fbpx
Wikipedia

Astronaut training

January 14, 2023

Astronaut training describes the complex process of preparing astronauts in regions around the world for their space missions before, during and after the flight, which includes medical tests,[1] physical training,[2] extra-vehicular activity (EVA) training, procedure training, rehabilitation process,[3] as well as training on experiments they will accomplish during their stay in space.

A test subject being suited up for studies on the Reduced Gravity Walking Simulator. This position meant that a person's legs experienced only one sixth of their weight, which was the equivalent of being on the lunar surface. The purpose of this simulator was to study the subject while walking, jumping or running. (1963)

Virtual and physical training facilities have been integrated to familiarize astronauts with the conditions they will encounter during all phases of flight and prepare astronauts for a microgravity environment.[4] Special considerations must be made during training to ensure a safe and successful mission, which is why the Apollo astronauts received training for geology field work on the Lunar surface and why research is being conducted on best practices for future extended missions, such as the trip to Mars.

Purpose of training

Training flow

The selection and training of astronauts are integrated processes to ensure the crew members are qualified for space missions.[5] The training is categorized into five objectives to train the astronauts on the general and specific aspects: basic training, advanced training, mission-specific training, onboard training, and proficiency maintenance training.[6] The trainees must learn medicine, language, robotics and piloting, space system engineering, the organization of space systems, and the acronyms in aerospace engineering during the basic training. While 60% to 80% of the astronauts will experience space motion sickness, including pallor, cold sweating, vomiting, and anorexia,[7] the astronaut candidates are expected to overcome the sickness. During the advanced training and the mission specific training, astronauts will learn about the operation of specific systems and skills required associated with their assigned positions in a space mission. The mission specific training typically requires 18 months to complete for Space Shuttle and International Space Station crews.[6] It is important to ensure the astronauts’ well-being, physical and mental health prior, during, and after the mission period. Proficiency maintenance aims to help the crew members to maintain a minimum level of performance, including topics such as extravehicular activity, robotics, language, diving, and flight training.[6]

Launch and landing

The effects of launching and landing has various effects on astronauts, with the most significant effects that occur being space motion sickness,[7] orthostatic intolerance, and cardiovascular events.

Space motion sickness is an event that can occur within minutes of being in changing gravity environments (i.e. from 1g on Earth prior to launch to more than 1g during launch, and then from microgravity in space to hypergravity during re-entry and again to 1g after landing). The symptoms range from drowsiness and headaches, to nausea and vomiting. There are three general categories of space motion sickness:

  • Mild: One to several transient symptoms, no operational impact
  • Moderate: Several symptoms of persistent nature, minimal operational impact
  • Severe: Several symptoms of persistent nature, significant impact on performance

About three-fourths of astronauts experience space motion sickness, with effects rarely exceeding two days. There is a risk for post-flight motion sickness, however this is only significant following long-duration space missions.

Post-flight, following exposure to microgravity, the vestibular system, located in the inner ear is disrupted because of the microgravity-induced unresponsiveness of the otoliths which are small calcareous concretions that sense body postures and are responsible for ensuring proper balance. In most cases, this leads to some postflight postural illusions.

Cardiovascular events represent important factors during the three phases of a space mission. They can be divided in:

  • Pre-existing cardiovascular diseases: these are typically selected-out during astronaut selection, but if they are present in an astronaut they can worsen over the course of the spaceflight.
  • Cardiovascular events and changes occurring during spaceflight: these are due to body fluids shift and redistribution, heart rhythm disturbances and decrease in maximal exercise capacity in the micro gravity environment. These effects can potentially lead the crew to be severely incapacitated upon return to a gravitational environment and thus unable to egress a spacecraft without assistance.
  • Orthostatic intolerance leading to syncope during post-flight stand test.

On-orbit operations

Further information: Effect of spaceflight on the human body

Astronauts are trained in preparation for the conditions of launch as well as the harsh environment of space. This training aims to prepare the crew for events falling under two broad categories: events relating to operation of the spacecraft (internal events), and events relating to the space environment (external events)

 
An internal view of ESA's Columbus module training mockup, located at the European Astronaut Centre in Cologne, Germany. Astronauts must familiarize themselves with all the spacecraft components during their training.

During training, astronauts are familiarized with the engineering systems of the spacecraft including spacecraft propulsion, spacecraft thermal control, and life support systems. In addition to this, astronauts receive training in orbital mechanics, scientific experimentation, earth observation, and astronomy. This training is particularly important for missions when an astronaut will encounter multiple systems (for example on the International Space Station (ISS)). Training is performed in order to prepare astronauts for events that may pose a hazard to their health, the health of the crew, or the successful completion of the mission. These types of events may be: failure of a critical life support system, capsule depressurization, fire, and other life-threatening events. In addition to the need to train for hazardous events, astronauts will also need to train to ensure the successful completion of their mission. This could be in the form of training for EVA, scientific experimentation, or spacecraft piloting.

External events

External events refers more broadly to the ability to live and work in the extreme environment of space. This includes adaptation to microgravity (or weightlessness), isolation, confinement, and radiation. The difficulty associated with living and working in microgravity include spatial disorientation, motion sickness, and vertigo. During long-duration missions, astronauts will often experience isolation and confinement. This has been known to limit performance of astronaut crews and hence training aims to prepare astronauts for such challenges.[8] The long-term effects of radiation on crews is still largely unknown. However, it is theorized that astronauts on a trip to Mars will likely receive more than 1000x the radiation dosage of a typical person on earth.[9] As such, present and future training must incorporate systems and processes for protecting astronauts against radiation.

Science experiments

Scientific experimentation has historically been an important element of human spaceflight, and is the primary focus of the International Space Station. Training on how to successfully carry out these experiments is an important part of astronaut training, as it maximizes the scientific return of the mission. Once on-orbit, communication between astronauts and scientists on the ground can be limited, and time is strictly apportioned between different mission activities. It is vital that astronauts are familiar with their assigned experiments in order to complete them in a timely manner, with as little intervention from the ground as possible.

For missions to the ISS, each astronaut is required to become proficient at one hundred or more experiments. During training, the scientists responsible for the experiments do not have direct contact with the astronauts who will be carrying them out. Instead, scientists instruct trainers who in turn prepare the astronauts for carrying out the experiment. Much of this training is done at the European Astronaut Center.

For human experiments, the scientists describe their experiments to the astronauts who then choose whether to participate on board the ISS. For these experiments, the astronauts will be tested before, during, and after the mission to establish a baseline and determine when the astronaut returned to the baseline.

 
A researcher using VR headset to investigate ideas for controlling rovers on a planet.

Purpose of virtual-reality training

Virtual reality training for astronauts intends to give the astronauts candidates an immersive training experience. Virtual reality has been explored as a technology to artificially expose astronauts to space conditions and procedures prior to going into space. Using virtual reality, astronauts can be trained and evaluated on performing an EVA (extravehicular activity) with all the necessary equipment and environmental features simulated. This modern technology also allows the scenario to be changed on the go, such as to test emergency protocols.[10] The VR training systems can reduce the effects of the space motion sickness through a process of habituation. Preflight VR training can be a countermeasure for space motion sickness and disorientation due to the weightlessness of the microgravity environment.[11] When the goal is to act as a practice tool, virtual reality is commonly explored in conjunction with robotics and additional hardware to increase the effect of immersion or the engagement of the trainee.[12]

Training by region

United States

At NASA, following the selection phase, the so-called "AsCans" (Astronaut candidates) have to undergo up to two years of training/indoctrination period to become fully qualified astronauts. Initially, all AsCans must go through basic training to learn both technical and soft skills. There are 16 different technical courses in:

 
Astronauts train in the Neutral Buoyancy Facility at the Johnson Space Center in Houston, Texas
 
The Crew of STS-135 practices rendezvous and docking with the ISS in the Systems Engineering Simulator at the Johnson Space Center on June 28, 2011, in Houston, Texas.

AsCans initially go through Basic Training, where they are trained on Soyuz, and ISS systems, flight safety and operations, as well as land or water survival. Pilot AsCans will receive training on NASA's T-38 Trainer Jet. Furthermore, because modern space exploration is done by a consortium of different countries and is a very publicly visible area, astronauts received professional and cultural training, as well as language courses (specifically in Russian).[13]

Following completion of Basic Training candidates proceed to NASA's Advanced Training. AsCans are trained on life-sized models to get a feel of what they will be doing in space. This was done both through the use of the Shuttle Training Aircraft while it was still operational and is done through simulation mock-ups. The shuttle training aircraft was exclusively used by the commander and pilot astronauts for landing practices until the retirement of the Shuttle, while advanced simulation system facilities are used by all the candidates to learn how to work and successfully fulfill their tasks in the space environment. Simulators and EVA training facilities help candidates to best prepare their different mission operations. In particular, vacuum chambers, parabolic flights, and neutral buoyancy facilities (NBF) allow candidates to get acclimated to the micro gravity environment, particularly for EVA. Virtual reality is also becoming increasingly used as a tool to immerse AsCans into the space environment.[13][14]

The final phase is the Intensive Training. It starts at about three months prior to launch, preparing candidates for their assigned mission. Flight-specific integrated simulations are designed to provide a dynamic testing ground for mission rules and flight procedures. The final Intensive Training joint crew/flight controller training is carried out in parallel with mission planning. This phase is where candidates will undergo mission specific operational training, as well as experience with their assigned experiments. Crew medical officer training is also included to effectively intervene with proactive and reactive actions in case of medical issues.[13]

Notable training facilities

It can take up to two years for an AsCan to become formally qualified as an astronaut. Usually, the training process are completed with various training facilities available in NASA:[15] Space training facilities try to replicate or simulate the experience of spaceflight in a spacecraft as closely and realistically as possible. This includes full-size cockpit replicas mounted on hydraulic rams and controlled by state of the art computer technology; elaborate watertanks for simulation of weightlessness; and devices used by scientists to study the physics and environment of outer space.

  • Space Vehicle Mock-up Facility (SVMF): located in the Johnson Space Center in Houston, TX. The SVMF consists of life-size models of vehicles of the ISS, the Orion, and different other commercial programs. The purpose of SVMF is to provide a unique simulated experience for astronauts to get familiar with their tasks in space vehicles. Potential training projects include preparation of emergency, on-orbit intra-vehicular maintenance, and airlock operations. The facility also provides experiences for astronauts in real-time communications with the ground team for mission support.[16]
  • KC-135 Stratotanker: the KC-135 is an air-refueling plane designed by Boeing. Known as the “Weightless Wonder” or the “Vomit Comet”, this plane is the most famous of its kind, which has served to simulate reduced or microgravity environments for NASA astronauts since 1994. The “roller coaster” maneuvers that the plane is capable of doing provide people as well as equipment onboard about 20–25 seconds of weightlessness.[17]
  • The Precision Air-Bearing Floor (PABF): located in the Johnson Space Center in Houston, TX. Because of the microgravity environment in space, the resulting lack of friction posts difficulties for astronauts to move and stop large objects. The PABF is a “flat floor” that uses compressed air to suspend typical hardwares or mock-ups that astronauts may encounter in space above the ground. It is used to simulate low-friction environments for astronauts to learn to move large objects.[16]
  • The Neutral Buoyancy Lab: (NBL): located in the Johnson Space Center in Houston, TX. Through a combination of weighting and floating effects, the NBL creates a balance between the tendencies to sink and to float, and therefore simulating the experience of weightlessness. In the NBL, several full-size models of the space vehicles are present in a large “water tank”. Unlike the SVMF, the NBL helps astronauts train on projects such as maintenance, but outside of the space vehicle.[18]

Europe

Astronaut training in Europe is carried out by the European Astronaut Centre (EAC), headquartered in Cologne, Germany. European training has three phases: Basic training, Advanced training, and Increment Specific Training.

 
Soyuz capsule simulator located at the EAC in Cologne, Germany. ESA astronauts will simulate operations in the capsule at the EAC.

For all ESA selected astronauts, Basic Training begins at the EAC headquarters. This section of the training cycle has four separate training blocks that last 16 months. Astronauts will receive an orientation on the major spacefaring nations, their space agencies, and all major crewed and uncrewed space programs. Training in this phase also looks into applicable laws and policies of the space sector. Technical (including engineering, astrodynamics, propulsion, orbital mechanics, etc.) and scientific (including human physiology, biology, earth observation, and astronomy) basics are introduced, to ensure that all new astronauts have the required base level of knowledge. Training is done on ISS operations and facilities, including an introduction to all major operating systems on board the ISS that are required for its functionality as a crewed space research laboratory. This phase also covers in-depth systems operations for all spacecraft that service the ISS (e.g. Soyuz, Progress, Automatic Transfer Vehicle (ATV), and the H-II Transfer Vehicle (HTV)), as well as ground control and launch facility training. This training phase also focuses on skills such as robotic operations, rendezvous and docking, Russian language courses, human behavior and performance, and finally a PADI open water scuba diving course. This scuba course provides basic EVA training at ESA's NBF before moving onto the larger NASA training facility at the Lyndon B. Johnson Space Center.

Advanced Training includes a much more in-depth look into the ISS, including learning how to service and operate all systems. Enhanced science training is also implemented at this time to ensure all astronauts can perform science experiments on board the ISS. This phase takes around one year to complete and training is completed across the ISS partner network, no longer only at the EAC. It is only upon completion of this phase that astronauts are assignment to a spaceflight.

Increment-Specific Training starts only after an astronaut has been assigned to a flight. This phase lasts 18 months and prepares them for their role on their assigned mission. During this phase crew members as well as backup crews will train together. The crew tasks on the ISS are individually tailored, with consideration to the astronaut's particular experience and professional background. There are three different user levels for all on-board equipment (i.e. user level, operator level, and specialist level). A crew member can be a specialist on systems while also only being an operator or user on others, hence why the training program is individually tailored. Increment Specific Training also includes training to deal with off-nominal situations. Astronauts will also learn how to run the experiments that are specifically scheduled for their assigned missions.

Russia

 
The grounds of the Gagarin Cosmonauts Training Center

Training for cosmonauts falls into three phases: General Space Training, Group Training, and Crew Training.[19] General Space Training lasts about two years and consists of classes, survival training, and a final exam which determines whether a cosmonaut will be a test or research cosmonaut. The next year is devoted to Group Training where cosmonauts specialize in the Soyuz or ISS as well as professional skills. The final phases, the Crew Training phase, lasts a year and a half and is dedicated to detailed vehicle operations procedures, ISS training, and the English language.

Training primarily takes place at the Yuri Gagarin Cosmonaut Training Center. The center facilities have full size mockups of all major Soviet and Russian spacecraft including the ISS. As with the ISS astronauts, cosmonauts train in the US, Germany, Japan, and Canada for specific training in the various ISS modules.

Japan

The Japanese human spaceflight program has historically focused on training astronauts for Space Shuttle missions. As such, training previously took place at NASA's Lyndon B. Johnson Space Center, and followed that of NASA astronauts and other international participants in the Space Shuttle program.

 
H-II rocket outside the Tsukuba Space Center where training of JAXA astronauts takes place

Since the development of domestic training facilities at the Tsukuba Space Center, training has increasingly taken place in Japan. With Japan's participation in the ISS, the training of Japanese astronauts follows a similar structure to that of other ISS partners. Astronauts carry out 1.5 years of Basic Training mainly at Tsukuba, followed by 1.5–2 years of Advanced Training at Tsukuba and ISS partner sites. Training for any international ISS astronauts involving the Kibo module will also be carried out at Tsukuba Space Center.[20]

Advanced Training is followed by Increment-Specific Training, which, along with any Kibo training, will be carried out at Tsukuba. EVA training for Kibo takes place in the Weightless Environment Test System (WETS). WETS is a Neutral Buoyancy Facility featuring a full-scale mock-up of the Kibo module on the ISS.[21] The Tsukuba Space Center also includes medical facilities for assessing suitability of candidates, an isolation chamber for simulating some of the mental and emotional stressors of long duration spaceflight, and a hypobaric chamber for training in hull breach or Life Support System failure scenarios resulting in a reduction or loss of air pressure.[22]

China

Although official detail of the selection process for the Shenzhou program is not available, what is known is that candidates are chosen by the Chinese National Space Administration from the Chinese air force and must be between 25 and 30 years of age, with a minimum of 800 hours flying time, and a degree-level education. Candidates must be between 160 cm and 172 cm in height, and between 50 kg and 70 kg in weight.[23]

For China's Shenzhou astronauts, training begins with a year-long program of education in the basics of spaceflight. During this period, candidates are also introduced to human physiology and psychology. The second phase of training, lasting nearly 3 years involves extensive training in piloting the Shenzhou vehicle in nominal and emergency modes. The third and final stage of training is mission specific training, and lasts approximately 10 months. During this phase of training, astronauts are trained in the high fidelity Shenzhou trainer, as well as the Neutral Buoyancy Facility located at the Astronaut Center of China (ACC), in Beijing. As well as time spent in the Neutral Buoyancy Facility (NBF), training for EVA takes place in a high vacuum, low temperature chamber that simulates the environmental conditions of space. At all stages of training, astronauts undergo physical conditioning, including time in a human centrifuge located at the ACC, and a program of micro gravity flights, carried out in Russia.[24]

India

The Indian human space flight program still awaits a formal go ahead. Once cleared the mission is expected to take two Indians in a Soyuz-type orbital vehicle into low Earth orbit. The training for these astronauts should be based on the lessons learned from training India's only Cosmonaut Wing Commander Rakesh Sharma (See Salyut-7 1984) and through India's international co-operation with NASA and Roscosmos. This would allow India to gain insights from their rich experiences in human spaceflight. There also lies a possibility that India may go proceed through its human spaceflight program individually, necessitating the Indian Space Research Organisation (ISRO) to develop its own training program. For astronaut training, India is deciding a place which is at a distance of 8 to 10 km from Kempegowda international airport. This land is under the ownership of ISRO. Astronaut training and biomedical engineering centers will be built on it. Though India's first man mission training will take place in USA or in Russia, this place can be used for future training. Moreover, center will have chambers for radiation regulation, thermal cycling and centrifugal for the acceleration training.[25]

Future training

Suborbital astronaut training

 
Ecuadorian Civilian Space Agency (EXA)

While the first generation of non-government spaceflight astronauts will likely perform suborbital trajectories, currently companies like Virgin Galactic and Xcor Aerospace are developing proprietary suborbital astronaut training programs. However, the first official Suborbital Astronaut Training program was a joint effort between two government agencies. The Ecuadorian Air Force and the Gagarin Cosmonaut Training Center[26] developed the ASA/T (Advanced Suborbital Astronaut Training) program which lasted up to 16 months between 2005 and 2007 and focused on command and research duties during short missions with suborbital trajectories up to 180 kilometers. This program had one Ecuadorian citizen graduate in 2007,[27][28][29] the Ecuadorian Space Agency made a call[30] for a new class of ASA/T training candidates, accordingly to the EXA, they will focus on renting commercial suborbital vehicles in order to perform crewed space research[31]

Commercial astronauts

 
Human centrifuge at DLR in Cologne, Germany used for human physiological tests. The high accelerations experienced during suborbital flights may necessitate testing or even training on human centrifuges to determine if participants are fit for space flight

Looking ahead, the emergence of commercial space tourism will necessitate new standards for flight participants that currently do not exist. These standards will be to ensure that medical screenings are done properly in order to ensure safe and successful flights. This process will differ from that for space agency astronauts because the goal is not to fly the best individual, but to ensure a safe flight for the passengers. The main considerations for this type of travel will be:

  • What type and extent of training is sufficient?
  • Who will qualify space tourists as fit for travel?
  • How will new regulations comply with existing medical boards?
  • What selection-out criteria need to be employed to reduce dangers to space tourists?

Medical regulations for commercial space flight might mitigate commercial space company risk by selecting only those capable of passing standard medical criteria, as opposed to allowing anyone who can purchase a ticket to fly. The first generation of commercial space flight will likely be suborbital trajectories which invoke significant acceleration changes, causing cardiovascular and pulmonary issues. Because of this any future medical criteria for commercial spaceflight participants needs to focus specifically on the detrimental effects of rapidly changing gravitational levels, and which individuals will be capable of tolerating this.

A fundamentals of scientist-astronaut formative program along with additional Bioastronautics, Extravehicular activity, Space Flight Operations, Flight Test Engineering and Upper-Atmospheric Research courses have been conducted by Project PoSSUM scientist-astronaut candidates since 2015.[32][33] As of January 2021, the program has attracted members from 46 different countries and published research on mesospheric dynamics, human performance in space suits, microgravity research in various fields, and post-landing environments. The programs are run by the International Institute of Astronautical Sciences that has also partnered with Embry-Riddle Aeronautical University, Final Frontier Design Spacesuits, Survival Systems USA, National Research Council of Canada, Canadian Space Agency and the National Association of Underwater Instructors.

Current research on fitness training and strategies for commercial astronauts conducted by Astrowright Spaceflight Consulting, the first commercial firm to offer dedicated fitness training for space tourists, suggests that conventional fitness training is inadequate to support safe movement in microgravity, and that training utilizing reduced points of stability should be emphasized.[34]

Long-duration missions to the Moon or Mars

 
Astronaut during virtual reality training

Astronauts for long-term missions–such as those to the Moon or Mars–need to carry out multiple tasks and duties, because on such missions the astronauts will need to function largely autonomously, and will need to be proficient in many different areas. For these types of missions, the training to prepare astronauts will likely include training as doctors, scientists, engineers, technicians, pilots, and geologists. In addition there will be a focus on the psychological aspects of long-duration missions where crew is largely isolated.[35]

Currently a six-month mission to the ISS requires up to five years of astronaut training. This level of training is to be expected and likely to be expanded upon for future space exploration missions. It may also include in-flight training aspects. It may be possible that the ISS will be used as a long-duration astronaut training facility in the future.

A powerful tool for astronaut training will be the continuing use of analog environments, including NASA Extreme Environment Mission Operations (NOAA NEEMO), NASA's Desert Research and Technology Studies (Desert RATS), Envihab (planned), Flight Analog Research Unit, Haughton-Mars Project (HMP), or even the ISS (in-flight). In fact, at NEEMO a total of 15 mission astronauts (known as aquanauts) have been trained for future missions to asteroids.[36] The use of virtual reality will also continue to be used as a means of training astronauts in a cost-effective manner, particularly for operations such as extra-vehicular activity (EVA).

 
Robonaut2 onboard ISS

These missions are not completely independent without the presence of robots. This opens up a new avenue towards Human-Robot Interaction which has to be thoroughly understood and practised to develop a harmonious relationship between astronauts and robots. These robots would aid the astronauts from being their personal assistants to next generation of extreme environment explorers. Currently there is a robot on the ISS aiding the astronauts in their mammoth tasks with a human touch. Intercultural and human robot interaction training is the need of the hour for long duration missions.

Training also has to be evolved for future Moon landings to a human mission to Mars. Factors like crew dynamics, crew size, and crew activities play a crucial role as these missions would last from one year to Moon to three years on Mars. The training required for such missions has to be versatile and easy to learn, adapt, and improvise.

A journey to Mars will require astronauts to remain in the crew capsule for nine months.[37] The monotony and isolation of the journey present new psychological challenges. The long period spent in the crew capsule is comparable to other forms of solitary confinement, such as in submarines or Antarctic bases. Being in an isolated and confined environment generates stress, interpersonal conflict, and other behavioral and mental problems.[38] However, natural scenery and communication with loved ones has shown to relax and lessen these effects. A Network of Social Interactions for Bilateral Life Enhancement (ANSIBLE), which provides natural scenery and socialization in a virtual reality environment, is being researched as a solution to behavioral health.[39]

Researchers are looking into how current mental health tools can be adjusted to help the crew face stressors that will arise in an isolated, confined environment (ICE) during extended missions.[40] The International Space Station uses a behavioral conflict management system known as the Virtual Space Station (VSS) to minimize conflict between crew members and address psychological challenges.[41] The program has modules that focus on relationship management, stress and depression that guide astronaut's through a virtual therapy session in space.[40]

Virtual reality astronaut training

History

Virtual reality technologies first came to a commercial release in the 1990s. It is not until then did people realize that VR can be used in training astronauts. The earlier VR gears for astronaut training are dedicated to enhance the communication between robot arm operators and the astronaut during Extravehicular Activities (EVA). It brings EVA crew members and robot arm operators together, in live, even when they are on board a spacecraft.[42] It is also used to replace some of the oversized models that cannot fit in the Neutral Buoyancy Lab (NBL).

In 1993, astronauts were trained and evaluated on working on the Hubble Space Telescope through a virtual reality training tool, Research in Human Factors Aspects of Enhanced Virtual Environments for EVA Training and Simulation (RAVEN). However, the aim of RAVEN was not to train astronauts but to evaluate the efficacy of training using virtual reality versus underwater and other setup.[43]

Through the years of technological development in VR, the hardware for the VR Lab in NASA has also significantly improved. Both the material and the resolution of the display are being renovated:[42]

  • 1991: Liquid-Crystal Display (LCD) - 320x420
  • 1992: Cathode Ray Tube (CRT) - 1280x1024
  • 2005: Micro Organic Light-Emitting Diode (micro-OLED) - 800x600
  • 2012: LCD - 1280x720
  • 2015: OLED - 1920x1080

Virtual reality has also been adopted to a much wider range of fields in space exploration throughout the history of technology renovation. The newer applications of VR include but are not limited to:[44]

  • Mission planning
  • Cooperative and interactive designing
  • Engineering problem-solving
  • Data modeling
 
Astronauts Tom Marshburn, left, and Dave Wolf train for a spacewalk in the Integrated EVA-RMS Virtual Reality Simulator Facility at Johnson Space Center

Current virtual reality training

While the extravehicular activities (EVAs) training facility can simulate the space conditions, including pressure and lighting, the Micro-g environment cannot be fully reconstructed in the Earth's 1-G environment.[45] Virtual reality is utilized during EVA training to increase the immersion of the training process. NASA Johnson Space Center has facilities such as the Space Vehicle Mockup Facility (SVMF), Virtual Reality Laboratory (VRL), and Neutral Buoyancy Laboratory (NBL).

The SVMF uses the Partial Gravity Simulator (PGS) and air bearing floor (PABF) to simulate the zero-gravity and the effects of Newton's laws of motion.[46] Similar training systems originated from the Apollo and Gemini training. Virtual reality enhances an astronaut's senses during training modules like fluid quick disconnect operations, spacewalks, and the orbiter's Space Shuttle thermal protection system (TPS) repairs.[46]

NASA Virtual Reality Laboratory utilizes virtual reality to supplement the Simplified Aid For EVA Rescue (SAFER) as simplified aid. The VR training offers a graphical 3-dimensional simulation of the International Space Station (ISS) with a headset, haptic feedback gloves, and motion tracker.[47] In 2018, two Expedition 55 astronauts Richard R. Arnold and Andrew J. Feustel, received virtual reality training and performed the 210th spacewalk.[48] The Virtual Reality Laboratory offers astronauts an immersive VR experience for spacewalks before launching into space. The training process combines a graphical rendering program that replicates the ISS and a device called the Charlotte Robot that allows astronauts to visually explore their surroundings while interacting with an object.  The Charlotte robot is a simple device with a metal arm attached to the side that allows a user to interact with the device. The user wears haptic feedback gloves with force sensors that send signals to a central computer.[49] In response, the central computer maneuvers the device using a web of cables and calculates how it would act in space through physics.[50] While objects are weightless in space, an astronaut has to be familiar with an object's forces of inertia and understand how the object will respond to simple motions to avoid losing it in space.[49][51] Training can be completed individually or with a partner. This allows astronauts to learn how to interact with mass and moments of inertia in a microgravity environment.[50]

The Neutral Buoyancy Laboratory (NBL) has advantages in simulating a zero-gravity environment and reproducing the sensation of floating in space. The training method is achieved by constructing a low gravity environment through Maintaining the Natural buoyancy in one of the largest pools in the world. The NBL pool used to practice extravehicular activities or spacewalks is 62 meters (202 feet) long, 31 meters (102 feet) wide, and 12 meters (40 feet) deep,[15] with a capacity of 6.2 million gallons.[52] Underwater head-mounted display virtual reality headset is used to provide visual information during the training with a frame rate of 60 fps and screen resolution of 1280 by 1440.[52] The underwater VR training system has a reduced training cost because of the accessibility of the VR applications, and astronauts need less time to complete the assigned practice task.

Despite the NASA training modules, commercial spaceflight training also uses virtual reality technology to improve their training systems. Boeing's virtual reality team develops a training system for Boeing Starliner to train astronauts to transport between the Earth and the ISS. The VR training system can simulate high-speed situations and emergency scenarios, for instance, launching, entering the space, and landing at an unexpected location.[53]

Advantages of virtual reality training

Visual reorientation is a phenomenon that happens when the perception of an object changes because of the changing visual field and cues.[54] This illusion will alter the astronaut's perception of the orienting force of gravity and then lose spatial direction. The astronauts must develop good spatial awareness and orientation to overcome visual reorientation. In the traditional disorientation training, for instance, the Yuri Gagarin Cosmonaut Training Center trains the astronaut by simulating a microgravity environment through a centrifuge.[6] In contrast, VR training requires less gear, training the astronauts more economically.

Virtual reality training utilizes the mix-realistic interaction devices, such as cockpits in flight simulators can reduce the simulation sickness and increase user movement.[55] Compared to traditional training, VR training performs better to minimize the effects of space motion sickness and spatial disorientation. Astronauts who received VR training can perform the task 12% faster, with a 53% decrease in nausea symptoms.[11]

While VR is used in astronaut training on the ground, immersive technology also contributes to on-orbit training.[56] VR head-mounted display can help the astronaut maintain physical well-being as part of proficiency maintenance training.[6][56] Moreover, VR systems are used to ensure the mental health of the crewmembers. The simulations of social scenarios can mitigate the stress and establish the connectedness under the isolated and confined environment (ICE).[56]

Virtual reality acclimates astronauts to environments in space such as the International Space Station before leaving earth. While astronauts can familiarize themselves with the ISS during training in the NBL, they are only able to see certain sections of the station. While it prepares astronauts for the tasks they are performing in space, it does not necessarily give them a full spatial understanding of the station's layout. That's where Virtual Reality plays an important role. The Virtual Reality Lab uses a system known as the Dynamic Onboard Ubiquitous Graphics program (DOUG) to model the ISS's exterior including decals, fluid lines, and electrical lines, so that the crew can acclimate to their new environment.[49] The level of detail goes beyond the exterior of the station. When a user enters space, they see pure black until their pupil's dilate and the sky fills with stars in an occurrence called the ‘blooming effect’.[57]

Disadvantages of virtual reality training

While virtual reality prepares astronauts for the unfamiliar tasks they will face in outer space, the training is unable to replicate the psychological and emotional stress that astronauts face on a daily basis. This is because virtual tasks do not hold the same repercussions as the real task and the technology does not produce strong psychological effects, like claustrophobia, that often occurs in enclosed environments.[58]

Stimulating a virtual microgravity environment can be costly due to additional equipment requirements. Unlike commercialized virtual reality, the equipment that NASA uses cannot be produced at a large scale because the systems require supplemental technology.[40] Several VR programs work in combination with the Neutral Buoyancy Lab or the Charlotte Robot in the Virtual Reality Lab which requires expensive facilities and does not eliminate the travel component that VR can minimize.[59] NASA's Charlotte robot is restricted by cables that simulate the microgravity environment and the Virtual Reality Lab only has two machines in their possession.[49] This particular training system requires a virtual glovebox system (GVX) that has been incorporated into training at NASA and the EVA virtual system at the Astronaut Center of China.[60] Using sensors embedded in the fabric, the gloves can sense when the wearer  decides to  grasp an object or release it, but the technology needs to be further developed to integrate precise user movements into virtual programs.[50] These gloves have been reported to be uncomfortable and only capture limited movements.[58] Full-body motion sensors have also been incorporated into training and tend to be expensive but necessary in order to have effective tactile feedback in response to the astronauts movements. While virtual reality programs have been developed that do not require full-body sensors, the absence reduces the degree to which a user can interact with the virtual world.[58]

Future

The primary focus of future research of virtual reality technologies in space exploration is to develop a method of simulating a microgravity environment. Although it has been a goal since the beginning of VR being used in astronaut training, minor progress has been made. The current setup uses a bungee rope attached to a person's feet, a swing attached to the body, and finally a head mounted VR display.[61][62] However, from participants in experiments that use this setup to simulate reduced gravity environments, they only experience the feel of moving around in space with the help of VR, but the experience does not resemble a real zero-gravity environment in outer space. Specifically, the pressure from the bungee rope and the swing because of the participants’ own weight creates an unreal and unpleasant feeling.[61] The current technology may be enough for the general public to experience what moving around in space is like, but it is still far from being formally used as an astronaut training tool.

These efforts of simulating micro-gravity serve a similar purpose of creating an increasingly immersive environment for astronaut training. In fact, this is a developing trend for the entire VR industry. The ultimate scene VR experience that we are imagining will eventually be marked by the elimination between the real and the virtual world.  

See also

References

  1. ^ Lewis, Robert (2017-12-08). "Medical Examination Requirements (MER) for Former Astronauts". NASA. Retrieved 2020-08-01.
  2. ^ Kale, Sneha R; Master, Hiral S; Verma, Chhaya V; Shetye, Jaimala; Surkar, Swati; Mehta, Amita (2013). "Exercise Training for Astronauts". Indian Journal of Physiotherapy and Occupational Therapy. 7 (2): 82. doi:10.5958/j.0973-5674.7.2.017.
  3. ^ Oddsson, Lars IE; Karlsson, Robin; Konrad, Janusz; Ince, Serdar; Williams, Steve R; Zemkova, Erika (December 2007). "A rehabilitation tool for functional balance using altered gravity and virtual reality". Journal of NeuroEngineering and Rehabilitation. 4 (1): 25. doi:10.1186/1743-0003-4-25. PMC 1936992. PMID 17623080.
  4. ^ "NASA, Space Science, and Western Europe". NASA in the World. 2013. doi:10.1057/9781137340931.0010. ISBN 978-1-137-34093-1.
  5. ^ Sgobba, Tommaso; Landon, Lauren B.; Marciacq, Jean-Bruno; Groen, Eric; Tikhonov, Nikolai; Torchia, Francesco (2018). "Selection and training". Space Safety and Human Performance. pp. 721–793. doi:10.1016/B978-0-08-101869-9.00016-9. ISBN 978-0-08-101869-9.
  6. ^ a b c d e Marciacq, Jean-Bruno; Bessone, Loredana (2009). "Crew Training Safety". Safety Design for Space Systems. pp. 745–815. doi:10.1016/B978-0-7506-8580-1.00025-7. ISBN 978-0-7506-8580-1.
  7. ^ a b Heer, Martina; Paloski, William H. (October 2006). "Space motion sickness: Incidence, etiology, and countermeasures". Autonomic Neuroscience. 129 (1–2): 77–79. doi:10.1016/j.autneu.2006.07.014. PMID 16935570. S2CID 6520556.
  8. ^ NASA. Long Duration Psychology. [online]. [Accessed 20 February 2012]. Available from World Wide Web: <https://history.nasa.gov/SP-4225/long-duration/long.htm>
  9. ^ DURANTE, M and FA CUCINOTTA. 2008. Heavy Ion Carcinogenesis and Human Space Exploration. Nature Rev Cancer, 2 May, pp.465-472.
  10. ^ Olbrich, Manuel; Graf, Holger; Keil, Jens; Gad, Rüdiger; Bamfaste, Steffen; Nicolini, Frank (2018). "Virtual Reality Based Space Operations – A Study of ESA's Potential for VR Based Training and Simulation". Virtual, Augmented and Mixed Reality: Interaction, Navigation, Visualization, Embodiment, and Simulation. Lecture Notes in Computer Science. Vol. 10909. pp. 438–451. doi:10.1007/978-3-319-91581-4_33. ISBN 978-3-319-91580-7.
  11. ^ a b Stroud, Kenneth J.; Harm, Deborah L.; Klaus, David M. (1 April 2005). "Preflight Virtual Reality Training as a Countermeasure for Space Motion Sickness and Disorientation". Aviation, Space, and Environmental Medicine. 76 (4): 352–356. PMID 15828634.
  12. ^ Menon, Anil S.; Barnes, Bobby; Mills, Rose; Bruyns, Cynthia D.; Twombly, Alexander; Smith, Jeff; Montgomery, Kevin; Boyle, Richard (2003). Using registration, calibration, and robotics to build a more accurate virtual reality simulation for astronaut training and telemedicine. UNION Agency. pp. 87–94. ISBN 978-80-903100-1-8.
  13. ^ a b c SEEDHOUSE, Erik. 2010. Prepare for Launch: The Astronaut Training Process. New York City, NY: Springer
  14. ^ NASA. 2004. Astronauts in Training. [online]. [Accessed 20 February 2012]. Available from World Wide Web: <http://www.nasa.gov/audience/forstudents/5-8/features/F_Astronauts_in_Training.html>
  15. ^ a b Logan, Barry. "NASA - Astronauts in Training". www.nasa.gov. Retrieved 2020-07-29.
  16. ^ a b "Space Vehicle Mockup Facility (SVMF)" (PDF). NASA. FS-2013-05-011-JSC.
  17. ^ McDonald-, Terry. "NASA - Zero-Gravity Plane on Final Flight". www.nasa.gov. Retrieved 2020-07-29.
  18. ^ "Sonny Carter Training Facility: The Neutral Buoyancy Laboratory" (PDF). NASA. FS-2006-11-026-JSC.
  19. ^ . Archived from the original on 2020-07-26. Retrieved 2012-02-26.
  20. ^ JAXA. 2011. Basic Training for International Space Station Astronaut Candidates. [online]. [Accessed 25 February 2012]. Available from World Wide Web: <http://iss.jaxa.jp/astro/ascan/ascan01_e.html >
  21. ^ JAXA. 2012. Tsukuba Space Center Overview. [online]. [Accessed 25 February 2012]. Available from World Wide Web: <http://www.jaxa.jp/about/centers/tksc/index_e.html>
  22. ^ ESA. 2008. Cercasi.astronauti. [online]. [Accessed 20 February 2012]. Available from World Wide Web: <http://www.esa.int/esaKIDSit/SEMGY11YUFF_LifeinSpace_1.html>
  23. ^ SINO DEFENSE. 2011. Chinese Astronaut Corps. [online]. [Accessed 25 February 2012]. Available from World Wide Web: <. Archived from the original on 2012-01-26. Retrieved 2012-02-26.>
  24. ^ MORRING, F. 2009. Astronaut Training. Aviation Week and Space Technology, pp.48-49.
  25. ^ "India says it will send a human to space by 2022". The Planetary Society.
  26. ^ Ecuadorian Air Force Official document on ASA/T program.
  27. ^ Ecuadorian Air Force presented with ASA/T program completion brief. <http://www.exa.ec/bp8/>
  28. ^ Ecuadorian Air Force presented with space program brief. <http://www.exa.ec/bp9/>
  29. ^ IAF EXA entry: Ecuadorian Space Agency. [online]. [Accessed October 1, 2015]. Available from World Wide Web: <http://www.iafastro.org/societes/ecuadorian-civilian-space-agency-exa/>
  30. ^ EXA call for astronaut candidates. [online]. [Accessed October 1, 2015]. <http://www.exa.ec/bp61/index.html>
  31. ^ Ecuadorian Space Program Manned Space Research - 61st International Astronautical Congress 2010 - HUMAN SPACE ENDEAVOURS SYMPOSIUM (B3)Overview Session (Present and Near-Term Human Space Flight Programs) (1). <https://www.academia.edu/771672/THE_ECUADORIAN_CIVILIAN_SPACE_PROGRAM_NEAR-FUTURE_MANNED_RESEARCH_MISSIONS_IN_A_LOW_COST_ENTRY_LEVEL_SPACE_PROGRAM>
  32. ^ SEEDHOUSE, Erik. 2016. XCOR, Developing the Next Generation Spaceplane. New York City, NY: Springer
  33. ^ SEEDHOUSE, Erik. 2015. Virgin Galactic: The First Ten Years. New York City, NY: Springer
  34. ^ MCGEE, B.W. et al. 2012. A Qualitative Assessment of Preflight Fitness Training Strategies and Methods [online]. [Accessed 29 May 2013]. Available from World Wide Web: <http://www.boulder.swri.edu/NSRC2012/Site1//PDF/McGee-O.pdf>
  35. ^ Kelly, Scott (2017). Endurance: A Year in Space, a Lifetime of Discovery. With Margaret Lazarus Dean. Alfred A. Knopf, a division of Penguin Random House. p. 50. ISBN 9781524731595. Unlike the early days of spaceflight, when piloting skill was what mattered, twenty-first-century astronauts are chosen for our ability to perform a lot of different jobs and to get along well with others, especially in stressful and cramped circumstances for long periods of time.
  36. ^ MOSKOWITZ, Clara. 2011. Astronauts Set to Become Aquanauts for Undersea 'Asteroid' Mission. [online]. [Accessed 26 February 2012]. Available from World Wide Web: <http://www.space.com/13007-nasa-astronauts-undersea-asteroid-mission.html>
  37. ^ Redd, Nola (14 November 2017). "How Long Does It Take to Get to Mars?". Space.com. Retrieved 2020-07-30.
  38. ^ Anderson, Allison; Mayer, Michael; Fellows, Abigail; Cowan, Devin; Hegel, Mark; Buckey, Jay (2017-06-01). "Relaxation with Immersive Natural Scenes Presented Using Virtual Reality". Aerospace Medicine and Human Performance. 88 (6): 520–526. doi:10.3357/AMHP.4747.2017. PMID 28539139 – via Research Gate.
  39. ^ Wu, Peggy; Morie, Jacquelyn; Chance, Eric; Haynes, Kip; Hamell, Joshua; Wall, Peter; Ladwig, Jack; Ott, Tammy (2015-04-12). "Maintaining Psycho-Social Health on the Way to Mars and Back". Proceedings of the 2015 Virtual Reality International Conference on ZZZ - VRIC '15. pp. 1–7. doi:10.1145/2806173.2806174. ISBN 9781450333139. S2CID 18919540.
  40. ^ a b c Anderson, Allison P.; Fellows, Abigail M.; Binsted, Kim A.; Hegel, Mark T.; Buckey, Jay C. (November 2016). "Autonomous, Computer-Based Behavioral Health Countermeasure Evaluation at HI-SEAS Mars Analog". Aerospace Medicine and Human Performance. 87 (11): 912–920. doi:10.3357/AMHP.4676.2016. PMID 27779949.
  41. ^ "Can Virtual Reality Help Astronauts Keep Their Cool?". Discover Magazine. Retrieved 2020-07-31.
  42. ^ a b Carson, Erin (September 17, 2015). "NASA shows the world its 20-year virtual reality experiment to train astronauts: The inside story". TechRepublic. Retrieved 2020-07-29.
  43. ^ Cater, John P.; Huffman, Stephen D. (1995-01-01). "Use of the Remote Access Virtual Environment Network (RAVEN) for Coordinated IVA—EVA Astronaut Training and Evaluation". Presence: Teleoperators and Virtual Environments. 4 (2): 103–109. doi:10.1162/pres.1995.4.2.103. PMID 11539288. S2CID 29308501.
  44. ^ Sternstein, Aliya (11 September 2006). "Astronauts to board virtual reality video game". Federal Computer Week. 20 (31): 58–59. ProQuest 218869004.
  45. ^ Thuot, Pierre J.; Harbaugh, Gregory J. (July 1995). "Extravehicular activity training and hardware design consideration". Acta Astronautica. 36 (1): 13–26. Bibcode:1995AcAau..36...13T. doi:10.1016/0094-5765(95)00035-X. PMID 11541312.
  46. ^ a b Moore, Sandra K.; Gast, Matthew A. (October 2010). "21st Century extravehicular activities: Synergizing past and present training methods for future spacewalking success". Acta Astronautica. 67 (7–8): 739–752. Bibcode:2010AcAau..67..739M. doi:10.1016/j.actaastro.2010.06.016. hdl:2060/20090034232.
  47. ^ "NASA is Using Virtual Reality to Train Astronauts". Unimersiv. 2016-04-11. Retrieved 2020-07-29.
  48. ^ "Virtual Reality Training and Global Robotics Work Before Spacewalk – Space Station". blogs.nasa.gov. Retrieved 2020-07-29.
  49. ^ a b c d "The NASA Playground That Takes Virtual Reality To a Whole New Level". Gizmodo. 16 June 2015. Retrieved 2020-07-31.
  50. ^ a b c "NASA is Using Virtual Reality to Train Astronauts". Unimersiv. 2016-04-11. Retrieved 2020-07-31.
  51. ^ Wang, Lan; Lin, Lingjie; Chang, Ying; Song, Da (December 2020). "Velocity Planning for Astronaut Virtual Training Robot with High-Order Dynamic Constraints". Robotica. 38 (12): 2121–2137. doi:10.1017/S0263574719001863. S2CID 213630797.
  52. ^ a b Sinnott, Christian; Liu, James; Matera, Courtney; Halow, Savannah; Jones, Ann; Moroz, Matthew; Mulligan, Jeffrey; Crognale, Michael; Folmer, Eelke; MacNeilage, Paul (November 2019). "Underwater Virtual Reality System for Neutral Buoyancy Training: Development and Evaluation" (PDF). NASA.
  53. ^ "Varjo & Boeing Starliner: A New Era in Astronaut Training". Varjo.com. Retrieved 2020-07-29.
  54. ^ Wilson, Christopher J.; Soranzo, Alessandro (2015-08-03). "The Use of Virtual Reality in Psychology: A Case Study in Visual Perception". Computational and Mathematical Methods in Medicine. 2015: 151702. doi:10.1155/2015/151702. PMC 4538594. PMID 26339281.
  55. ^ Rönkkö, Jukka; Markkanen, Jussi; Launonen, Raimo; Ferrino, Marinella; Gaia, Enrico; Basso, Valter; Patel, Harshada; D’Cruz, Mirabelle; Laukkanen, Seppo (March 2006). "Multimodal astronaut virtual training prototype". International Journal of Human-Computer Studies. 64 (3): 182–191. doi:10.1016/j.ijhcs.2005.08.004.
  56. ^ a b c Salamon, Nick; Grimm, Jonathan M.; Horack, John M.; Newton, Elizabeth K. (May 2018). "Application of virtual reality for crew mental health in extended-duration space missions". Acta Astronautica. 146: 117–122. Bibcode:2018AcAau.146..117S. doi:10.1016/j.actaastro.2018.02.034.
  57. ^ "NASA trains astronauts with zero-G virtual reality". Engadget. Retrieved 2020-07-31.
  58. ^ a b c Baughman, Alex (2020). Evaluation of Virtual and Hybrid Reality Systems for Astronaut Training (Thesis). ProQuest 2418705802.
  59. ^ Machkovech, Sam (2016-03-13). "Ars tests NASA's first Vive VR experiments: ISS, lunar rover simulators". Ars Technica. Retrieved 2020-07-31.
  60. ^ Qingchao, Xie; Jiangang, Chao (March 2017). "The Application of Leap Motion in Astronaut Virtual Training". IOP Conference Series: Materials Science and Engineering. 187 (1): 012015. Bibcode:2017MS&E..187a2015Q. doi:10.1088/1757-899x/187/1/012015. S2CID 113777872.
  61. ^ a b Lindsey, Patrica F. (October 1994). "Development of microgravity, full body functional reach envelope using 3-D computer graphic models and virtual reality technology". NASA Technical Reports.
  62. ^ Tamaddon, Kiarash; Stiefs, Dirk (2017). "Embodied experiment of levitation in microgravity in a simulated virtual reality environment for science learning". 2017 IEEE Virtual Reality Workshop on K-12 Embodied Learning through Virtual & Augmented Reality (KELVAR). pp. 1–5. doi:10.1109/KELVAR.2017.7961560. ISBN 978-1-5386-1892-9. S2CID 24280241.

Further reading

  • Baratt, Michael (May 1, 2008), Principles of Clinical Medicine for Space Flight, Springer, ISBN 978-0-387-98842-9
  • Clément, Gilles (April 25, 2005), Fundamentals of Space Medicine, Space Technology Library, ISBN 978-1-4020-3246-2
  • Kanas, Nick (September 30, 2003), Space Psychology and Psychiatry, Space Technology Library, ISBN 978-1-4020-1341-6
  • Seedhouse, Erik (April 13, 2010), Prepare for Launch: The Astronaut Training Process, Springer Praxis Books / Space Exploration, ISBN 978-1-4419-1349-4

External links

  • NASA Astronauts
  • CSA Astronauts
  • ESA Astronauts
  • JAXA Astronauts
  • Roscosmos 2012-10-16 at the Wayback Machine
  • List of experiments in International Space Station
  • ISRO Human Spaceflight
  • Train Like An Astronaut

January 14, 2023
astronaut, training, describes, complex, process, preparing, astronauts, regions, around, world, their, space, missions, before, during, after, flight, which, includes, medical, tests, physical, training, extra, vehicular, activity, training, procedure, traini. Astronaut training describes the complex process of preparing astronauts in regions around the world for their space missions before during and after the flight which includes medical tests 1 physical training 2 extra vehicular activity EVA training procedure training rehabilitation process 3 as well as training on experiments they will accomplish during their stay in space A test subject being suited up for studies on the Reduced Gravity Walking Simulator This position meant that a person s legs experienced only one sixth of their weight which was the equivalent of being on the lunar surface The purpose of this simulator was to study the subject while walking jumping or running 1963 Virtual and physical training facilities have been integrated to familiarize astronauts with the conditions they will encounter during all phases of flight and prepare astronauts for a microgravity environment 4 Special considerations must be made during training to ensure a safe and successful mission which is why the Apollo astronauts received training for geology field work on the Lunar surface and why research is being conducted on best practices for future extended missions such as the trip to Mars Contents 1 Purpose of training 1 1 Training flow 1 2 Launch and landing 1 3 On orbit operations 1 3 1 External events 1 4 Science experiments 1 5 Purpose of virtual reality training 2 Training by region 2 1 United States 2 1 1 Notable training facilities 2 2 Europe 2 3 Russia 2 4 Japan 2 5 China 2 6 India 3 Future training 3 1 Suborbital astronaut training 3 2 Commercial astronauts 3 3 Long duration missions to the Moon or Mars 4 Virtual reality astronaut training 4 1 History 4 2 Current virtual reality training 4 3 Advantages of virtual reality training 4 4 Disadvantages of virtual reality training 4 5 Future 5 See also 6 References 7 Further reading 8 External linksPurpose of training EditTraining flow Edit The selection and training of astronauts are integrated processes to ensure the crew members are qualified for space missions 5 The training is categorized into five objectives to train the astronauts on the general and specific aspects basic training advanced training mission specific training onboard training and proficiency maintenance training 6 The trainees must learn medicine language robotics and piloting space system engineering the organization of space systems and the acronyms in aerospace engineering during the basic training While 60 to 80 of the astronauts will experience space motion sickness including pallor cold sweating vomiting and anorexia 7 the astronaut candidates are expected to overcome the sickness During the advanced training and the mission specific training astronauts will learn about the operation of specific systems and skills required associated with their assigned positions in a space mission The mission specific training typically requires 18 months to complete for Space Shuttle and International Space Station crews 6 It is important to ensure the astronauts well being physical and mental health prior during and after the mission period Proficiency maintenance aims to help the crew members to maintain a minimum level of performance including topics such as extravehicular activity robotics language diving and flight training 6 Launch and landing Edit The effects of launching and landing has various effects on astronauts with the most significant effects that occur being space motion sickness 7 orthostatic intolerance and cardiovascular events Space motion sickness is an event that can occur within minutes of being in changing gravity environments i e from 1g on Earth prior to launch to more than 1g during launch and then from microgravity in space to hypergravity during re entry and again to 1g after landing The symptoms range from drowsiness and headaches to nausea and vomiting There are three general categories of space motion sickness Mild One to several transient symptoms no operational impact Moderate Several symptoms of persistent nature minimal operational impact Severe Several symptoms of persistent nature significant impact on performanceAbout three fourths of astronauts experience space motion sickness with effects rarely exceeding two days There is a risk for post flight motion sickness however this is only significant following long duration space missions Post flight following exposure to microgravity the vestibular system located in the inner ear is disrupted because of the microgravity induced unresponsiveness of the otoliths which are small calcareous concretions that sense body postures and are responsible for ensuring proper balance In most cases this leads to some postflight postural illusions Cardiovascular events represent important factors during the three phases of a space mission They can be divided in Pre existing cardiovascular diseases these are typically selected out during astronaut selection but if they are present in an astronaut they can worsen over the course of the spaceflight Cardiovascular events and changes occurring during spaceflight these are due to body fluids shift and redistribution heart rhythm disturbances and decrease in maximal exercise capacity in the micro gravity environment These effects can potentially lead the crew to be severely incapacitated upon return to a gravitational environment and thus unable to egress a spacecraft without assistance Orthostatic intolerance leading to syncope during post flight stand test On orbit operations Edit Further information Effect of spaceflight on the human body Astronauts are trained in preparation for the conditions of launch as well as the harsh environment of space This training aims to prepare the crew for events falling under two broad categories events relating to operation of the spacecraft internal events and events relating to the space environment external events An internal view of ESA s Columbus module training mockup located at the European Astronaut Centre in Cologne Germany Astronauts must familiarize themselves with all the spacecraft components during their training During training astronauts are familiarized with the engineering systems of the spacecraft including spacecraft propulsion spacecraft thermal control and life support systems In addition to this astronauts receive training in orbital mechanics scientific experimentation earth observation and astronomy This training is particularly important for missions when an astronaut will encounter multiple systems for example on the International Space Station ISS Training is performed in order to prepare astronauts for events that may pose a hazard to their health the health of the crew or the successful completion of the mission These types of events may be failure of a critical life support system capsule depressurization fire and other life threatening events In addition to the need to train for hazardous events astronauts will also need to train to ensure the successful completion of their mission This could be in the form of training for EVA scientific experimentation or spacecraft piloting External events Edit External events refers more broadly to the ability to live and work in the extreme environment of space This includes adaptation to microgravity or weightlessness isolation confinement and radiation The difficulty associated with living and working in microgravity include spatial disorientation motion sickness and vertigo During long duration missions astronauts will often experience isolation and confinement This has been known to limit performance of astronaut crews and hence training aims to prepare astronauts for such challenges 8 The long term effects of radiation on crews is still largely unknown However it is theorized that astronauts on a trip to Mars will likely receive more than 1000x the radiation dosage of a typical person on earth 9 As such present and future training must incorporate systems and processes for protecting astronauts against radiation Science experiments Edit Scientific experimentation has historically been an important element of human spaceflight and is the primary focus of the International Space Station Training on how to successfully carry out these experiments is an important part of astronaut training as it maximizes the scientific return of the mission Once on orbit communication between astronauts and scientists on the ground can be limited and time is strictly apportioned between different mission activities It is vital that astronauts are familiar with their assigned experiments in order to complete them in a timely manner with as little intervention from the ground as possible For missions to the ISS each astronaut is required to become proficient at one hundred or more experiments During training the scientists responsible for the experiments do not have direct contact with the astronauts who will be carrying them out Instead scientists instruct trainers who in turn prepare the astronauts for carrying out the experiment Much of this training is done at the European Astronaut Center For human experiments the scientists describe their experiments to the astronauts who then choose whether to participate on board the ISS For these experiments the astronauts will be tested before during and after the mission to establish a baseline and determine when the astronaut returned to the baseline A researcher using VR headset to investigate ideas for controlling rovers on a planet Purpose of virtual reality training Edit Virtual reality training for astronauts intends to give the astronauts candidates an immersive training experience Virtual reality has been explored as a technology to artificially expose astronauts to space conditions and procedures prior to going into space Using virtual reality astronauts can be trained and evaluated on performing an EVA extravehicular activity with all the necessary equipment and environmental features simulated This modern technology also allows the scenario to be changed on the go such as to test emergency protocols 10 The VR training systems can reduce the effects of the space motion sickness through a process of habituation Preflight VR training can be a countermeasure for space motion sickness and disorientation due to the weightlessness of the microgravity environment 11 When the goal is to act as a practice tool virtual reality is commonly explored in conjunction with robotics and additional hardware to increase the effect of immersion or the engagement of the trainee 12 Training by region EditUnited States Edit At NASA following the selection phase the so called AsCans Astronaut candidates have to undergo up to two years of training indoctrination period to become fully qualified astronauts Initially all AsCans must go through basic training to learn both technical and soft skills There are 16 different technical courses in Life support systems Orbital mechanics Payload deployment Earth observations Space physiology and medicine Astronauts train in the Neutral Buoyancy Facility at the Johnson Space Center in Houston Texas The Crew of STS 135 practices rendezvous and docking with the ISS in the Systems Engineering Simulator at the Johnson Space Center on June 28 2011 in Houston Texas AsCans initially go through Basic Training where they are trained on Soyuz and ISS systems flight safety and operations as well as land or water survival Pilot AsCans will receive training on NASA s T 38 Trainer Jet Furthermore because modern space exploration is done by a consortium of different countries and is a very publicly visible area astronauts received professional and cultural training as well as language courses specifically in Russian 13 Following completion of Basic Training candidates proceed to NASA s Advanced Training AsCans are trained on life sized models to get a feel of what they will be doing in space This was done both through the use of the Shuttle Training Aircraft while it was still operational and is done through simulation mock ups The shuttle training aircraft was exclusively used by the commander and pilot astronauts for landing practices until the retirement of the Shuttle while advanced simulation system facilities are used by all the candidates to learn how to work and successfully fulfill their tasks in the space environment Simulators and EVA training facilities help candidates to best prepare their different mission operations In particular vacuum chambers parabolic flights and neutral buoyancy facilities NBF allow candidates to get acclimated to the micro gravity environment particularly for EVA Virtual reality is also becoming increasingly used as a tool to immerse AsCans into the space environment 13 14 The final phase is the Intensive Training It starts at about three months prior to launch preparing candidates for their assigned mission Flight specific integrated simulations are designed to provide a dynamic testing ground for mission rules and flight procedures The final Intensive Training joint crew flight controller training is carried out in parallel with mission planning This phase is where candidates will undergo mission specific operational training as well as experience with their assigned experiments Crew medical officer training is also included to effectively intervene with proactive and reactive actions in case of medical issues 13 Notable training facilities Edit Neil Armstrong in a Lunar Module simulator prior to his journey to the Moon It can take up to two years for an AsCan to become formally qualified as an astronaut Usually the training process are completed with various training facilities available in NASA 15 Space training facilities try to replicate or simulate the experience of spaceflight in a spacecraft as closely and realistically as possible This includes full size cockpit replicas mounted on hydraulic rams and controlled by state of the art computer technology elaborate watertanks for simulation of weightlessness and devices used by scientists to study the physics and environment of outer space Space Vehicle Mock up Facility SVMF located in the Johnson Space Center in Houston TX The SVMF consists of life size models of vehicles of the ISS the Orion and different other commercial programs The purpose of SVMF is to provide a unique simulated experience for astronauts to get familiar with their tasks in space vehicles Potential training projects include preparation of emergency on orbit intra vehicular maintenance and airlock operations The facility also provides experiences for astronauts in real time communications with the ground team for mission support 16 KC 135 Stratotanker the KC 135 is an air refueling plane designed by Boeing Known as the Weightless Wonder or the Vomit Comet this plane is the most famous of its kind which has served to simulate reduced or microgravity environments for NASA astronauts since 1994 The roller coaster maneuvers that the plane is capable of doing provide people as well as equipment onboard about 20 25 seconds of weightlessness 17 The Precision Air Bearing Floor PABF located in the Johnson Space Center in Houston TX Because of the microgravity environment in space the resulting lack of friction posts difficulties for astronauts to move and stop large objects The PABF is a flat floor that uses compressed air to suspend typical hardwares or mock ups that astronauts may encounter in space above the ground It is used to simulate low friction environments for astronauts to learn to move large objects 16 The Neutral Buoyancy Lab NBL located in the Johnson Space Center in Houston TX Through a combination of weighting and floating effects the NBL creates a balance between the tendencies to sink and to float and therefore simulating the experience of weightlessness In the NBL several full size models of the space vehicles are present in a large water tank Unlike the SVMF the NBL helps astronauts train on projects such as maintenance but outside of the space vehicle 18 Europe Edit Astronaut training in Europe is carried out by the European Astronaut Centre EAC headquartered in Cologne Germany European training has three phases Basic training Advanced training and Increment Specific Training Soyuz capsule simulator located at the EAC in Cologne Germany ESA astronauts will simulate operations in the capsule at the EAC For all ESA selected astronauts Basic Training begins at the EAC headquarters This section of the training cycle has four separate training blocks that last 16 months Astronauts will receive an orientation on the major spacefaring nations their space agencies and all major crewed and uncrewed space programs Training in this phase also looks into applicable laws and policies of the space sector Technical including engineering astrodynamics propulsion orbital mechanics etc and scientific including human physiology biology earth observation and astronomy basics are introduced to ensure that all new astronauts have the required base level of knowledge Training is done on ISS operations and facilities including an introduction to all major operating systems on board the ISS that are required for its functionality as a crewed space research laboratory This phase also covers in depth systems operations for all spacecraft that service the ISS e g Soyuz Progress Automatic Transfer Vehicle ATV and the H II Transfer Vehicle HTV as well as ground control and launch facility training This training phase also focuses on skills such as robotic operations rendezvous and docking Russian language courses human behavior and performance and finally a PADI open water scuba diving course This scuba course provides basic EVA training at ESA s NBF before moving onto the larger NASA training facility at the Lyndon B Johnson Space Center Advanced Training includes a much more in depth look into the ISS including learning how to service and operate all systems Enhanced science training is also implemented at this time to ensure all astronauts can perform science experiments on board the ISS This phase takes around one year to complete and training is completed across the ISS partner network no longer only at the EAC It is only upon completion of this phase that astronauts are assignment to a spaceflight Increment Specific Training starts only after an astronaut has been assigned to a flight This phase lasts 18 months and prepares them for their role on their assigned mission During this phase crew members as well as backup crews will train together The crew tasks on the ISS are individually tailored with consideration to the astronaut s particular experience and professional background There are three different user levels for all on board equipment i e user level operator level and specialist level A crew member can be a specialist on systems while also only being an operator or user on others hence why the training program is individually tailored Increment Specific Training also includes training to deal with off nominal situations Astronauts will also learn how to run the experiments that are specifically scheduled for their assigned missions Russia Edit The grounds of the Gagarin Cosmonauts Training Center Training for cosmonauts falls into three phases General Space Training Group Training and Crew Training 19 General Space Training lasts about two years and consists of classes survival training and a final exam which determines whether a cosmonaut will be a test or research cosmonaut The next year is devoted to Group Training where cosmonauts specialize in the Soyuz or ISS as well as professional skills The final phases the Crew Training phase lasts a year and a half and is dedicated to detailed vehicle operations procedures ISS training and the English language Training primarily takes place at the Yuri Gagarin Cosmonaut Training Center The center facilities have full size mockups of all major Soviet and Russian spacecraft including the ISS As with the ISS astronauts cosmonauts train in the US Germany Japan and Canada for specific training in the various ISS modules Japan Edit The Japanese human spaceflight program has historically focused on training astronauts for Space Shuttle missions As such training previously took place at NASA s Lyndon B Johnson Space Center and followed that of NASA astronauts and other international participants in the Space Shuttle program H II rocket outside the Tsukuba Space Center where training of JAXA astronauts takes place Since the development of domestic training facilities at the Tsukuba Space Center training has increasingly taken place in Japan With Japan s participation in the ISS the training of Japanese astronauts follows a similar structure to that of other ISS partners Astronauts carry out 1 5 years of Basic Training mainly at Tsukuba followed by 1 5 2 years of Advanced Training at Tsukuba and ISS partner sites Training for any international ISS astronauts involving the Kibo module will also be carried out at Tsukuba Space Center 20 Advanced Training is followed by Increment Specific Training which along with any Kibo training will be carried out at Tsukuba EVA training for Kibo takes place in the Weightless Environment Test System WETS WETS is a Neutral Buoyancy Facility featuring a full scale mock up of the Kibo module on the ISS 21 The Tsukuba Space Center also includes medical facilities for assessing suitability of candidates an isolation chamber for simulating some of the mental and emotional stressors of long duration spaceflight and a hypobaric chamber for training in hull breach or Life Support System failure scenarios resulting in a reduction or loss of air pressure 22 China Edit Although official detail of the selection process for the Shenzhou program is not available what is known is that candidates are chosen by the Chinese National Space Administration from the Chinese air force and must be between 25 and 30 years of age with a minimum of 800 hours flying time and a degree level education Candidates must be between 160 cm and 172 cm in height and between 50 kg and 70 kg in weight 23 For China s Shenzhou astronauts training begins with a year long program of education in the basics of spaceflight During this period candidates are also introduced to human physiology and psychology The second phase of training lasting nearly 3 years involves extensive training in piloting the Shenzhou vehicle in nominal and emergency modes The third and final stage of training is mission specific training and lasts approximately 10 months During this phase of training astronauts are trained in the high fidelity Shenzhou trainer as well as the Neutral Buoyancy Facility located at the Astronaut Center of China ACC in Beijing As well as time spent in the Neutral Buoyancy Facility NBF training for EVA takes place in a high vacuum low temperature chamber that simulates the environmental conditions of space At all stages of training astronauts undergo physical conditioning including time in a human centrifuge located at the ACC and a program of micro gravity flights carried out in Russia 24 India Edit The Indian human space flight program still awaits a formal go ahead Once cleared the mission is expected to take two Indians in a Soyuz type orbital vehicle into low Earth orbit The training for these astronauts should be based on the lessons learned from training India s only Cosmonaut Wing Commander Rakesh Sharma See Salyut 7 1984 and through India s international co operation with NASA and Roscosmos This would allow India to gain insights from their rich experiences in human spaceflight There also lies a possibility that India may go proceed through its human spaceflight program individually necessitating the Indian Space Research Organisation ISRO to develop its own training program For astronaut training India is deciding a place which is at a distance of 8 to 10 km from Kempegowda international airport This land is under the ownership of ISRO Astronaut training and biomedical engineering centers will be built on it Though India s first man mission training will take place in USA or in Russia this place can be used for future training Moreover center will have chambers for radiation regulation thermal cycling and centrifugal for the acceleration training 25 Future training EditSuborbital astronaut training Edit Ecuadorian Civilian Space Agency EXA While the first generation of non government spaceflight astronauts will likely perform suborbital trajectories currently companies like Virgin Galactic and Xcor Aerospace are developing proprietary suborbital astronaut training programs However the first official Suborbital Astronaut Training program was a joint effort between two government agencies The Ecuadorian Air Force and the Gagarin Cosmonaut Training Center 26 developed the ASA T Advanced Suborbital Astronaut Training program which lasted up to 16 months between 2005 and 2007 and focused on command and research duties during short missions with suborbital trajectories up to 180 kilometers This program had one Ecuadorian citizen graduate in 2007 27 28 29 the Ecuadorian Space Agency made a call 30 for a new class of ASA T training candidates accordingly to the EXA they will focus on renting commercial suborbital vehicles in order to perform crewed space research 31 Commercial astronauts Edit Human centrifuge at DLR in Cologne Germany used for human physiological tests The high accelerations experienced during suborbital flights may necessitate testing or even training on human centrifuges to determine if participants are fit for space flight Looking ahead the emergence of commercial space tourism will necessitate new standards for flight participants that currently do not exist These standards will be to ensure that medical screenings are done properly in order to ensure safe and successful flights This process will differ from that for space agency astronauts because the goal is not to fly the best individual but to ensure a safe flight for the passengers The main considerations for this type of travel will be What type and extent of training is sufficient Who will qualify space tourists as fit for travel How will new regulations comply with existing medical boards What selection out criteria need to be employed to reduce dangers to space tourists Medical regulations for commercial space flight might mitigate commercial space company risk by selecting only those capable of passing standard medical criteria as opposed to allowing anyone who can purchase a ticket to fly The first generation of commercial space flight will likely be suborbital trajectories which invoke significant acceleration changes causing cardiovascular and pulmonary issues Because of this any future medical criteria for commercial spaceflight participants needs to focus specifically on the detrimental effects of rapidly changing gravitational levels and which individuals will be capable of tolerating this A fundamentals of scientist astronaut formative program along with additional Bioastronautics Extravehicular activity Space Flight Operations Flight Test Engineering and Upper Atmospheric Research courses have been conducted by Project PoSSUM scientist astronaut candidates since 2015 32 33 As of January 2021 the program has attracted members from 46 different countries and published research on mesospheric dynamics human performance in space suits microgravity research in various fields and post landing environments The programs are run by the International Institute of Astronautical Sciences that has also partnered with Embry Riddle Aeronautical University Final Frontier Design Spacesuits Survival Systems USA National Research Council of Canada Canadian Space Agency and the National Association of Underwater Instructors Current research on fitness training and strategies for commercial astronauts conducted by Astrowright Spaceflight Consulting the first commercial firm to offer dedicated fitness training for space tourists suggests that conventional fitness training is inadequate to support safe movement in microgravity and that training utilizing reduced points of stability should be emphasized 34 Long duration missions to the Moon or Mars Edit Astronaut during virtual reality training Astronauts for long term missions such as those to the Moon or Mars need to carry out multiple tasks and duties because on such missions the astronauts will need to function largely autonomously and will need to be proficient in many different areas For these types of missions the training to prepare astronauts will likely include training as doctors scientists engineers technicians pilots and geologists In addition there will be a focus on the psychological aspects of long duration missions where crew is largely isolated 35 Currently a six month mission to the ISS requires up to five years of astronaut training This level of training is to be expected and likely to be expanded upon for future space exploration missions It may also include in flight training aspects It may be possible that the ISS will be used as a long duration astronaut training facility in the future A powerful tool for astronaut training will be the continuing use of analog environments including NASA Extreme Environment Mission Operations NOAA NEEMO NASA s Desert Research and Technology Studies Desert RATS Envihab planned Flight Analog Research Unit Haughton Mars Project HMP or even the ISS in flight In fact at NEEMO a total of 15 mission astronauts known as aquanauts have been trained for future missions to asteroids 36 The use of virtual reality will also continue to be used as a means of training astronauts in a cost effective manner particularly for operations such as extra vehicular activity EVA Robonaut2 onboard ISS These missions are not completely independent without the presence of robots This opens up a new avenue towards Human Robot Interaction which has to be thoroughly understood and practised to develop a harmonious relationship between astronauts and robots These robots would aid the astronauts from being their personal assistants to next generation of extreme environment explorers Currently there is a robot on the ISS aiding the astronauts in their mammoth tasks with a human touch Intercultural and human robot interaction training is the need of the hour for long duration missions Training also has to be evolved for future Moon landings to a human mission to Mars Factors like crew dynamics crew size and crew activities play a crucial role as these missions would last from one year to Moon to three years on Mars The training required for such missions has to be versatile and easy to learn adapt and improvise A journey to Mars will require astronauts to remain in the crew capsule for nine months 37 The monotony and isolation of the journey present new psychological challenges The long period spent in the crew capsule is comparable to other forms of solitary confinement such as in submarines or Antarctic bases Being in an isolated and confined environment generates stress interpersonal conflict and other behavioral and mental problems 38 However natural scenery and communication with loved ones has shown to relax and lessen these effects A Network of Social Interactions for Bilateral Life Enhancement ANSIBLE which provides natural scenery and socialization in a virtual reality environment is being researched as a solution to behavioral health 39 Researchers are looking into how current mental health tools can be adjusted to help the crew face stressors that will arise in an isolated confined environment ICE during extended missions 40 The International Space Station uses a behavioral conflict management system known as the Virtual Space Station VSS to minimize conflict between crew members and address psychological challenges 41 The program has modules that focus on relationship management stress and depression that guide astronaut s through a virtual therapy session in space 40 Virtual reality astronaut training EditHistory Edit Virtual reality technologies first came to a commercial release in the 1990s It is not until then did people realize that VR can be used in training astronauts The earlier VR gears for astronaut training are dedicated to enhance the communication between robot arm operators and the astronaut during Extravehicular Activities EVA It brings EVA crew members and robot arm operators together in live even when they are on board a spacecraft 42 It is also used to replace some of the oversized models that cannot fit in the Neutral Buoyancy Lab NBL In 1993 astronauts were trained and evaluated on working on the Hubble Space Telescope through a virtual reality training tool Research in Human Factors Aspects of Enhanced Virtual Environments for EVA Training and Simulation RAVEN However the aim of RAVEN was not to train astronauts but to evaluate the efficacy of training using virtual reality versus underwater and other setup 43 Through the years of technological development in VR the hardware for the VR Lab in NASA has also significantly improved Both the material and the resolution of the display are being renovated 42 1991 Liquid Crystal Display LCD 320x420 1992 Cathode Ray Tube CRT 1280x1024 2005 Micro Organic Light Emitting Diode micro OLED 800x600 2012 LCD 1280x720 2015 OLED 1920x1080Virtual reality has also been adopted to a much wider range of fields in space exploration throughout the history of technology renovation The newer applications of VR include but are not limited to 44 Mission planning Cooperative and interactive designing Engineering problem solving Data modeling Astronauts Tom Marshburn left and Dave Wolf train for a spacewalk in the Integrated EVA RMS Virtual Reality Simulator Facility at Johnson Space Center Current virtual reality training Edit While the extravehicular activities EVAs training facility can simulate the space conditions including pressure and lighting the Micro g environment cannot be fully reconstructed in the Earth s 1 G environment 45 Virtual reality is utilized during EVA training to increase the immersion of the training process NASA Johnson Space Center has facilities such as the Space Vehicle Mockup Facility SVMF Virtual Reality Laboratory VRL and Neutral Buoyancy Laboratory NBL The SVMF uses the Partial Gravity Simulator PGS and air bearing floor PABF to simulate the zero gravity and the effects of Newton s laws of motion 46 Similar training systems originated from the Apollo and Gemini training Virtual reality enhances an astronaut s senses during training modules like fluid quick disconnect operations spacewalks and the orbiter s Space Shuttle thermal protection system TPS repairs 46 NASA Virtual Reality Laboratory utilizes virtual reality to supplement the Simplified Aid For EVA Rescue SAFER as simplified aid The VR training offers a graphical 3 dimensional simulation of the International Space Station ISS with a headset haptic feedback gloves and motion tracker 47 In 2018 two Expedition 55 astronauts Richard R Arnold and Andrew J Feustel received virtual reality training and performed the 210th spacewalk 48 The Virtual Reality Laboratory offers astronauts an immersive VR experience for spacewalks before launching into space The training process combines a graphical rendering program that replicates the ISS and a device called the Charlotte Robot that allows astronauts to visually explore their surroundings while interacting with an object The Charlotte robot is a simple device with a metal arm attached to the side that allows a user to interact with the device The user wears haptic feedback gloves with force sensors that send signals to a central computer 49 In response the central computer maneuvers the device using a web of cables and calculates how it would act in space through physics 50 While objects are weightless in space an astronaut has to be familiar with an object s forces of inertia and understand how the object will respond to simple motions to avoid losing it in space 49 51 Training can be completed individually or with a partner This allows astronauts to learn how to interact with mass and moments of inertia in a microgravity environment 50 The Neutral Buoyancy Laboratory NBL has advantages in simulating a zero gravity environment and reproducing the sensation of floating in space The training method is achieved by constructing a low gravity environment through Maintaining the Natural buoyancy in one of the largest pools in the world The NBL pool used to practice extravehicular activities or spacewalks is 62 meters 202 feet long 31 meters 102 feet wide and 12 meters 40 feet deep 15 with a capacity of 6 2 million gallons 52 Underwater head mounted display virtual reality headset is used to provide visual information during the training with a frame rate of 60 fps and screen resolution of 1280 by 1440 52 The underwater VR training system has a reduced training cost because of the accessibility of the VR applications and astronauts need less time to complete the assigned practice task Despite the NASA training modules commercial spaceflight training also uses virtual reality technology to improve their training systems Boeing s virtual reality team develops a training system for Boeing Starliner to train astronauts to transport between the Earth and the ISS The VR training system can simulate high speed situations and emergency scenarios for instance launching entering the space and landing at an unexpected location 53 Advantages of virtual reality training Edit Visual reorientation is a phenomenon that happens when the perception of an object changes because of the changing visual field and cues 54 This illusion will alter the astronaut s perception of the orienting force of gravity and then lose spatial direction The astronauts must develop good spatial awareness and orientation to overcome visual reorientation In the traditional disorientation training for instance the Yuri Gagarin Cosmonaut Training Center trains the astronaut by simulating a microgravity environment through a centrifuge 6 In contrast VR training requires less gear training the astronauts more economically Virtual reality training utilizes the mix realistic interaction devices such as cockpits in flight simulators can reduce the simulation sickness and increase user movement 55 Compared to traditional training VR training performs better to minimize the effects of space motion sickness and spatial disorientation Astronauts who received VR training can perform the task 12 faster with a 53 decrease in nausea symptoms 11 While VR is used in astronaut training on the ground immersive technology also contributes to on orbit training 56 VR head mounted display can help the astronaut maintain physical well being as part of proficiency maintenance training 6 56 Moreover VR systems are used to ensure the mental health of the crewmembers The simulations of social scenarios can mitigate the stress and establish the connectedness under the isolated and confined environment ICE 56 Virtual reality acclimates astronauts to environments in space such as the International Space Station before leaving earth While astronauts can familiarize themselves with the ISS during training in the NBL they are only able to see certain sections of the station While it prepares astronauts for the tasks they are performing in space it does not necessarily give them a full spatial understanding of the station s layout That s where Virtual Reality plays an important role The Virtual Reality Lab uses a system known as the Dynamic Onboard Ubiquitous Graphics program DOUG to model the ISS s exterior including decals fluid lines and electrical lines so that the crew can acclimate to their new environment 49 The level of detail goes beyond the exterior of the station When a user enters space they see pure black until their pupil s dilate and the sky fills with stars in an occurrence called the blooming effect 57 Disadvantages of virtual reality training Edit While virtual reality prepares astronauts for the unfamiliar tasks they will face in outer space the training is unable to replicate the psychological and emotional stress that astronauts face on a daily basis This is because virtual tasks do not hold the same repercussions as the real task and the technology does not produce strong psychological effects like claustrophobia that often occurs in enclosed environments 58 Stimulating a virtual microgravity environment can be costly due to additional equipment requirements Unlike commercialized virtual reality the equipment that NASA uses cannot be produced at a large scale because the systems require supplemental technology 40 Several VR programs work in combination with the Neutral Buoyancy Lab or the Charlotte Robot in the Virtual Reality Lab which requires expensive facilities and does not eliminate the travel component that VR can minimize 59 NASA s Charlotte robot is restricted by cables that simulate the microgravity environment and the Virtual Reality Lab only has two machines in their possession 49 This particular training system requires a virtual glovebox system GVX that has been incorporated into training at NASA and the EVA virtual system at the Astronaut Center of China 60 Using sensors embedded in the fabric the gloves can sense when the wearer decides to grasp an object or release it but the technology needs to be further developed to integrate precise user movements into virtual programs 50 These gloves have been reported to be uncomfortable and only capture limited movements 58 Full body motion sensors have also been incorporated into training and tend to be expensive but necessary in order to have effective tactile feedback in response to the astronauts movements While virtual reality programs have been developed that do not require full body sensors the absence reduces the degree to which a user can interact with the virtual world 58 Future Edit The primary focus of future research of virtual reality technologies in space exploration is to develop a method of simulating a microgravity environment Although it has been a goal since the beginning of VR being used in astronaut training minor progress has been made The current setup uses a bungee rope attached to a person s feet a swing attached to the body and finally a head mounted VR display 61 62 However from participants in experiments that use this setup to simulate reduced gravity environments they only experience the feel of moving around in space with the help of VR but the experience does not resemble a real zero gravity environment in outer space Specifically the pressure from the bungee rope and the swing because of the participants own weight creates an unreal and unpleasant feeling 61 The current technology may be enough for the general public to experience what moving around in space is like but it is still far from being formally used as an astronaut training tool These efforts of simulating micro gravity serve a similar purpose of creating an increasingly immersive environment for astronaut training In fact this is a developing trend for the entire VR industry The ultimate scene VR experience that we are imagining will eventually be marked by the elimination between the real and the virtual world See also EditEffect of spaceflight on the human body Human analog missions Human spaceflight Mercury Seven NASA Astronaut Corps Space medicine The Astronaut MonumentReferences Edit Lewis Robert 2017 12 08 Medical Examination Requirements MER for Former Astronauts NASA Retrieved 2020 08 01 Kale Sneha R Master Hiral S Verma Chhaya V Shetye Jaimala Surkar Swati Mehta Amita 2013 Exercise Training for Astronauts Indian Journal of Physiotherapy and Occupational Therapy 7 2 82 doi 10 5958 j 0973 5674 7 2 017 Oddsson Lars IE Karlsson Robin Konrad Janusz Ince Serdar Williams Steve R Zemkova Erika December 2007 A rehabilitation tool for functional balance using altered gravity and virtual reality Journal of NeuroEngineering and Rehabilitation 4 1 25 doi 10 1186 1743 0003 4 25 PMC 1936992 PMID 17623080 NASA Space Science and Western Europe NASA in the World 2013 doi 10 1057 9781137340931 0010 ISBN 978 1 137 34093 1 Sgobba Tommaso Landon Lauren B Marciacq Jean Bruno Groen Eric Tikhonov Nikolai Torchia Francesco 2018 Selection and training Space Safety and Human Performance pp 721 793 doi 10 1016 B978 0 08 101869 9 00016 9 ISBN 978 0 08 101869 9 a b c d e Marciacq Jean Bruno Bessone Loredana 2009 Crew Training Safety Safety Design for Space Systems pp 745 815 doi 10 1016 B978 0 7506 8580 1 00025 7 ISBN 978 0 7506 8580 1 a b Heer Martina Paloski William H October 2006 Space motion sickness Incidence etiology and countermeasures Autonomic Neuroscience 129 1 2 77 79 doi 10 1016 j autneu 2006 07 014 PMID 16935570 S2CID 6520556 NASA Long Duration Psychology online Accessed 20 February 2012 Available from World Wide Web lt https history nasa gov SP 4225 long duration long htm gt DURANTE M and FA CUCINOTTA 2008 Heavy Ion Carcinogenesis and Human Space Exploration Nature Rev Cancer 2 May pp 465 472 Olbrich Manuel Graf Holger Keil Jens Gad Rudiger Bamfaste Steffen Nicolini Frank 2018 Virtual Reality Based Space Operations A Study of ESA s Potential for VR Based Training and Simulation Virtual Augmented and Mixed Reality Interaction Navigation Visualization Embodiment and Simulation Lecture Notes in Computer Science Vol 10909 pp 438 451 doi 10 1007 978 3 319 91581 4 33 ISBN 978 3 319 91580 7 a b Stroud Kenneth J Harm Deborah L Klaus David M 1 April 2005 Preflight Virtual Reality Training as a Countermeasure for Space Motion Sickness and Disorientation Aviation Space and Environmental Medicine 76 4 352 356 PMID 15828634 Menon Anil S Barnes Bobby Mills Rose Bruyns Cynthia D Twombly Alexander Smith Jeff Montgomery Kevin Boyle Richard 2003 Using registration calibration and robotics to build a more accurate virtual reality simulation for astronaut training and telemedicine UNION Agency pp 87 94 ISBN 978 80 903100 1 8 a b c SEEDHOUSE Erik 2010 Prepare for Launch The Astronaut Training Process New York City NY Springer NASA 2004 Astronauts in Training online Accessed 20 February 2012 Available from World Wide Web lt http www nasa gov audience forstudents 5 8 features F Astronauts in Training html gt a b Logan Barry NASA Astronauts in Training www nasa gov Retrieved 2020 07 29 a b Space Vehicle Mockup Facility SVMF PDF NASA FS 2013 05 011 JSC McDonald Terry NASA Zero Gravity Plane on Final Flight www nasa gov Retrieved 2020 07 29 Sonny Carter Training Facility The Neutral Buoyancy Laboratory PDF NASA FS 2006 11 026 JSC Cosmonaut training overview RuSpace Archived from the original on 2020 07 26 Retrieved 2012 02 26 JAXA 2011 Basic Training for International Space Station Astronaut Candidates online Accessed 25 February 2012 Available from World Wide Web lt http iss jaxa jp astro ascan ascan01 e html gt JAXA 2012 Tsukuba Space Center Overview online Accessed 25 February 2012 Available from World Wide Web lt http www jaxa jp about centers tksc index e html gt ESA 2008 Cercasi astronauti online Accessed 20 February 2012 Available from World Wide Web lt http www esa int esaKIDSit SEMGY11YUFF LifeinSpace 1 html gt SINO DEFENSE 2011 Chinese Astronaut Corps online Accessed 25 February 2012 Available from World Wide Web lt Chinese Space Program Chinese Astronaut Corps SinoDefence com Archived from the original on 2012 01 26 Retrieved 2012 02 26 gt MORRING F 2009 Astronaut Training Aviation Week and Space Technology pp 48 49 India says it will send a human to space by 2022 The Planetary Society Ecuadorian Air Force Official document on ASA T program Ecuadorian Air Force presented with ASA T program completion brief lt http www exa ec bp8 gt Ecuadorian Air Force presented with space program brief lt http www exa ec bp9 gt IAF EXA entry Ecuadorian Space Agency online Accessed October 1 2015 Available from World Wide Web lt http www iafastro org societes ecuadorian civilian space agency exa gt EXA call for astronaut candidates online Accessed October 1 2015 lt http www exa ec bp61 index html gt Ecuadorian Space Program Manned Space Research 61st International Astronautical Congress 2010 HUMAN SPACE ENDEAVOURS SYMPOSIUM B3 Overview Session Present and Near Term Human Space Flight Programs 1 lt https www academia edu 771672 THE ECUADORIAN CIVILIAN SPACE PROGRAM NEAR FUTURE MANNED RESEARCH MISSIONS IN A LOW COST ENTRY LEVEL SPACE PROGRAM gt SEEDHOUSE Erik 2016 XCOR Developing the Next Generation Spaceplane New York City NY Springer SEEDHOUSE Erik 2015 Virgin Galactic The First Ten Years New York City NY Springer MCGEE B W et al 2012 A Qualitative Assessment of Preflight Fitness Training Strategies and Methods online Accessed 29 May 2013 Available from World Wide Web lt http www boulder swri edu NSRC2012 Site1 PDF McGee O pdf gt Kelly Scott 2017 Endurance A Year in Space a Lifetime of Discovery With Margaret Lazarus Dean Alfred A Knopf a division of Penguin Random House p 50 ISBN 9781524731595 Unlike the early days of spaceflight when piloting skill was what mattered twenty first century astronauts are chosen for our ability to perform a lot of different jobs and to get along well with others especially in stressful and cramped circumstances for long periods of time MOSKOWITZ Clara 2011 Astronauts Set to Become Aquanauts for Undersea Asteroid Mission online Accessed 26 February 2012 Available from World Wide Web lt http www space com 13007 nasa astronauts undersea asteroid mission html gt Redd Nola 14 November 2017 How Long Does It Take to Get to Mars Space com Retrieved 2020 07 30 Anderson Allison Mayer Michael Fellows Abigail Cowan Devin Hegel Mark Buckey Jay 2017 06 01 Relaxation with Immersive Natural Scenes Presented Using Virtual Reality Aerospace Medicine and Human Performance 88 6 520 526 doi 10 3357 AMHP 4747 2017 PMID 28539139 via Research Gate Wu Peggy Morie Jacquelyn Chance Eric Haynes Kip Hamell Joshua Wall Peter Ladwig Jack Ott Tammy 2015 04 12 Maintaining Psycho Social Health on the Way to Mars and Back Proceedings of the 2015 Virtual Reality International Conference on ZZZ VRIC 15 pp 1 7 doi 10 1145 2806173 2806174 ISBN 9781450333139 S2CID 18919540 a b c Anderson Allison P Fellows Abigail M Binsted Kim A Hegel Mark T Buckey Jay C November 2016 Autonomous Computer Based Behavioral Health Countermeasure Evaluation at HI SEAS Mars Analog Aerospace Medicine and Human Performance 87 11 912 920 doi 10 3357 AMHP 4676 2016 PMID 27779949 Can Virtual Reality Help Astronauts Keep Their Cool Discover Magazine Retrieved 2020 07 31 a b Carson Erin September 17 2015 NASA shows the world its 20 year virtual reality experiment to train astronauts The inside story TechRepublic Retrieved 2020 07 29 Cater John P Huffman Stephen D 1995 01 01 Use of the Remote Access Virtual Environment Network RAVEN for Coordinated IVA EVA Astronaut Training and Evaluation Presence Teleoperators and Virtual Environments 4 2 103 109 doi 10 1162 pres 1995 4 2 103 PMID 11539288 S2CID 29308501 Sternstein Aliya 11 September 2006 Astronauts to board virtual reality video game Federal Computer Week 20 31 58 59 ProQuest 218869004 Thuot Pierre J Harbaugh Gregory J July 1995 Extravehicular activity training and hardware design consideration Acta Astronautica 36 1 13 26 Bibcode 1995AcAau 36 13T doi 10 1016 0094 5765 95 00035 X PMID 11541312 a b Moore Sandra K Gast Matthew A October 2010 21st Century extravehicular activities Synergizing past and present training methods for future spacewalking success Acta Astronautica 67 7 8 739 752 Bibcode 2010AcAau 67 739M doi 10 1016 j actaastro 2010 06 016 hdl 2060 20090034232 NASA is Using Virtual Reality to Train Astronauts Unimersiv 2016 04 11 Retrieved 2020 07 29 Virtual Reality Training and Global Robotics Work Before Spacewalk Space Station blogs nasa gov Retrieved 2020 07 29 a b c d The NASA Playground That Takes Virtual Reality To a Whole New Level Gizmodo 16 June 2015 Retrieved 2020 07 31 a b c NASA is Using Virtual Reality to Train Astronauts Unimersiv 2016 04 11 Retrieved 2020 07 31 Wang Lan Lin Lingjie Chang Ying Song Da December 2020 Velocity Planning for Astronaut Virtual Training Robot with High Order Dynamic Constraints Robotica 38 12 2121 2137 doi 10 1017 S0263574719001863 S2CID 213630797 a b Sinnott Christian Liu James Matera Courtney Halow Savannah Jones Ann Moroz Matthew Mulligan Jeffrey Crognale Michael Folmer Eelke MacNeilage Paul November 2019 Underwater Virtual Reality System for Neutral Buoyancy Training Development and Evaluation PDF NASA Varjo amp Boeing Starliner A New Era in Astronaut Training Varjo com Retrieved 2020 07 29 Wilson Christopher J Soranzo Alessandro 2015 08 03 The Use of Virtual Reality in Psychology A Case Study in Visual Perception Computational and Mathematical Methods in Medicine 2015 151702 doi 10 1155 2015 151702 PMC 4538594 PMID 26339281 Ronkko Jukka Markkanen Jussi Launonen Raimo Ferrino Marinella Gaia Enrico Basso Valter Patel Harshada D Cruz Mirabelle Laukkanen Seppo March 2006 Multimodal astronaut virtual training prototype International Journal of Human Computer Studies 64 3 182 191 doi 10 1016 j ijhcs 2005 08 004 a b c Salamon Nick Grimm Jonathan M Horack John M Newton Elizabeth K May 2018 Application of virtual reality for crew mental health in extended duration space missions Acta Astronautica 146 117 122 Bibcode 2018AcAau 146 117S doi 10 1016 j actaastro 2018 02 034 NASA trains astronauts with zero G virtual reality Engadget Retrieved 2020 07 31 a b c Baughman Alex 2020 Evaluation of Virtual and Hybrid Reality Systems for Astronaut Training Thesis ProQuest 2418705802 Machkovech Sam 2016 03 13 Ars tests NASA s first Vive VR experiments ISS lunar rover simulators Ars Technica Retrieved 2020 07 31 Qingchao Xie Jiangang Chao March 2017 The Application of Leap Motion in Astronaut Virtual Training IOP Conference Series Materials Science and Engineering 187 1 012015 Bibcode 2017MS amp E 187a2015Q doi 10 1088 1757 899x 187 1 012015 S2CID 113777872 a b Lindsey Patrica F October 1994 Development of microgravity full body functional reach envelope using 3 D computer graphic models and virtual reality technology NASA Technical Reports Tamaddon Kiarash Stiefs Dirk 2017 Embodied experiment of levitation in microgravity in a simulated virtual reality environment for science learning 2017 IEEE Virtual Reality Workshop on K 12 Embodied Learning through Virtual amp Augmented Reality KELVAR pp 1 5 doi 10 1109 KELVAR 2017 7961560 ISBN 978 1 5386 1892 9 S2CID 24280241 Further reading EditBaratt Michael May 1 2008 Principles of Clinical Medicine for Space Flight Springer ISBN 978 0 387 98842 9 Clement Gilles April 25 2005 Fundamentals of Space Medicine Space Technology Library ISBN 978 1 4020 3246 2 Kanas Nick September 30 2003 Space Psychology and Psychiatry Space Technology Library ISBN 978 1 4020 1341 6 Seedhouse Erik April 13 2010 Prepare for Launch The Astronaut Training Process Springer Praxis Books Space Exploration ISBN 978 1 4419 1349 4External links EditNASA Astronauts CSA Astronauts ESA Astronauts JAXA Astronauts Roscosmos Archived 2012 10 16 at the Wayback Machine List of experiments in International Space Station CNSA Manned Spaceflight ISRO Human Spaceflight NASA How to become an astronaut 101 Train Like An Astronaut Retrieved from https en wikipedia org w index php title Astronaut training amp oldid 1132497942, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.