Engineering/34 Years Of Strandbeest Evolution
34 Years Of Strandbeest Evolution

34 Years Of Strandbeest Evolution

Veritasium21 minDec 7, 2024
This is a Strandbeest. It's a walking skeleton that's powered only by the wind, created by Dutch inventor Theo Jansen.
14 chapters
  • Introduction to Strandbeests(0'001'26)
    Walking skeletons powered only by wind with no motors or electronics, created by Dutch inventor Theo Jansen.
    Made from unconventional materials including tape, glue, snot, and screws that transfer force effectively.
    The Strandbeest has become notable enough to appear on The Simpsons, blurring the line between science and art.
    Theo Jansen promised himself to spend one year on the tubes in 1990, but the project grew far beyond that initial timeline.
  • Overcoming Structural Challenges(1'262'40)
    Early Strandbeests could only lie on their backs with moving legs due to weak connections made with Sellotape.
    Jansen replaced tape with zip ties, creating a much stronger and cleaner connection system.
    Jansen restricted himself to only a few basic materials to maintain simplicity and elegance in his designs.
    Five additional hurdles remained to achieve Jansen's vision of Strandbeests surviving independently on the beach.
  • Finding the Perfect Footpath(2'404'34)
    The path traced by the foot must be mostly flat at the bottom for the Strandbeest to maintain balance and walk properly.
    Jansen wrote a computer program in 1990 to calculate footpaths, but brute force testing would take 100,000 years.
    • Started with 1,500 different combinations of tube proportions • Selected combinations with flatter footpaths to reproduce with slight variations • Ran simulation for months until discovering 13 holy numbers
    The 13 holy numbers describe the proportions and placements of all tubes, forming the genetic code used by nearly every Strandbeest for over 30 years.
  • Achieving Smooth Locomotion(4'347'02)
    Three legs connect together, each offset by 120 degrees from the others, ensuring continuous contact with the ground.
    This offset arrangement produces a continuous smooth walk rather than a rigid robotic movement pattern.
    Adam Savage's experience building a Strandbeest showed that even small errors in linkage lengths can prevent proper walking.
    When proportions are correct, the Strandbeest walks smoothly; when adjusted properly, it transforms from non-functional to perfectly mobile instantly.
  • Adapting to Beach Conditions(7'029'00)
    Fluffy sand easily buries thin feet, causing Strandbeests to get stuck and unable to move.
    • Developed large surface area feet instead of simple sticks • Added wires to increase contact time with the ground • This prevents feet from sinking while ensuring smooth transitions
    Flexible joints between ankle and foot allow proper weight distribution and smooth gait without excessive pressure on the structure.
    Extended stationary periods allow sand to cover Strandbeests, inspiring the evolution of flying variants that lift slightly to let sand pass underneath.
  • Collective Survival Strategies(9'0011'46)
    Individual Strandbeests blow over easily in strong winds, but groups holding each other together provide mutual support and strength.
    Some Strandbeests were designed to be pulled by other Strandbeests, allowing the group to move as a coordinated unit.
    Working together, Strandbeests can overcome challenges that would be impossible for individuals to survive.
    Derek personally pulled a Strandbeest up a Dutch beach with another one following, demonstrating the practical application of this design.
  • Energy Storage and Activation(11'4614'30)
    Strandbeests can only walk when wind is present; they become immobile when wind dies down, limiting their effectiveness.
    • A sail catches wind and turns a crankshaft • The crankshaft pushes a piston that compresses air • Pressurized air stores in plastic bottles at up to 5 bars
    Pressurized air connected to pumps creates artificial muscles that can push or pull, enabling movement independent of current wind.
    Different applications include crawling, walking with self-propulsion, and tail wagging, mimicking biological muscle functions.
  • Developing Sensory Systems(14'3016'01)
    Strandbeests are blind and deaf, unable to sense their surroundings or prevent themselves from walking into the water.
    • A water feeler hovers at ground height and continuously sucks in air • When touching seawater, the device swallows water and detects resistance • This sensory input can trigger course correction
    Strandbeests need a nervous system to process sensory inputs, make decisions, and command muscles to respond appropriately.
    Theo constructed pneumatic nerve cells that function like logic gates, using pistons and valves to switch air flow on and off, mimicking binary computation.
  • Building a Mechanical Brain(16'0117'40)
    Pneumatic valves can invert signals, switching zeros and ones just like computer logic gates for processing information.
    Only about 20 nerve cells would be needed for a Strandbeest to detect water and turn away from it.
    Sand creeping into mechanical components makes construction extremely difficult despite the relatively simple logic required.
    Each challenge overcomes pushes Strandbeests closer to animal-like biology, following similar evolutionary patterns that life on Earth experienced.
  • Degradation and Sustainability(17'4018'14)
    Strandbeests gradually lose color and parts break off over time due to exposure to beach elements.
    Small amounts of microplastic pollution result from this degradation, though not on the scale of global concerns.
    • Almost all parts are reused in new creations • Damaged pieces are sold as fossils to collectors • Broken Strandbeests go to a graveyard for historical preservation
    One person's decades-long obsession has created an entire ecosystem of machines that continue to evolve and inspire.
  • The Original Motivation(18'1419'18)
    During the late 1980s, rising carbon dioxide levels made it clear that sea levels would rise by 2.2 meters by 2100.
    About a third of the Netherlands lies below current sea level, making rising sea levels an existential threat to the nation.
    Theo's idea was to use wind-powered Strandbeests to kick up sand while walking, pushing it toward dunes to heighten them and protect coastlines.
    Jansen published his concept in de Volkskrant newspaper under the name Strandbeest, Dutch for beach beast.
  • From Vision to Obsession(19'1820'05)
    A newspaper article about protecting the Netherlands evolved into a lifetime pursuit that now defines Theo Jansen's entire existence.
    The original coastal protection goal has given way to a more fundamental human need: the desire to be remembered after death.
    Jansen's goal is for Strandbeests to eventually live independently on beaches, allowing him to die with peace of mind knowing his creation survives.
    Jansen acknowledges he doesn't have millions of years to achieve his vision but hopes to inspire young people to continue the work through his infectious enthusiasm.
  • Global Spreading of Genetic Code(20'0521'05)
    Thousands of people worldwide are incorporating Theo's 13 holy numbers into their own Strandbeest designs and variations.
    • Miniature Strandbeests for small-scale displays • Rideable versions for human passengers • Walking bicycles combining human and wind power
    Unlike Theo's own strict design rules, he allows others complete creative freedom to build and modify Strandbeests as they wish.
    Theo's lack of control over others' designs represents a beautiful open-source approach where he simply enjoys seeing his creations come to life globally.
  • Future Vision and Legacy(21'0521'39)
    Strandbeests may one day achieve complete independence, roaming world beaches and kicking up sand along coastlines.
    These artificial creatures could potentially protect coastlines from rising sea levels, fulfilling Theo's original vision from 30+ years ago.
    The vision is of Strandbeests becoming a new form of life on Earth, distinct from biology yet alive in their own mechanical way.
    What began as one person's creative obsession has evolved into a distributed global phenomenon with potential real-world environmental benefits.