - B) stop the descent, if possible climb until the pain subsides, then descend at a lower rate - C) descend at a higher rate until the pain subsides, then continue descending at a lower rate - D) stop the descent, if possible climb until the pain subsides, then descend at a higher rate **Correct: B)** > **Explanation:** Middle ear pressure equalisation problems occur most commonly during descent, when increasing external pressure cannot enter the middle ear cavity fast enough through the Eustachian tube. The correct remedy is to stop the descent, climb slightly if possible to reduce the pressure differential and allow the pain to subside, then resume the descent at a slower rate to give the Eustachian tube time to equalise. Option A addresses climbing problems, which are much less common. Option C (descending faster) would worsen the pressure imbalance. Option D correctly stops the descent but then resumes at a higher rate, which would recreate the problem. ### Q105: Which of the following symptoms may indicate oxygen deficiency? ^t40q105 - A) joint pain - B) lung pain - C) reduced heart rate - D) difficulty concentrating **Correct: D)** > **Explanation:** Difficulty concentrating is one of the earliest and most characteristic symptoms of hypoxia (oxygen deficiency), reflecting the brain's high sensitivity to reduced oxygen supply. As altitude increases and oxygen partial pressure drops, cognitive functions deteriorate before physical symptoms become apparent. Option A (joint pain) is associated with decompression sickness, not hypoxia. Option B (lung pain) is not a typical hypoxia symptom. Option C (reduced heart rate) is incorrect because the body's compensatory response to hypoxia is to increase heart rate, not decrease it. ### Q106: What causes motion sickness (kinetosis)? ^t40q106 - A) a disorder of the middle ear - B) irritation of the balance organ - C) evaporation of gases into the blood - D) a strong reduction in atmospheric pressure **Correct: B)** > **Explanation:** Motion sickness is caused by irritation of the vestibular system (balance organ) in the inner ear when it receives conflicting signals from the eyes, the vestibular apparatus, and proprioceptors. This sensory mismatch — for example, the inner ear detecting motion while the eyes see a stationary cockpit interior — triggers the autonomic nervous system response that produces nausea and vomiting. Option A (middle ear disorder) confuses a pathological condition with a normal physiological response. Option C and Option D describe altitude-related phenomena (decompression) that are unrelated to motion sickness. ### Q107: Which are the side effects of anti-motion-sickness medications? ^t40q107 - A) drowsiness and slowed reaction time - B) general weakness and loss of appetite - C) exhaustion and depression - D) hyperactivity and risk-taking tendency **Correct: A)** > **Explanation:** Anti-motion-sickness medications — primarily antihistamines (such as dimenhydrinate) and anticholinergics (such as scopolamine) — commonly cause drowsiness and significantly slowed reaction times as their primary side effects. These effects directly compromise the alertness and rapid decision-making required for safe flying. Option B, Option C, and Option D describe side effects not typically associated with standard anti-motion-sickness drugs. Because of the sedating effects described in Option A, pilots should not use these medications before or during flight without medical clearance from an aviation medical examiner. ### Q108: What is decisive for the onset of noise-induced hearing loss? ^t40q108 - A) only the duration of noise exposure - B) the duration and intensity of the noise - C) only the intensity of the noise - D) the sudden onset of a noise **Correct: B)** > **Explanation:** Noise-induced hearing loss depends on the total sound energy dose received by the ear, which is a function of both the intensity (measured in decibels) and the duration of exposure. A very loud noise over a short period or a moderately loud noise sustained over many hours can both cause permanent damage. Option A ignores intensity — a quiet sound, no matter how long the exposure, will not cause damage. Option C ignores duration — a brief loud burst is generally less harmful than the same intensity sustained for hours. Option D (sudden onset) describes acoustic shock, which is only one mechanism and not the full picture. ### Q109: Increasing and sustained positive g-loads can produce symptoms that appear in the following order:... ^t40q109 - A) loss of color vision, reduction of peripheral vision, total loss of vision, loss of consciousness - B) red-out, reduction of peripheral vision, total loss of vision, loss of consciousness - C) reduction of peripheral vision, loss of color vision, total loss of vision, loss of consciousness - D) loss of color vision, reduction of peripheral vision, red-out, loss of consciousness **Correct: A)** > **Explanation:** As positive g-forces increase, blood drains from the head toward the lower body in a predictable sequence of visual and neurological symptoms: first grey-out (loss of colour vision as the retina receives less oxygenated blood), then tunnel vision (reduction of peripheral vision as the outer retina fails first), then complete blackout (total loss of vision), and finally G-LOC (loss of consciousness). Option B incorrectly begins with red-out, which occurs under negative g-forces, not positive. Option C reverses the first two symptoms. Option D inserts red-out mid-sequence, which does not occur during positive g-loading. ### Q110: From what altitude does the body of a healthy person begin to compensate for oxygen deficiency by accelerating breathing rate? ^t40q110 - A) roughly 6,000-7,000 ft - B) roughly 10,000-12,000 ft - C) roughly 3,000-4,000 ft - D) from 12,000 ft **Correct: A)** > **Explanation:** At approximately 6,000-7,000 ft, the reduced partial pressure of oxygen becomes sufficient to trigger the body's chemoreceptors, which detect the drop in blood oxygen and stimulate an increase in respiratory rate as a compensatory mechanism. Option B (10,000-12,000 ft) describes the upper limit of effective compensation, not where it begins. Option C (3,000-4,000 ft) is too low — at this altitude, the oxygen reduction is minimal and no compensation is needed. Option D (from 12,000 ft) is the point where compensation becomes inadequate, not where it starts. ### Q111: The ideal level of arousal is at which point in the diagram? See figure (HPL- 002) P = Performance A = Arousal / Stress Siehe Anlage 1... ^t40q111 - A) Point C - B) Point D - C) Point B - D) Point A **Correct: C)** > **Explanation:** The Yerkes-Dodson law, illustrated by the inverted-U curve in figure HPL-002, shows that performance peaks at a moderate, optimal level of arousal — represented by Point B at the top of the curve. Option D (Point A) lies on the left side where arousal is too low, resulting in boredom, inattention, and poor performance. Option A (Point C) and Option B (Point D) represent progressively higher arousal levels on the right side of the curve, where over-stimulation causes anxiety, cognitive overload, and declining performance. For pilots, maintaining arousal at Point B ensures maximum alertness without the errors that come from excessive stress. ### Q112: Which answer is correct concerning stress? ^t40q112 - A) Everybody reacts to stress in the same manner - B) Stress and its different symptoms are irrelevant for flight safety - C) Stress can occur if there seems to be no solution for a given problem - D) Training and experience have no influence on the occurence of stress **Correct: C)** > **Explanation:** Stress commonly arises when a person perceives a threatening or problematic situation for which no adequate solution appears available — the feeling of being trapped or overwhelmed triggers the physiological stress response. Option A is incorrect because individual stress responses vary enormously based on personality, experience, coping mechanisms, and physical condition. Option B dangerously dismisses the impact of stress on flight safety, when in fact stress-related errors are a major factor in aviation incidents. Option D is wrong because training and experience are proven to raise the stress threshold by providing learned responses to challenging situations. ### Q113: During flight you have to solve a problem, how to you proceed? ^t40q113 - A) Solve problem immediately, otherwise refer to the operationg handbook - B) Contact other pilot via radio for help, keep flying - C) Primarily fly the airplane and keep it stable, then attend to the problem and keep flying the airplane - D) There is no time for solving problems during flight **Correct: C)** > **Explanation:** The fundamental principle of airmanship is "aviate, navigate, communicate" — in that order. The pilot's primary duty is always to fly the aircraft and maintain stable flight before addressing any secondary problem. Option A risks losing aircraft control by prioritising problem-solving over flying. Option B (radio contact) is a valid step but must come after ensuring the aircraft is under control. Option D incorrectly implies that problem-solving during flight is impossible, when in fact pilots routinely handle in-flight issues provided they maintain aircraft control as the overriding priority. ### Q114: At which point in the diagram will a pilot find himself to be overstrained? See figure (HPL-002) P = Perfromance A = Arousal / Stress Siehe Anlage 1... ^t40q114 - A) Point D - B) Point C - C) Point A - D) Point B **Correct: A)** > **Explanation:** On the Yerkes-Dodson inverted-U curve, Point D represents the extreme right of the arousal axis where stress levels are very high and performance has collapsed — the pilot is overstrained. At this level of arousal, cognitive function breaks down, decision-making becomes erratic, and the risk of critical errors increases dramatically. Option B (Point C) represents elevated but not yet maximal stress. Option C (Point A) represents under-arousal and boredom. Option D (Point B) is the peak of the curve where optimal performance occurs. Recognising the slide from Point B toward Point D is a critical pilot skill. ### Q115: The swiss cheese model is used to explain the... ^t40q115 - A) State of readiness of a pilot. - B) Optimal problem solution. - C) Error chain. - D) Procedure for an emergency landing. **Correct: C)** > **Explanation:** James Reason's Swiss Cheese Model is a foundational concept in aviation safety that illustrates how accidents result from an error chain — a series of individual failures in successive defensive barriers that happen to align, allowing a hazard to penetrate all layers simultaneously. Each "slice of cheese" represents a safety barrier with inherent "holes" (latent conditions and active failures). Option A (pilot readiness) is assessed through fitness-to-fly checks, not the Swiss Cheese Model. Option B (problem solving) uses decision-making frameworks like DECIDE. Option D (emergency landing procedures) are covered by standard operating procedures and checklists, not error chain theory. ### Q116: What does the term Red-out mean? ^t40q116 - A) Rash during decompression sickness - B) Falsified colour perception during sunrise and sunset - C) "Red vision" during negative g-loads - D) Anaemia caused by an injury **Correct: C)** > **Explanation:** Red-out occurs during sustained negative g-forces (such as during a bunt or inverted flight manoeuvre), when blood is forced upward into the head and eyes. The excess blood pressure in the ocular capillaries produces a characteristic red tinge across the visual field. This is the negative-g counterpart to grey-out and blackout, which occur under positive g-forces when blood drains away from the head. Option A (decompression sickness rash) is an entirely different condition affecting dissolved gases in the body. Option B (sunrise/sunset colour) is a natural optical phenomenon, not a physiological impairment. Option D (anaemia from injury) is a medical condition unrelated to g-forces.