Author: The InnovaSpace TeamSpace Without Borders! InnovaSpace CEO Thais Russomano recently contributed an article to the magazine - Asian Hospital & Healthcare Management - examining the challenges humankind faces if we are to spend more time in space. It gives a good overview of the topic without being too technical and is open access, so we thought you might like to take a look! The article features on pages 6-9 of the magazine and you can download the magazine free by following this LINK
Cardiopulmonary resuscitation (CPR) is a well-established part of basic life support (BLS), having saved countless lives since its first development in the 1960s. External chest compressions (ECCs), which form the main part of BLS, must be carried out until Advanced Life Support can begin. It is essential that ECCs are performed to the correct depth and frequency to guarantee effectiveness. The absence of gravity during spaceflight means that performing ECCs is more challenging. The likelihood of a dangerous cardiac event occurring during a space mission is remote, however, the possibility does exist. Nowadays, the selection process for space missions considers individuals at ages and with health standards that would have prohibited their selection in the past. With increased age, less stringent health requirements, longer duration missions and increased physical labour, due to a rise in orbital extravehicular activity, the risk of an acute life-threatening condition occurring in space has become of greater concern. The advent of space tourism may even enhance this possibility, with its popularity set to rise over the coming years as private companies test their new technology. Therefore, space scientists and physicians will have a greater responsibility to ensure space travellers, whether professional astronauts or space tourists, are adequately trained and familiarised with extraterrestrial BLS and CPR methods. Recently, work has been undertaken to develop methods of basic and advanced life support in microgravity and hypogravity, and several CPR techniques have been developed and tested. This blog presents one of these, the Evetts-Russomano MicroG CPR Method. Evetts-Russomano MicroG CPR Method In the Evetts-Russomano (ER) method, the rescuer can respond immediately, as it requires no additional CPR equipment/medication or the use of a restraint system. To assume the position, the rescuer places their left leg over the right shoulder of the patient and their right leg around the patient’s torso, allowing their ankles to be crossed approximately in the centre of the patient’s back; this is to provide stability and a solid platform against which to deliver force, without the patient being pushed away. From this position, chest compressions can be performed while still retaining easy access to perform ventilation. When adopting the ER CPR method, the rescuer must be situated in a manner that also allows sufficient space on the patient’s chest for the correct positioning of their hands to deliver the chest compressions. Extraterrestrial CPR simulation The main difference between extraterrestrial and terrestrial CPR is the strength of the gravitational field. In microgravity, patient and rescuer are both essentially weightless. When thinking about the technique of terrestrial CPR, with the rescuer accelerating their chest and upper body to generate a force to compress the patient’s chest, it is obvious that this cannot work in microgravity without significant aids. To this end, the ER CPR method has been developed using a ground-based microG simulation, during parabolic flights, and subsequently tested under-water! Video credits: Ground-based MicroG Simulation (land) = Space Researcher Lucas Rehnberg, MD (MicroG Center PUCRS, Brazil) Parabolic Flight MicroG Simulation (air)= Researchers = Thais Russomano, Simon Evetts, Lisa Evetts & João Castro (ESA 29th Parabolic Flight Campaign, Bordeaux, France) Underwater MicroG Simulation (water) = Sea King Dive Center, Chengdu, China - Instructor Gang Wei; Chinese Space First Responder & Space Researcher/Instructor Chris Yuan A project of InnovaSpace, PECA and Guangxi Diving Paradise Club, China Free Resource: Extraterrestrial CPR and Its Applications in Terrestrial Medicine
Authors: Thais Russomano, Lucas Rehnberg In book: Resuscitation Aspects, Ed: Theodoros Aslanidis Publisher: IntechOpen 2017 See Download Link at https://www.innovaspace.org/chapters.html Tiyoko HashimotoInstrutora de mergulho livre, mergulho autônomo e mergulhadora em formação no mergulho profissional raso LinkedIn Profile O mergulho faz parte de uma série de habilidades para quem busca a carreira astronáutica. Por quê? A água é cerca de 800 vezes mais densa que o ar, o que dificulta a movimentação subaquática, exigindo além de mais esforço, uma movimentação mais lenta para evitar fadiga que pode levar mergulhadores inexperientes a até abortar o mergulho. Além disso, a flutuabilidade neutra, ou seja, a capacidade de "boiar" na água permite que o praticante tenha a sensação semelhante à da microgravidade. Para fazer uso da flutuabilidade neutra como treinamento, as agências espaciais têm usado, ao longo dos anos, laboratórios subaquáticos como o NBL (Neutral Buoyancy Laboratory), localizado em Houston, no Texas, Estados Unidos e que faz parte do complexo da NASA. Segundo a NASA, possui 61,21 metros de comprimento, 30,90 de largura e 12,12 metros de profundidade e permite treinamentos como caminhadas espaciais, comunicação e segurança, além de permitir testes com equipamentos de vídeo e trajes espaciais. Na ESA (Agência Espacial Europeia), em Colônia, Alemanha, os astronautas são certificados no nível de mergulhadores de resgate. Esse conhecimento, segundo a ESA, permite melhor desempenho dos astronautas nas caminhadas espaciais e permite que previnam problemas e saibam lidar com emergências de modo adequado.
De acordo com a NASA, os astronautas utilizam nitrox (mistura de nitrogênio com uma porcentagem maior de oxigênio, também conhecido como ar enriquecido no mergulho) durante as sessões de treinamento no NBL. No mergulho dependente saturado não há perda de ar, nem se solta bolhas, como ocorre no mergulho recreativo. Todo o material exalado durante um mergulho saturado, que pode ir até 320 metros de profundidade, é recaptado, reciclado, para depois ser usado novamente na respiração. Isso ocorre porque o gás em questão, além do oxigênio, é o hélio, que tem um custo bastante elevado. Our thanks go to space enthusiast Ermis Divinis, aged 11, who used his digital media skills to create this fun summary of the Mars rovers, which have provided the scientific community with so much valuable data about the Red Planet. Enjoy!
Anna Karahan European Space Foundation - ERC Coordinator & Inspiration Zone producer It’s 2077 We have been expanding our presence on Mars for several decades now, which involves trial missions, in-depth research, terrain checking, the first human landing on the surface of the Red Planet and the creation of a scientific base. Driven by curiosity and the desire to learn and expand the human possibilities of adapting to new living conditions, we decide to establish colonies on Mars. The inhabitants of the new Martian city-states are not accidental. They were selected based on their health, intellectual and psychological abilities as well as the skills they will contribute to building a new society, drawing on the lessons learned from the mistakes made on Earth... Warsaw, 4-6 March 2022 25 students, divided into interdisciplinary groups, begin working on the project of five Martian colonies. They include representatives of geology, law, architecture, design, and culture. Supported by mentors, they try to find answers to the following question: What location on Mars will be the most appropriate for their colony, considering the possibility of easy landing and take-off, access to a water source, as well as the scientific and soil-forming potential of the area? In terms of architecture and design, they must remember about the impact of temperature, sandstorms, harmful radiation, and meteorite strikes, but also make sure the colonies are self-sufficient and provide shelter for thousands of people. Also in the spotlight are such important questions as: How will our senses react on Mars? What do we, as humans, need to survive in an extreme environment? The Mars Colony Hackathon participants also discuss whether they want to transfer to Mars the current Earth culture as well as the economic and political status quo, or... on the contrary? Should they take the current trends in sustainability, climate change, inequality, diversity, and the impact of technology on people into account? What values, traditions and rituals will accompany them? Another sol of 2077 begins.
There are already five colonies on Mars: IGNIS, MARIS, MONADA, M.O.D. AND WEST COAST COLONY. They are all self-sufficient, but willingly cooperate with one another and with Earth in the exchange of goods, know-how as well as education and tourism. They all signed a non-aggression pact. Goods are transported by centrifugal force technology, and people move between colonies on sub-orbital rocket flights. In the close vicinity, inhabitants travel by rovers. We visit the IGNIS colony, located in the Athabasca Valley in the Elysium Planitia region. It arose from a research colony founded in the 2040s by the International Organisation whose inhabitants revolted and declared independence. The main IGNIS doctrine in international relations is not getting involved in the political affairs on Earth. Its inhabitants live in symbiosis with nature, and they base their sustainable development on science. They obtain water thanks from the nearby pingos, and their source of energy is a cosmic solar power plant in a geostationary orbit, sending energy in the form of high-frequency radio beams. The power plant has movable panels, which enable the plant to draw energy throughout the day and night. The inhabitants expect that at a later stage the development of the energy sector will be based on small modular reactors (SMR). The IGNIS system is a hybrid of the republic and direct democracy. Everything that is produced in the colony as well as all the tools and items that the inhabitants use belong to the republic and are used on a shared basis. We continue our journey to visit the MARIS colony, located in Valles Marineris.
As a result of human activities on Earth, the climate crisis deepened, natural resources were depleted, and biodiversity was disappearing. In the social field, we were affected by wars, social inequality, discrimination, and polarisation. The human condition was also deteriorating because of loneliness and civilisation diseases. The founders of MARIS wanted to change that, so they decided to create their Martian colony – a new community based on responsibility and integrity of human beings with the planet, community, and themselves. The local habitat is famous for its hydroponic crops and baths with saunas. The community cares about good mood and mental health of every citizen, which ensures the proper functioning of the entire colony. Therefore, apart from integration, a common dining room, kitchen, or medical, educational and laboratory space, it places great emphasis on providing the inhabitants with private space. As guests, we are invited to one of the capsule-rooms that function as bedrooms. We immediately experience thermal comfort and silence. We can also regulate the amount of light. The whole room is finished with a soft material and there is a pleasant smell in the air... Next sol we travel to the northernmost colony of MONADA, located between Mamers Valles and Deutronilus Mensae.
In some philosophical systems, a monad is a basic substance, on the one hand elemental, permeated with individuality, and on the other hand, rich in various types of capital. It gives almost unlimited development opportunities. The MONADA inhabitants treat their colony as an organism which, having a huge and varied potential, can not only develop independently, but also establish relationships with other entities in the world, which is a continuous collection of elementary substances. Its architectural solutions are also based on spherical units, which are self-sufficient and independent in a crisis, but for the sake of proper functioning of the society they connect with one another to form a network. Each unit has the necessary sectors located on different levels: industry, food production, public utilities, such as hospitals, schools, and religious places, as well as housing. Light runs through each sphere from above and cascades across the room. The radial layout of rooms and internal space can be modified by moving the walls. The colony has one of the largest deposits of magnesium-rich sulphur oxide and olivine as well as access to several rubble glaciers which constitute the source of water. MONADA sells its medicines, steel, solutions related to design and architecture, including modular furniture, “my personal sun” lamps, personalised “Martian wallpapers”, aromatic postcards from Mars as well as a patented circulation system and inter-colonial rover loading system both to the countries on Earth and the Martian colonies. The next stop on our Martian journey is M.O.D. (Martian allotments), located in Dao Vallis.
It is an international, democratic colony, still dependent on the Earth for the supply of certain raw materials and resources. It was built of modular segments created with a 3D printer and completely hidden under the surface of Martian regolith. The main element of the individual residential modules are internal allotments used for garden cultivation, experimenting, and relaxation. The colony focuses on simplicity and minimalism in limited Martian conditions, hence the white walls of the rooms and easy-to-modify segments. The virtual reality used in the colony, however, allows its inhabitants to create an environment that gives a sense of greater security, avatars, or everyday outfits to express themselves and their individual style. Special overalls worn by the inhabitants check their vital functions, hormone levels, and work-life balance simultaneously. M.O.D. conducts intensive research to increase recyclability and the best possible use of limited Martian resources as well as to develop production and plantations that provide the colony with food and vital products. The joint work of the M.O.D. inhabitants strengthen intergenerational ties, giving an opportunity for integration and talks. Each of the inhabitants undergoes compulsory training to be able to work in various sectors of the habitat if necessary. WEST COAST COLONY, located in the Olympus Mont region, is the last stop of our trip.
Separation of powers, peaceful space exploration, cognition and science, high level of education, cooperation between humans and artificial intelligence, transhumanism, and bionics – these are the bases of its functioning. The area chosen by the inhabitants for their colony is convenient not only in terms of living, but also for geological research. The magnesium- and iron-rich basalt rocks present here are a good raw material for construction and the production of soil fertilisers. The colony bases its economy and exports on them. The colony is highly automated. Robots are used in the transport of raw materials and products from/to factories, the production of modular elements for housing, cultivation, services, and even administration. The West Coast Colony inhabitants believe that as humans we have certain limitations, and we must constantly overcome our weaknesses. Therefore, they focus on transhumanism and gene improvement in such a way as to adapt the human body to the difficult Martian conditions. They also place great emphasis on inclusiveness, cultural and social life, common rituals as well as education and learning the truth about the universe. The colony also includes green zones for rest and recreation with plants brought from Earth... Warsaw, 6 March 2022 We are going back to Earth. There is a war going on across our eastern border and climate change brings us intense winds, rains, earthquakes, and volcanic eruptions... Some people question the sense of organising such design and humanist workshops or hackathons. But maybe travelling to Mars in our imagination will help us see and express what we do not like here on Earth, change the things that should be changed or even adopt a completely different approach to things we know? Is it not thanks to our dreams and imagination that we are able to look into the future and create the world we want to live in? Not only on Mars, but also here on our planet Earth... The Mars Colony Hackathon was organised by the US Embassy and the European Space Foundation in cooperation with the Polish Space Agency and Venture Café. The workshop took place on 4-6 March 2022 at the Cambridge Innovation Centre in Warsaw. Congratulations to the winning team members: MONADA – Julia Jeka, Karolina Kruszewska, Tomasz Leonik, Oliwia Mandrela and Kamil Serafin. *Blog also published on the European Space Foundation website This blog is promoted and supported by the:
Author: Chris YuanMember of the InnovaSpace Board of Advisors; CoFounder Planet Expedition Commander Academy (PECA), Explorers Club member, Space Dreamer... "Bang bang bang, bang bang," there was a knocking sound from the water. This is an 18-foot-deep pool in the diving hall of Nanning City Gymnasium in Guangxi. Two PECA (Planet Expedition Command Academy) trainees: Hannah and Selina, wearing scuba diving gear, are stitching together a satellite model underwater, which is designed with PVC pipes of different colours that are removable and can be spliced together. This training involves scuba divers simulating the role of space station EVA astronauts, capturing and repairing damaged satellites. The person under training must maintain neutral buoyancy during the whole process and retain sober analytical and hands-on ability under the conditions of maintaining air consumption, completing the assembly of the satellite model and bringing it out of the water. Hannah and Selina are mother and daughter, and Selina had just graduated from college and planned to have a gap year. The pair chose to participate in the 3-month PECA general training course. The scene just described was their training subject for PECA's second physical space, Ocean Planet: astronauts completing space missions in a simulated weightless state. They started from scratch and had already successfully completed the first physical space: Earth-Mountain Exploration, in which they completed a 10-day cross-country horseback trek on the Qinghai-Tibet Plateau, and finally entered Tibet on horseback, after completing 235 kilometres of horseback riding. Finally they arrived in Guangxi, China and experienced a lot of confined water training, cave diving, to adapt to the exploration of the underwater world, and simulate future space travel. Selina had no previous experience with such a wide range of different exploration types, and when asked if she worried about whether she would be up to the challenges of the training, she said: "I chose to take this step, that is, I chose to face the unknown changes." The PECA curriculum has been seeking a path that connects the ordinary person at one end, with at the other end the coming age of great sailing for civilian space exploration (see also previous blog). Space exploration in the minds of most people is a national strategy, a game for a few people financially supported by the government, and super-rich people. Several of my friends have asked me a similar question, a pointed question:
"How do you think that space travel can become a majority movement in the future? How is their training program different from official astronauts?" Allow me to start with a story. Fifteen years ago, I rode a mountain bike alone from the Ger-mud area of Qinghai to Lhasa, Tibet, and then continued on until I reached the base camp of Mount Everest. This is the highest road in the world. My journey lasted 40 days, was 2200km and ended at the highest altitude of the Everest Base Camp. I later wrote a book "Through Your Eyes, See My Soul - 40 Days of Everest Ride". Some readers asked me the same question: "What is the most important prerequisite for a beginner who will ride the Qinghai-Tibet line? Sufficient money or physical reserves?" After thinking carefully, I replied: Neither of the two you mentioned are the most important, the most important thing is the ambition you have to go, it's the determination, it's the emotion. With that first push, money and other things follow." Think about it, it took only 66 years from the Wright brothers first successful test flight of their plane to the landing of a man on the Moon! Author: Nelson VinagreAerospace Exercise Physiology & Rehabilitation Lead; Coordinator, Portuguese Hub - InnovaSpace Não sou tão velho assim nem tão novo, mas já vivi suficientemente para ter muitas experiências em ambientes extremos e radicais, onde pudéssemos observar a resposta fisiológica do corpo humano exposto a estas diferentes situações. Em minha história esportiva, trago a natação como base de meu treinamento fisiológico, onde durante anos treinei para competições e depois que me tornei educador físico, treinador, instrutor em salvamento aquático e pesquisador nas áreas do treinamento. Assim, pude compreender ainda melhor muitas reações que se passavam comigo e com as pessoas com quem eu trabalhava. Como hobby e amante do esporte, fiz parte de uma geração que ajudou a quebrar os tabus da imagem do surf, que era considerado esporte de malandro, e que hoje veio a se tornar esporte olímpico e modalidade profissional. Nos anos 90, além de ter realizados treinamentos de mergulho com garrafa, na famosa Escola Superior de Esportes de Colônia/Alemanha (Deutsche Sport Hochschule), pude realizar mergulhos na costa brasileira tanto com garrafa quanto com snorkel no Pantanal, em Bonito, no Mato Grosso do Sul, em meio as Piraputangas. Paralelamente a vida acadêmica que se iniciava, a partir dos 17 anos me dedicava intensamente as lides aéreas, onde pretendia me tornar aeronauta e piloto profissional de linhas aéreas. Foram muitos anos de dedicação teórico-prática, fazendo minhas licenças de piloto planador, privado, comercial, instrumentos, multi-motor, rebocador e agrícola, que me remeteram a algumas centenas de horas de voo e ainda mais pousos e decolagens, especialmente pela operação de planadores, que exigia de mim, como rebocador, múltiplas subidas e descidas em curto espaço de tempo. Nessa situação, apesar de estarmos atuando dentro de uma altitude fisiológica, certamente impunha ao meu organismo um condicionamento físico razoável dado pela resposta hemodinâmica, proprioceptiva, vestibular... Nos diferentes locais onde atuei profissionalmente, pude perceber que sou plenamente adaptável a distintos ambientes. Parti de Porto Alegre 1993 rumo a Serra Gaúcha, que além de ser uma das regiões mais frias do Brasil, encontra-se a 1000m de altitude, requerendo de nosso organismo certa adaptação em relação ao nível do mar. Na busca de novos desafios desportivos, inovadores e de interação com o meio, lá estávamos a descobrir nova modalidade que no Brasil ainda não havia ressonância, o rafting que pela primeira vez realizava uma competição no Vale do Paranhana. Depois desse período de “treinamento e exposição a temperaturas mais baixas” por 14 meses, mudei-me para a Alemanha em função do estágio acadêmico no departamento de esportes de inverno da famosa Escola de Colônia, em pleno inverno, tendo que me adaptar abruptamente do auge do verão brasileiro para temperaturas constantemente abaixo de zero e uma realidade climática completamente diferente a encontrada no Brasil, ainda que viesse de uma região sub tropical. Na década seguinte e com novos desafios acadêmicos profissionais no Brasil, tive a incumbência de coordenar um curso na Amazônia Ocidental, mais precisamente no Estado de Rondônia, próximo à fronteira do Brasil com a Bolívia, onde as temperaturas se aproximavam da casa dos 44 graus Celsius e a umidade relativa média do ar era superior aos 70%, para não falarmos das questões da saturação de litometeoros no ar, ocasionado pela fumaça em excesso gerada por grandes queimadas. Novas fronteiras acadêmicas e desportivas surgiram e, de volta a Alemanha, tive a possibilidade de aprofundar minha carreira profissional junto à Agência Espacial Alemã (DLR) e ao Departamento de Medicina Desportiva da Universidade de Göttingen. Com ambas instituições, realizei meu aprofundamento cientifico junto aos desportos adaptados e inclusivos. Já são mais de 14 anos enxergando o movimento humano sobre outra perspectiva, seja do ponto de vista das limitações fisiológica e biomecânicas, seja psicossocial, seja das transferências tecnológicas, mas acima de tudo, partindo da percepção de um continuum desenvolvimental. Novos ventos, literalmente, desta vez me levaram ao ponto mais Ocidental da Europa, de onde escrevo este mais recente relato de experiencia desportiva de minha vida, a regata marítima que, diga-se de passagem, em muito tem a ver com o voo à vela. Essa nova experiencia me remeteu a um novo ambiente, do qual se pode extrair inúmeras reações comportamentais (psycho-enviroment behavior) e fisiológicas, a partir uma vivência que em muito pode nos ajudar na realização de novos experimentos e a entender o que se passa fisiologicamente com nosso organismo nos processos de desorientação espacial e os efeitos indesejáveis por ela gerados.
Author: Chris YuanCoFounder Planet Expedition Commander Academy, Explorers Club member, and Space Dreamer...
Author: Karin Brünnemann, PMP®Karin Brünnemann is PMI Slovakia’s first interplanetary project manager. Karin has more than 25 years of experience managing global strategic projects. She helps companies during phases of cultural change and digital transformation. Apart from being a PMP®, Karin is also a certified trainer for intercultural management. She is currently using her project management expertise in her work as a Flight Planner for the Austrian Space Forum’s AMADEE-20 analog Mars mission. The Hydronaut project is an underwater habitat that started operations in 2020 and is currently the scene for analog space research. Dr. Miroslav Rozloznik, a Flight Planner for the Austrian Space Forum, conducted an underwater analog space mission in 2021 that was fully dedicated to science. The week-long mission, in which three analog astronauts participated, included a two-day underwater stay, and featured an EVA. Scientist-on-Board, Dr. Miroslav Rozloznik from Slovakia, conducted numerous experiments in the areas of physiology, microbiology, medicine, and space psychology. Dr. Rozloznik explained “Conducting underwater analog missions complements Moon or Mars simulations in land-based habitats. While we might not be able to test rovers, drones, or rock sampling procedures, the feeling in the underwater habitat is much more space-like. I felt very detached from Earth, even the support diver appeared like an alien, when he was looking into our porthole, dressed in his diving suit. The underwater habitat also offers the possibility to simulate more complex conditions like long periods of darkness, or variation in temperature and humidity. Furthermore, the ‘psychological safety net’ of being able to open the door and get help in case something happens, is not there. We can leave the habitat but will face several hours of decompression in cold water before we are back in a safe environment.” Part of the underwater experiments focused on the internal environment of the habitat, gathering data relating to air quality, temperature, humidity, and the microbiology of the habitat. Another area of research was dedicated to the medical and physiological well-being of the divers. Dr. Rozloznik tested novel diagnostic instruments, for example, a remote stethoscope that transmitted real-time heartbeat and breathing rates to a doctor located in the mission control center. Such equipment will be very useful for future space exploration and also has many applications for telemedicine on Earth. The crew also tested various biosensors, allowing for comparison and cross-link between physiological, neurophysiological, and psychological measurements. Author: Karin Brünnemann, PMP®Karin Brünnemann is PMI Slovakia’s first interplanetary project manager. Karin has more than 25 years of experience managing global strategic projects. She helps companies during phases of cultural change and digital transformation. Apart from being a PMP®, Karin is also a certified trainer for intercultural management. She is currently using her project management expertise in her work as a Flight Planner for the Austrian Space Forum’s AMADEE-20 analog Mars mission.
The AMADEE-20 analog Mars mission took place in Israel’s Negev desert during October 2021. Over the course of four weeks, an international crew of six analog astronauts conducted a number of experiments to study human behaviour and well-being; tested technical equipment, vehicles, and space suits; and deployed platforms and procedures in the areas of geoscience and life detection. A further aim of this Mars simulation was the development of a state-of-the-art Mission Support structure. I joined the AMADEE-20 team as a Flight Planner two years ago. In this role, I have been using my project management skills to help prepare and conduct scientific experiments as a member of the Mission Support team. Each experiment can be viewed as a subproject in itself and needs to be managed meticulously. There are many similarities between my work as a Project Manager on Earth and my assignment as a Flight Planner for the analog Mars mission. To begin with, a Mars mission, whether simulated or real, is of course, a project. It is humanity’s most challenging, complex, risky, and expensive project. Like any other project, it can be divided into process groups. I started work on the AMADEE-20 Mars simulation during the planning process. One of my main tasks as a Flight Planner at this stage was to obtain a full and very detailed description of the experiments (subprojects) I had been assigned to. The output of these descriptions are documents comparable to a project charter. Since time “on Mars” is very limited during the mission, resources have to be assigned very carefully to the different experiments (subprojects) in order not to run into any resource conflicts. Furthermore, just like international projects on Earth, (analog) astronauts and Mission Support team members will experience cross-cultural differences and will be trained to handle them. One major difference between the projects I am normally working on, and this Mars simulation is the detail to which experiments (subprojects) have to be managed. Usually, I plan tasks for my project teams on a daily basis. For analog Mars projects, we have to plan tasks in time slots of 15 minutes. During a simulated and later real Mars mission, astronauts must wear space suits to protect themselves from the hostile environment on our neighbouring planet. As it takes a long time to put on a space suit and as they are very heavy and not comfortable to wear and work in, the time the astronauts can spend outside their habitat is very limited and therefore, very valuable and must be scheduled in great detail. Another difference is the high risk to human life and well-being, as well as to the safety of the usually very expensive equipment. Communication also poses a big challenge. The entire team has to almost learn a new language, consisting of many acronyms specific to space exploration. Simple Earth-words like “yes” and “no” are not used, since they can easily be misunderstood; we use “affirmative” and “negative” instead to express approval or disagreement.
Despite these differences, as a certified PMP® and trained analog Mars Mission Support team member, I am well prepared to take on this challenge. And as a Project Manager, I am of course, very much enjoying to expand my skills beyond Earth and to be part of creating the future of space travel and project management. If you want to learn more about this analog Mars mission, please visit https://oewf.org/en/portfolio/amadee-20/. If you want to learn more about project management for analog Mars missions, please contact me at karin@4CEE.eu or https://www.linkedin.com/in/karinbrunnemann/. |
Welcometo the InnovaSpace Knowledge Station Categories
All
|