PRE2017 4 Groep1

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Group members

Thomas Boot 0988095 Industrial Engineering
Jelte Dirks 0908196 Computer Science and Engineering
Maurits van Riezen 1050246 Software Science
Linh Tran 0936651 Electrical Engineering
Roan Weterings 0888129 Psychology and Technology

Planning

The most recent Gantt chart has the most recent approach, planning, milestones, deliverables and task-division overview.

File:OGO Robots Everywhere Gantt V1.pdf

Week 1: The Plan

Brainstorm

Festival Smartwear bag with necessities for First Aid and Organisation personnel. Drone will automatically bring new supplies when necessary.
Extreme Sports/Exploration Smartwear monitors health, etc. Drone will fly in to bring First aid equipment for self-help, location data will be used to send First Aid personnel if necessary.
Cameraman Smartwear monitors heartrate of many or all people at an event. A location with the highest average heartrate has the most exciting event. The drone will fly to the most exciting event to film footage.
Police aid Drone can fly around for easy patrolling, the drone can be sent to a specific location as a scout, the drone has an easier time chasing someone.
Shock band (unethical) People who leave trash anywhere but a recycling bin will get a small shock. The band has an NFC chip for payments within the event so people will wear and use it, eliminating the hassle with plastic chips and coins as well.

Literature Research/State of the Art

User needs, Extreme Sports

Extreme sports in Extreme conditions

Dr. M. Malashenkova (2016), exercise physiologist, has given a definition of extreme sports: “The definition “Extreme” in relation to sport is performed in a hazardous environment and involves great risk. In the modern world of extreme sports, a number of factors require an athlete to have maximum concentration, cope with the stress and physical and emotional mobilisation capabilities. Common to all of these sports are risk-taking, pushing limits (physical and legal) and having fun.” As extreme sports, she recognises: “trekking, paragliding, rock climbing, mountain bike, snorkeling, hot air ballooning, hand gliding, wind surfing, canoeing, sailing, skydiving, surfing, bungee jumping, scuba diving, snowboarding, and skiing” (Malashenkova, 2016). These sports are practiced in a wide variety of locations and in a wide variety of extreme natural conditions to do with “hypoxia, altitude, speed, atmospheric pressure, wind, and temperature”. Some people are capable of adapting to these extreme conditions by increasing functional reserves, though it is unclear if everyone can adapt to such extremes. When conducting research in this area, special attention should be given to safety, medical monitoring, and psychological testing of participants (Malashenkova, 2016).


Sports in extreme conditions: the impact of exercise in cold temperatures on asthma and bronchial hyper-responsiveness in athletes (only abstract available)

Athletes performing outdoor endurance winter sports frequently report exercise-induced asthma (EIA) and bronchial hyperresponsiveness (BHR). EIA is likely caused by the increase in breathing rate; water and heat loss are elevated, and in combination with the increased breathing rate can lead to inflammation of the airways. This can lead to increased parasympathetic nervous activity, likely leading to BHR. Sporters in these conditions ought to be regularly assessed in terms of lung function and BHR. These conditions can be alleviated or cured with medicinal treatment (Carlsen, 2012).


Extreme sports: Extreme physiology. Exercise‐induced pulmonary oedema (only abstract available)

During an extreme triathlon event in australia, certain participants were afflicted with dyspnoea (shortness of breath for an abnormal duration), haemoptysis (coughing up blood), and pulmonary oedema (fluid accumulation in the lungs) (Ma and Dutch, 2013).


Sports and extreme conditions. Cardiovascular incidence in long term exertion and extreme temperatures (heat, cold) (only abstract available)

Extreme sports tend to result in a higher body temperature and more sweating, which can result in dehydration and therefore a lower blood volume. This dehydration can also lead to an inability to regulate body temperature leading to thermal stress and injury such as heat stroke. Extended periods of sweating can lead to hyponatremia; decreased sodium concentration in one’s blood, leading to headaches, nausea, balancing issues, confusion, seizures and coma. Chances of thermal stress due to heat (hyperthermia) can be increased by a hot environment, as well as elevated levels of air humidity. Cold temperatures can result in hypothermia and frostbite (Melin, and Savourey, 2001).


Emerging Environmental and Weather Challenges in Outdoor Sports

Because of climate change effects seen around the globe, current advice concerning extreme sports in extreme environments may well have become insufficient. plain weather indications no longer allow for an accurate estimation of heat or cold related illnesses and injuries. Several environmental and weather challenges include:

  • Heat (treat heat related illnesses by developing cardiorespiratory fitness, using pre-cooling and ingestion of cold air, water or ice, acclimatization, and hydration and salt balance strategies)
  • Ultraviolet exposure (skin cancers and sunburn, use sunscreen and UVR (Ultra Violet Ray) protective textiles.)
  • Lightning (lethal injuries, use weather reports, taking shelter if necessary)
  • Air pollution (deteriorating lung functionality, inflammation, immune system issues, bronchitis, asthma, etc.) (higher fitness level, train away from cars)
  • Cold (hypothermia, frostbite, asthma, cardiovascular events, hallucinations, exacerbation through hypoxia, use protective clothing to prevent heat loss, no constricting clothing)
  • Altitude (lower or higher pressure, hypoxia, high altitude sicknesses: pulmonary edema, cerebral edema. Use altitude acclimatization.)
  • Snow and avalanche (asphyxia, compression, hypercapnia, hypoxia, use education, safety gears)
  • Exercise induced asthma and bronchial hyperresponsiveness (use pollen distribution forecasts, antihistamines, immunotherapy, air acclimatisation gear (for cold air))

(Brocherie, Girard, and Millet, 2015).


Extreme Sports: Injuries and Medical Coverage

Common injuries sustained from extreme sports include: head injury, wrist injury, fractures, internal injuries, microtrauma to the scrotum, ankle injury, knee injury, overuse injury, stress fractures, ligament and tendon injury, finger injury, concussion, abdominal injury, sunburn, dehydration, hyponatremia, and sleep deprivation. Some new extreme sports even include marathons on the south pole, or in the desert. Protective gear is advised to help alleviate some risk factors. There is a need for better medical coverage, better design of protective equipment, and assistance in event planning. currently it is difficult to handle injuries during a race, and equally difficult to arrange evacuations, because medical personnel needs the same advanced skills as the participants to reach them (Young, 2002).


Extreme Sports as a Precursor to Environmental Sustainability

Extreme sports gained a reputation for being for risk seeking adrenaline junkies, without much recognition for how extreme sports influence one’s relationship with the natural world. The reason to participate in extreme sports is not as shallow as just the adrenaline rush; they trigger deep personal changes in courage and humility amongst other construct (Brymer & Oades, 2009). The emphasis lies on how the sports change the relationship with nature, and how it is experienced (Brymer, Downey & Gray, 2009).

Performing in extreme sports works as a demonstration of human power, resilience, and robustness, which is done because society makes people feel powerless and insignificant. (Le Breton, 2000; Palmer, 2000). According to people in favour of ecopsychology, activities in nature are beneficial to psychological well being. They help kickstart combating environmental problems because they increase interest in the natural world beyond seeing it as a mere resource. This is because these activities help us recognise and realise we are part of the natural world, which helps people to actually adopt more environmentally sustainable practices (Brymer, Downey & Gray, 2009). This means participating in extreme sports would be beneficial to society, the environment, and individuals; provided it can be done in a safer or more controlled manner.


The extreme sports experience: A research report

Participants of extreme sports tend to report 5 main aspects of and/or reasons for participating; Commitment and skill (high levels of preparation and practice) Defining the boundaries (high risk, limited outcome possibilities) On risk (labeling them as risk or thrill seekers is “missing the point”) Feelings of accomplishment and personal insight (“empowering and making life easier to deal with Extraordinary experiences akin to Maslow’s peak experiences (“altered perceptions of time and space, floating and flying, calm and stillness, and self validation experiences” The conclusion is that extreme sports are not about risk taking, according to participants (Brymer, 2009).

Summarised User needs:

  • Experiencing raw, awe-inspiring nature
  • Proving one's own skills to oneself
  • Acquiring mental health benefits
  • Being reached by First aid in an easier way
  • Less risk from:

- Altitude/Atmospheric pressure

- Temperature

- Hypoxia/Hypercapnnia

- Exercise-induced Asthma/Broncial Hyperresponsiveness

- Dyspnoea

- Haemoptysis

- Pulmonary oedema

- Hyponatremia

- Injuries and Fractrures

References

Brocherie, F., Girard, O., & Millet, G. P. (2015). Emerging environmental and weather challenges in outdoor sports. Climate, 3(3), 492-521.

Brymer, E. (2009). The extreme sports experience: a research report. IFPRA world, 6-7.

Brymer, E., Downey, G., & Gray, T. (2009). Extreme sports as a precursor to environmental sustainability. Journal of Sport & Tourism, 14(2-3), 193-204.

Carlsen, K. H. (2012). Sports in extreme conditions: the impact of exercise in cold temperatures on asthma and bronchial hyper-responsiveness in athletes. Br J Sports Med, 46(11), 796-799.

Ma, J. L. G., & Dutch, M. J. (2013). Extreme sports: Extreme physiology. Exercise‐induced pulmonary oedema. Emergency Medicine Australasia, 25(4), 368-371.

Malashenkova, M. (2016, October). Extreme sports in Extreme conditions. Paper presented at ITP Sport, Exercise & Health Research Symposium, Institute of Sport & Adventure (ISA), Otago Polytechnic (OP).

Melin, B., & Savourey, G. (2001). Sports and extreme conditions. Cardiovascular incidence in long term exertion and extreme temperatures (heat, cold). La Revue du praticien, 51(12 Suppl), S28-30.

Young, C. C. (2002). Extreme sports: injuries and medical coverage. Current sports medicine reports, 1(5), 306-311.


User needs, Space Exploration

Constraints, Smart Wear

Sensors, Non-Invasive

Sensors, Invasive

Problem Statement

Extreme sporters find themselves in dangerous situations, and are hard to reach when they are in danger. Our combination of a drone and smartwear will monitor their health, warn them in time of potential dangers, and send help when necessary.

Objectives

  • Creating smart sportswear with sensors to decide if there are any risks or problems
  • The smartwear must be able to at least monitor the vital functions: breathing, circulation, and consciousness.
  • The smartwear should be able to send preventive warnings
  • The smartwear needs a location tracker (GPS), and have a microphone and speaker to be able to contact medical personnel if necessary. The drone needs a GPS, microphone, speaker, and camera in order to be eyes on site for the medical personnel.

Week 2

Week 3

Week 4

Week 5

Week 6

Week 7

Week 8

Week 9

Results