# Human Performance --- ### Q61: When a pilot scans the sky to detect the presence of other aircraft, he should… ^t40q61 - A) try to take in the visible portion of the sky with large sweeping eye movements. - B) roll the eyes across as wide a field of vision as possible. - C) scan the sky sector by sector and let the eyes rest briefly on each sector. - D) take in the entire visible portion of the sky by moving the eyes as rapidly as possible. **Correct: C)** > **Explanation:** The correct scan technique for collision avoidance is a systematic sector-by-sector sweep with a brief pause of 1–2 seconds on each sector (C), because the eye can only achieve sharp focus when it is stationary — foveal vision requires fixation to detect small or distant targets against the sky background. Rapid sweeping or rolling movements (A, B, D) smear the image across the retina and prevent the photoreceptors from resolving the angular size of a distant aircraft. Each sector should subtend no more than about 10–15 degrees to ensure adequate coverage with effective fixation. ### Q62: Alcohol is eliminated at a rate of:... ^t40q62 - A) 0.5 per mille per hour. - B) 0.3 per mille per hour. - C) 0.1 per mille per hour. - D) 1 per mille per hour. **Correct: C)** > **Explanation:** The liver eliminates alcohol at a fixed rate of approximately 0.1 per mille (‰) per hour (C), largely independent of body weight, hydration, or the type of drink consumed. A pilot with a blood alcohol level of 0.5 ‰ after an evening of drinking would still have measurable alcohol 5 hours later, well within a pre-dawn departure window. A, B, and D all overstate the elimination rate, which would lead a pilot to dangerously underestimate residual impairment when calculating fitness for flight. ### Q63: From the following factors, identify the one that increases the risk of heart attack:... ^t40q63 - A) Lack of exercise. - B) Hypoglycaemia. - C) Undernutrition. - D) Cholesterol level too low. **Correct: A)** > **Explanation:** Physical inactivity (A) is a well-established independent risk factor for coronary artery disease and myocardial infarction, because regular exercise improves lipid profiles, reduces blood pressure, and maintains healthy body weight. In aviation medicine, cardiac incapacitation is a significant concern given its potential for sudden pilot incapacitation, which is why medical certification includes cardiac screening. B is wrong because hypoglycaemia is a blood sugar disorder relevant to diabetes, not a direct cardiac risk factor. C and D are wrong because undernutrition and low cholesterol are not associated with increased heart attack risk in the general population. ### Q64: Amphetamine is a stimulant which in Switzerland can be obtained on prescription from pharmacies... ^t40q64 - A) Pilots on duty on a flight of more than 5 hours are allowed to take this medication to stay awake. - B) Pilots on duty may solely take this medication if accompanied by a qualified co-pilot. - C) Pilots on duty on a flight of more than 5 hours should always have this medication at hand for moments of fatigue. - D) Due to its adverse effects, pilots on duty are not allowed to take this medication. **Correct: D)** > **Explanation:** Amphetamines are strictly prohibited for pilots on duty (D) because their adverse effects — including heightened aggression, impaired judgement, cardiovascular strain, and a severe crash phase of exhaustion after the stimulant wears off — create unacceptable flight safety risks. Aviation regulations require pilots to be free of all medications with significant CNS effects, and no flight duration (A, C) or the presence of a co-pilot (B) provides an exception. The correct approach to fatigue management in aviation is structural rest planning and adherence to duty time limitations, not pharmacological stimulation. ### Q65: What is meant by "risk area awareness" in aviation? ^t40q65 - A) Knowledge of accident rates during takeoff and landing. - B) The awareness that the aerodrome area where aircraft taxi ("risk area") is a dangerous zone. - C) Awareness of the potential hazards of the various phases of flight. - D) A procedure for preventing aviation accidents. **Correct: C)** > **Explanation:** Risk area awareness (C) refers to the pilot's continuous recognition that different phases of flight carry different and specific hazard profiles — takeoff and landing are statistically the most accident-prone phases, while cruise presents different risks such as weather, navigation, and airspace conflict. This concept underpins proactive threat and error management: by knowing which phase presents which threats, the pilot can apply heightened attention and appropriate procedures at the right moments. A is wrong because knowing accident statistics is not the same as actively applying phase-specific hazard awareness. B misapplies the term to a taxiway location; D is wrong because risk area awareness is an attitude and awareness framework, not a procedure. ### Q66: Several decision-making models are applied in aviation. A widely used model goes by the acronym "DECIDE". Which of the following statements is correct? ^t40q66 - A) The first D stands for "Do" and means "Apply the best option". - B) The first D stands for "Detect" and means "Recognise that a change has occurred which requires attention". - C) The first E stands for "Evaluate" and means "Assess the consequences of one's actions". - D) DECIDE is a decision-making aid that must be applied in every in-flight decision situation. **Correct: B)** > **Explanation:** In the DECIDE model, the first D stands for Detect — recognising that a change in the situation has occurred that demands attention (B). The full sequence is: Detect, Estimate (the significance), Choose (a course of action), Identify (the best option), Do (implement it), Evaluate (the outcome). A is wrong because "Do" is the fifth step, not the first. C is wrong because E stands for Estimate (assess the significance of the change), not Evaluate (which is the final step). D is wrong because DECIDE is a framework for non-routine decisions, not a mandatory procedure for every routine in-flight action. ### Q67: Regarding typical hazardous attitudes, which of the following statements is correct? ^t40q67 - A) It is possible to recognise and correct one's own hazardous attitudes. - B) An anti-authority attitude is less dangerous than macho behaviour. - C) Inexperienced pilots are generally the only ones who behave dangerously. - D) Hazardous attitudes do not really exist because flight safety depends solely on the pilot's attention. **Correct: A)** > **Explanation:** The entire rationale of hazardous attitude training is that self-awareness and targeted antidotes enable a pilot to recognise and counteract their own dangerous tendencies (A) — for example, responding to a macho impulse with the reminder "Taking chances is foolish." B is wrong because anti-authority attitudes (rejecting rules and procedures) are at least as dangerous as macho behaviour, since they undermine the entire safety system. C is wrong because experienced pilots can be equally susceptible, particularly to invulnerability and complacency. D is wrong because the existence and safety impact of hazardous attitudes is thoroughly established in aviation psychology research. ### Q68: Which of these statements correctly describes "selective attention"? ^t40q68 - A) Selective attention is unavoidable in the cockpit to avoid distraction during checklist recitation. - B) Selective attention can lead the pilot to fail to notice an audible alarm even though it is perfectly audible. - C) Selective attention refers to an attitude where attention is focused on flight instruments when visibility conditions are poor. - D) Selective attention is a method for avoiding stress. **Correct: B)** > **Explanation:** Selective attention is the cognitive mechanism by which the brain filters out most incoming sensory information to focus on a primary task — and in the cockpit this can cause a pilot to be completely unaware of an alarm, radio call, or warning light that is fully audible or visible (B). This is sometimes called inattentional blindness and is a documented contributing factor in numerous aviation incidents where crew were heads-down on a problem while another critical change went unnoticed. A is wrong because selective attention is an involuntary perceptual hazard, not a deliberate strategy. C describes instrument flying technique; D misrepresents the concept — selective attention is not a stress management method. ### Q69: Regarding stress, which of the following statements is correct? ^t40q69 - A) There is an optimal level of stress that even improves performance. - B) Under-stimulation causes no stress and has no negative effect on performance. - C) Stress in the cockpit improves the work rate. - D) Stress is only caused by brief overload. **Correct: A)** > **Explanation:** The Yerkes-Dodson law demonstrates that there is an optimal level of arousal — often called eustress — at which cognitive performance is maximised (A). Below this level, insufficient stimulation leads to boredom and inattention; above it, excessive stress degrades performance through cognitive narrowing and decision errors. B is wrong because under-stimulation (monotony) is itself a recognised stressor that impairs vigilance — directly relevant to long solo flights. C is wrong because high stress generally reduces work quality even if it briefly increases pace. D is wrong because stress arises from many sources including sustained overload, time pressure, ambiguity, and emotional threat, not only from brief acute overload. ### Q70: The human internal clock… ^t40q70 - A) has a cycle of roughly 25 hours. - B) has a cycle of roughly 20 hours. - C) is synchronised with the external clock and its cycle lasts exactly 24 hours. - D) has a cycle of roughly 30 hours. **Correct: A)** > **Explanation:** The endogenous circadian rhythm — the internal biological clock — runs on a free-running cycle of approximately 25 hours (A), which is slightly longer than the 24-hour solar day and must be reset daily by light exposure, primarily in the morning. This slight mismatch explains why jet lag is asymmetric: eastward travel (shortening the day) is more disruptive than westward travel. B and D give incorrect cycle lengths; C is wrong because the internal clock inherently deviates from exactly 24 hours — it requires continuous entrainment by external zeitgebers to stay aligned with the solar day. ### Q71: Which of the following measures is suitable for relieving the onset of motion sickness (kinetosis) in passengers? ^t40q71 - A) move the head regularly - B) look through the windows - C) breathe fresh air - D) drink coffee **Correct: C)** > **Explanation:** Fresh air (C) is an effective early intervention for motion sickness because it reduces the autonomic component of the response — cooling the skin, normalising breathing, and reducing the nausea trigger via the vagus nerve. A is wrong because head movements during flight aggravate motion sickness by producing the Coriolis effect in the semicircular canals. B is wrong because looking through small windows at a moving scene can worsen the vestibular-visual conflict; only an unobstructed stable external horizon is helpful. D is wrong because caffeine provides no relief and may increase anxiety and gastric discomfort. ### Q72: During training, a pilot has mainly used narrow runways. What illusion will this pilot experience during a correct final approach to a flat, very wide runway? ^t40q72 - A) the illusion that the runway slopes upward in the landing direction (upslope) - B) the illusion of being at a greater height above the runway than is actually the case - C) the illusion of being lower above the runway than is actually the case - D) the illusion that the runway first slopes upward (upslope) then downward (downslope) **Correct: C)** > **Explanation:** A pilot trained on narrow runways has calibrated height perception to the visual angle subtended by a narrow strip; when approaching a much wider runway at the same actual height, the runway subtends a larger angle than expected, making it appear closer and lower — creating an illusion of being lower than reality (C). This leads to a tendency to fly a higher-than-correct approach angle, risking an overshoot. B describes the opposite illusion produced by a narrower-than-usual runway. A and D describe slope illusions caused by runway gradient, a different visual phenomenon unrelated to runway width. ### Q73: When are middle ear pressure equalization problems most probable to occur? ^t40q73 - A) during a long flight at high altitude - B) during a rapid descent - C) during a long climb - D) during strong negative vertical accelerations **Correct: B)** > **Explanation:** Middle ear pressure equalisation problems occur predominantly during descent (B) because as altitude decreases, ambient pressure rises and air must flow into the middle ear through the Eustachian tube. The Eustachian tube opens more easily to release pressure outward (during climb) than to allow air inward (during descent), especially when congested from a cold or allergy; a rapid descent builds the pressure differential faster than the tube can compensate. A is wrong because constant altitude produces no pressure differential. C is wrong because climb allows easier outward flow of middle ear air. D is wrong because brief vertical accelerations do not create the sustained ambient pressure changes that cause barotrauma. ### Q74: The proportion of oxygen in the atmosphere is 21% at sea level. How does it change at 5500 m? ^t40q74 - A) it is one quarter of the sea level percentage - B) it is half the sea level percentage - C) it is double the sea level percentage - D) it is the same as at sea level **Correct: D)** > **Explanation:** The proportion of oxygen in the atmosphere remains approximately 21% at all altitudes up to roughly 80 km (D), because atmospheric mixing keeps the composition of the homosphere essentially uniform. What changes dramatically with altitude is total atmospheric pressure — and therefore the partial pressure of oxygen — which at 5,500 m is roughly half the sea-level value, meaning each breath delivers only half as many oxygen molecules. A, B, and C all incorrectly suggest that the oxygen fraction itself changes; the key concept is the distinction between oxygen fraction and oxygen partial pressure. ### Q75: Which are the effects of inhaling carbon monoxide (from a defective exhaust system)? ^t40q75 - A) even in low concentrations, this gas can cause total incapacitation - B) there are no harmful effects to fear as carbon monoxide is harmless - C) harmful effects are solely to be expected if the body is exposed to the gas for several hours - D) there are no harmful effects to fear as the body compensates for the reduced oxygen supply **Correct: A)** > **Explanation:** Carbon monoxide is dangerous even at very low concentrations (A) because it binds to haemoglobin with approximately 200 times the affinity of oxygen, rapidly forming carboxyhaemoglobin that cannot transport oxygen, while simultaneously impairing cellular respiration. The onset of cognitive impairment and incapacitation can be rapid and insidious — CO is colourless, odourless, and tasteless, providing no warning. B and D are dangerously wrong; the body cannot effectively compensate because the CO-haemoglobin bond is extremely strong. C is wrong because incapacitation can occur within minutes of significant exposure, not after hours. ### Q76: Which is the most effective hearing protection in the cabin of a powered aircraft or hot air balloon? ^t40q76 - A) cotton wool - B) a helmet with earphones - C) ear plugs - D) due to the low noise produced, any protection is effective **Correct: B)** > **Explanation:** A helmet with integrated earphones (B) provides the most effective hearing protection because it combines circumaural attenuation of the outer ear with active communication through the earphones, and its rigid structure prevents bone conduction of sound. Cotton wool (A) provides minimal and inconsistent attenuation with no communication function. Earplugs (C) offer moderate passive protection but lack the communication capability essential for radio operation. D is wrong because engine noise in powered aircraft and hot air balloon burners can exceed safe exposure limits during prolonged flights, and noise-induced hearing loss is cumulative and irreversible. ### Q77: Gas-forming foods that cause flatulence ought to be avoided before a high-altitude flight. Which of these foods must therefore be avoided? ^t40q77 - A) legumes (beans) - B) meat - C) pasta - D) potatoes **Correct: A)** > **Explanation:** Legumes such as beans, lentils, and peas (A) are the principal gas-forming foods because their oligosaccharides are fermented by intestinal bacteria, producing significant quantities of gas. At altitude, Boyle's Law dictates that gas volume expands inversely with pressure: at 18,000 ft, intestinal gas approximately doubles in volume compared to sea level, potentially causing severe abdominal pain and distension that distracts the pilot. B, C, and D are not significant gas producers. The same principle applies to carbonated drinks, which should also be avoided before high-altitude flights. ### Q78: The respiratory process enables gas exchange in somatic cells (metabolism). These cells… ^t40q78 - A) absorb nitrogen and release oxygen - B) absorb oxygen and release carbon dioxide (CO2) - C) absorb oxygen and release nitrogen - D) absorb oxygen and release carbon monoxide (CO) **Correct: B)** > **Explanation:** Cellular (aerobic) respiration in somatic cells involves the uptake of oxygen (O₂) and the release of carbon dioxide (CO₂) as nutrients are oxidised to produce ATP energy (B). This is the reverse of the gas exchange occurring in the lungs, where CO₂ is expelled and O₂ is absorbed from alveolar air into the bloodstream. A is wrong because nitrogen is physiologically inert under normal conditions and is neither consumed nor produced in cellular metabolism. C repeats this nitrogen error. D is wrong because carbon monoxide is a product of incomplete combustion; healthy cells do not produce it. ### Q79: A regular smoker pilot smokes a few cigarettes shortly before an alpine flight. What effects might this have on their flight fitness? ^t40q79 - A) for a regular smoker, there are no effects to fear as the body is accustomed to the harmful substances absorbed - B) the pilot will experience oxygen deficiency at a lower altitude than if they had abstained from smoking before the flight - C) the nicotine absorbed may cause mild disturbances of consciousness and difficulty concentrating - D) the smoke causes mild carbon dioxide (CO2) poisoning, which may cause sensations of dizziness and numbness **Correct: B)** > **Explanation:** Smoking shortly before flight raises the carboxyhaemoglobin level in the blood — CO from cigarette smoke binds to haemoglobin and reduces the blood's effective oxygen-carrying capacity before the aircraft even leaves the ground, so hypoxic symptoms will appear at a lower altitude than for a non-smoker (B). A is wrong because habituation to nicotine does not protect against the acute oxygen-carrying impairment caused by elevated carboxyhaemoglobin. C is wrong because the primary aviation-relevant hazard of pre-flight smoking is CO-induced oxygen reduction, not nicotine's direct CNS effects. D is wrong because the relevant gas is CO (carbon monoxide), not CO₂ (carbon dioxide). ### Q80: When is the risk of vestibular disturbance causing dizziness greatest? ^t40q80 - A) when rotating the head during a descent - B) when rotating the head during straight-and-level flight - C) when rotating the head during a climb - D) when rotating the head during a coordinated turn **Correct: D)** > **Explanation:** The risk of vestibular dizziness is greatest when rotating the head during a coordinated turn (D), because the semicircular canals are already registering the rotational acceleration of the turn. A head rotation in a perpendicular plane simultaneously activates canals in a different axis, compounding the vestibular input and producing the disorienting Coriolis illusion — an overwhelming sensation of tumbling in an unexpected direction. A, B, and C all involve head movements, but without the pre-existing rotational loading of the canals, the Coriolis effect cannot occur; straight flight, climbs, and descents alone do not provide this compounding stimulus. ### Q81: How can a pilot better withstand positive g-forces in flight? ^t40q81 - A) by sitting as upright as possible - B) by relaxing their muscles and leaning forward - C) by contracting the abdominal and leg muscles and performing forced breathing - D) by tightening their harness straps as much as possible **Correct: C)** > **Explanation:** Contracting the abdominal and leg muscles while performing a forced exhalation against a closed glottis — the Anti-G Straining Manoeuvre (C) — raises intra-abdominal pressure, constricts peripheral blood vessels, and reduces the volume of blood displaced from the head to the lower body, significantly delaying grey-out and G-LOC. A is wrong because posture alone does not generate the necessary intravascular pressure increase. B is wrong because relaxing muscles accelerates blood pooling in the legs and worsens g-tolerance. D is wrong because harness tightness improves body-seat coupling but does not influence the cardiovascular mechanism of g-tolerance. ### Q82: Which are the most dangerous effects of oxygen deficiency? ^t40q82 - A) tingling sensations - B) blue discoloration of fingernails and lips - C) impairment of judgment and concentration - D) nausea **Correct: C)** > **Explanation:** The most dangerous effect of oxygen deficiency is impairment of judgement and concentration (C), because the hypoxic pilot loses the cognitive ability to recognise their own incapacitation — they feel well, or even euphoric, while their decision-making capacity is already seriously degraded. This "happy hypoxia" is what makes the condition so lethal: the pilot does not recognise the need to descend or use supplemental oxygen. A (tingling) and B (cyanosis) are physical signs that may appear after cognitive impairment is already advanced, and D (nausea) is a non-specific symptom with no direct consequence for flight control. ### Q83: What can be said about the rate of blood alcohol elimination in humans? ^t40q83 - A) it is accelerated by breathing pure oxygen - B) it depends only on time and amounts to roughly 0.1 per mille per hour - C) it depends on the alcohol content of the drink consumed - D) it can be accelerated by drinking strong coffee **Correct: B)** > **Explanation:** Blood alcohol elimination is a fixed metabolic process governed by the liver's zero-order kinetics, proceeding at approximately 0.1 per mille per hour regardless of external interventions (B). Neither breathing oxygen (A), drinking coffee (D), nor any other popular remedy meaningfully accelerates this rate. C is wrong because the type or strength of drink consumed affects only the peak blood alcohol level, not the rate at which it is subsequently cleared. This is a critical safety principle: a pilot cannot "sober up faster" and must calculate backwards from consumption time to ensure compliance before flight. ### Q84: What impact does proprioception (deep sensitivity) have on position perception? ^t40q84 - A) in coordination with the balance organ, proprioception gives a correct position impression even when visibility is lost - B) when visual references are lost, proprioception can give a false perception of position - C) proprioception alone is always sufficient to sustain a correct perception of position - D) when training is adequate, proprioception can prevent spatial disorientation when visibility is lost **Correct: B)** > **Explanation:** When visual references are lost, proprioceptive signals from muscles, tendons, and joints can generate false impressions of aircraft attitude or position (B), because the proprioceptive system is calibrated for terrestrial movement and cannot reliably distinguish the complex accelerations of flight from gravitational loads. This is why spatial disorientation occurs: the body "feels" level while the aircraft is in a banked spiral. A and C are wrong because neither proprioception alone nor its combination with the vestibular system can substitute for visual or instrument references in flight. D is wrong because no training can overcome the physiological limitations of proprioception in IMC. ### Q85: Which of these factors has no direct effect on visual acuity? ^t40q85 - A) high blood pressure - B) carbon monoxide (CO) - C) oxygen deficiency - D) alcohol **Correct: A)** > **Explanation:** High blood pressure (A) does not have a direct, immediate effect on visual acuity during normal flight; while chronic hypertension can eventually cause retinopathy, acute elevated blood pressure within physiological limits does not impair the optical or neural components of vision in a way relevant to flight safety. In contrast, carbon monoxide (B) reduces retinal oxygenation by binding haemoglobin; oxygen deficiency (C) impairs retinal function because the retina has the highest specific oxygen consumption of any body tissue; and alcohol (D) causes dose-dependent degradation of contrast sensitivity, night vision, and stereo acuity. ### Q86: Up to what maximum altitude can a healthy human body compensate for oxygen deficiency by increasing heart rate and breathing rate? ^t40q86 - A) roughly 3,000 ft - B) roughly 22,000 ft - C) roughly 6,000-7,000 ft - D) roughly 10,000-12,000 ft **Correct: D)** > **Explanation:** A healthy body can partially compensate for decreasing oxygen partial pressure by increasing both heart rate and respiratory rate up to approximately 10,000–12,000 ft (D); beyond this altitude, these compensatory mechanisms become insufficient to maintain adequate arterial oxygen saturation. A is wrong because 3,000 ft is well within the normal compensatory range and requires no additional physiological effort. C is wrong because 6,000–7,000 ft is the altitude at which compensation begins, not its upper limit. B is wrong because 22,000 ft is far above the compensation ceiling — at that altitude, loss of consciousness occurs rapidly without oxygen supplementation. ### Q87: What has to be observed when taking over-the-counter medications? ^t40q87 - A) even over-the-counter medications can influence flight fitness - B) over-the-counter medications have no side effects and therefore no influence on flight fitness - C) all flying is prohibited after taking any medication - D) over-the-counter medications only have insignificant side effects; their influence on flight fitness is negligible **Correct: A)** > **Explanation:** Over-the-counter (OTC) medications can have side effects that directly impair flight safety (A), including sedation from antihistamines, blurred vision from decongestants, reduced reaction time, dizziness, or impaired judgement — even at therapeutic doses. The fact that a drug is available without a prescription reflects relative safety for healthy adults in everyday life, but aviation demands a much higher standard of cognitive and physiological performance. B and D both understate the risk; C overstates it by prohibiting all medication. Pilots should consult their aviation medical examiner before taking any medication, including OTC products. ### Q88: What sensory illusion can a linear acceleration produce in horizontal flight when visual references are lost? ^t40q88 - A) the impression of being in a left turn - B) the impression of descending - C) the impression of being in a right turn - D) the impression of climbing **Correct: D)** > **Explanation:** A sustained forward linear acceleration in level flight creates the somatogravic illusion (D): the otoliths cannot distinguish between the forward inertial force of acceleration and the backward component of a nose-up pitch, so the brain interprets the acceleration as a climb. This illusion is particularly dangerous on take-off at night or in poor visibility, where the instinctive response to a perceived climb is to push the nose down — potentially into terrain. A and C (turn impressions) are produced by angular acceleration in the semicircular canals, not by linear translational acceleration. B is the opposite of the actual illusion produced. ### Q89: How long does the human eye take to fully adapt to darkness? ^t40q89 - A) roughly 1 second - B) roughly 10 minutes - C) roughly 10 seconds - D) roughly 30 minutes **Correct: D)** > **Explanation:** Full dark adaptation — the regeneration of rhodopsin photopigment in the rod photoreceptors of the peripheral retina — takes approximately 30 minutes (D). Rods are responsible for scotopic (low-light) vision but are bleached by exposure to bright light, and their photopigment recovery is a biochemical process that cannot be accelerated. A, B, and C all underestimate the required time. For night flying, pilots must avoid bright light sources for 30 minutes before flight; even brief exposure to white light can partially reset dark adaptation and require another recovery period. ### Q90: Which of these statements about hyperventilation is correct? ^t40q90 - A) hyperventilation is always a consequence of oxygen deficiency - B) hyperventilation causes an excess of carbon dioxide (CO2) in the blood - C) hyperventilation can be triggered by stress and anxiety - D) hyperventilation causes a deficiency of carbon monoxide (CO) in the blood **Correct: C)** > **Explanation:** Hyperventilation is commonly triggered by psychological states such as stress, anxiety, or fear (C) — as well as pain, altitude, or deliberate over-breathing — and involves breathing faster or deeper than the body's metabolic demand. A is wrong because hyperventilation is not caused by oxygen deficiency; in fact, it raises blood oxygen levels while reducing CO₂. B is wrong because hyperventilation causes a deficiency (not excess) of CO₂ — the resulting hypocapnia causes respiratory alkalosis, leading to symptoms such as tingling, spasms, and dizziness that can mimic hypoxia. D is wrong because carbon monoxide plays no role in hyperventilation physiology.