If you ever feel like you’re struggling with independence, just remember these creatures who start life with the ultimate “figure it out yourself” kit.
Introducing the “Self-Service Buffet” of the animal kingdom, where the motto is “Hatch, Birth, Good Luck!” These creatures don’t stick around for cuddles or parenting classes:
Sea Turtles – The Ultimate Sand Sprinters: These little guys burst from their eggs and make a mad dash for the ocean, dodging seagulls and crabs. It’s like the world’s most stressful obstacle course, where the prize is simply survival.
Salmon – Swimmers on a Solo Mission: After hatching, young salmon are on their own, navigating the perilous waters without a GPS or even a pep talk. They’ve got more instinct in their little fins than most of us have in our entire body!
Praying Mantises – The Loner Ninjas: These insects hatch ready to rumble, with no parental guidance on how to be the ultimate predator. It’s a tough world where your siblings might just see you as their first meal. Talk about family drama!
Kangaroo Rats – Desert Hoppers Inc.: Born in the harsh desert, these tiny rodents are all about the solo journey from the get-go. No room service or guided tours here; just a lot of hopping and hoping.
Octopuses – The Brainy Solitaires: Octopus moms are the epitome of “do it yourself,” laying their eggs and then, well, signing off. The babies hatch fully equipped with all the smarts and skills they need, making them the envy of every overbooked parent.
Komodo Dragons – The Scaly Independents: These formidable lizards hatch ready to take on the world, with a fierce look in their eye that says, “I didn’t choose the dragon life, the dragon life chose me.”
Butterflies – The Winged Wanderers: From caterpillar to chrysalis, and then to butterfly, these creatures do it all on their own. If butterflies had social media, their status would perpetually be “Just transformed. Who dis?”
A Monarch butterfly freshly emerged from the chrysalis after expanding its crumpled wings.
So, if you ever feel like you’re struggling with independence, just remember these creatures who start life with the ultimate “figure it out yourself” kit. They might just inspire you to tackle your own obstacles – though hopefully, with fewer predators involved.
Copyright 2024 Michael Stephen Wills All Rights Reserved
After 2 pm check in we interrupted unpacking for a sundown beach walk, IPhones and Sony Alpha 700 camera in hand on the last evening of 2019. There is a business on A1A, the main road through town, advertising “beach weddings” and “elopements.” Here, using the 18 – 200 mm f3.5-6.2 lens, I spied this grouping of a mature couple holding hands, minister in attendance, for a wedding ceremony witnessed by young adult children on the right, parents (?) left. The groom’s shorts contrast with the bride’s white gown.
Sunlight, low in the western sky, was perfect for mirror-like reflections in the retreating surf.
A given of the Atlantic beach is the late afternoon light, best for capturing figures against the ocean.
Written below the high tide mark, a message inscribed, impermanent in spite of the deep cuts.
I have practice framing sunsets against beach development. Cannot complain as we enjoy our beach side condo.
A slide show of these images.
Mature Love / Beach VowsCruise Ships Depart Cape Canaveral Late AfternoonTo Each His Own PassionSurf CastingBlack Skimmer Going His Own WayGull ReflectionLast Sunset of 2019Messages in the Sand Washed Away Twice Daily at High Tide
Copyright 2024 All Rights Reserved Michael Stephen Wills
Ever wondered about the iconic robotic arms that gracefully danced in space, tethered to the Space Shuttle? Meet Canadarm, a marvel of engineering that transformed space missions. Born from a NASA invitation to Canada in 1969, this robotic arm did more than just move payloads; it became a symbol of international collaboration in space exploration. After the Columbia disaster, its role expanded, ensuring the safety of astronauts with critical inspections. Dive into the captivating journey of Canadarm, where technology meets the stars. Click to discover how a Canadian innovation became a pivotal part of space history.
The Canadarm is here extended in the foreground and docked in background
The Canadarm, or Canadarm1, officially known as the Shuttle Remote Manipulator System (SRMS) and sometimes referred to as the SSRMS, represents a series of robotic arms utilized aboard the Space Shuttle orbiters. These arms were instrumental in deploying, manipulating, and retrieving payloads. Following the tragic Space Shuttle Columbia disaster, the use of Canadarm became invariably linked with the Orbiter Boom Sensor System (OBSS). The OBSS played a crucial role in examining the shuttle’s exterior for any damages to its thermal protection system, enhancing the safety of subsequent missions.
The genesis of Canada’s involvement in the Space Shuttle program dates back to 1969 when the National Aeronautics and Space Administration (NASA) extended an invitation to Canada. At the outset, the specifics of Canada’s role were unclear, though the need for a manipulator system was immediately recognized as vital. The Canadian firm DSMA ATCON had previously made strides in robotics with the development of a robot designed to load fuel into CANDU nuclear reactors, capturing NASA’s interest. By 1975, a formal agreement was reached between NASA and the Canadian National Research Council (NRC), under which Canada would undertake the development and construction of the Canadarm.
The NRC subsequently awarded the contract for the manipulator to Spar Aerospace (currently known as MDA), under which three distinct systems were to be developed: an engineering model to aid in design and testing, a qualification model for environmental testing to ensure the design’s suitability for space, and a flight unit destined for use in missions. This collaborative effort marked a significant milestone in the use of robotics in space exploration, showcasing international cooperation in advancing space technology.
Copyright 2024 Michael Stephen Wills All Rights Reserved
Here is the fifth in a series of photographs centered on the early history of space flight on Cape Canaveral mostly taken during a tour organized by the Cape Canaveral Lighthouse Foundation. “Google” the foundation for details of future tours. Here we explore the sites of the first launches on the Cape, Launch Complexes 1, 2, 3, 4. (LC 1 – 4).
From Vengeance To Space
Our bus proceeded east on Lighthouse Road past Launch Complexes 21 and 22 in less than half a mile we were within the first sites of the United States Space age, sites with the lowest numbers, LC 1 – 4.
Click Any Image for a larger viewe
If, instead of distance, the bus traveled back in time 68 years to July, 1950 we would be witness to the first United States space launch of the two-stage “Bumper 8”, a former “V2” missile topped by a WAC Corporal that reached 248 miles above the earth, about where the International Space Station circles now.
The Nazi “vengeance weapon 2”, the V2, a device so horrifying British authorities claimed the first V2 attacks to be “gas explosions” rather than admit a Nazi weapon descended without warning. Beginning September, 1944, over 3,000 V2’s landed on London, Antwerp and Liège resulting in an estimated 9,000 deaths, mostly civilians. 12,000 forced labor and concentration camp slaves died in the construction of the production facilities captured by the Soviet Union during the collapse of the Nazis. These victims, arms linked, will form a circle 15.9 miles in circumference around the Bumper 2 launch.
The 21,000 V2 victims, linked arm in arm, make a circle 15.9 miles in circumference.
von Braun and key V2 personnel surrendered to the Americans and, along with enough parts to construct 80 V2s, were taken to the United States. His direction of US missile development lead eventually to the enormous Saturn rocket that lifted three men to the moon, so good came from our bet on vonBraun and the V2.
Observation Bunker
In January, 2018, firmly in the present, our bus approached these now “deactivated” sites driving down Lighthouse Road. Confined to the bus, I used my Canon EOS 1Ds Mark III and the EF 70-300mm f/4-5.6 IS USM lens to capture these scenes.
Looking across Launch Complexes 1 and 2 to Lighthouse Road and the tower. An observation bunker Observation Bunker from Launch Complex 3, looking across Launch Complex 1.
I can almost see someone behind the glass, enjoying a blast of air-conditioned air, dry and cool.
Litter on and around Launch Complex 4
Missile Housing without Engine Radar Parabola FragmentCement Blacked by Rocket Launch Blasts
Aerostat
From 1950 into the 1960’s LC 1-4 saw launches of cruise missiles, some of which were able to maneuver and land on the “skid strip” you can pick out on the “21,000 V2 Victims” image, above. A positive discovery from my research on wikipedia the weapon systems tested here were not fired in anger. Continued development in other places lead to production of generations of cruise missiles launched by Presidents Clinton and Bush against Afghanistan, Iraq and (??) other targets. What victim ghosts, arms linked in ever growing circles, are lurking in our future?
A building on LC 4 has the designation “Aerostat”, one of the last projects supported. I saw an aerostat in action in the early 2000’s over Fort Huachuca, Arizona near the border with Mexico. An aerostat is a flying craft that does not rely on moving air to achieve lift, balloons for example.
The Goodyear blimp is a memory from my childhood on Long Island, the Fort Huachuca aerostat was a smaller version, outfitted with advanced technology for monitoring the surrounding environment. “Google” aerostat mexican border to learn more about the current deployment.
Another view of the abandoned aerostat building on LC 4
With the development of Intercontinental Ballistic Missiles (ICBMs) the facilities of LC 1 – 4 became obsolete. ICBMs are a theme of the next installment of this series.
Sources of information for this post: I used information from the Wikipedia site for the key words V-2, Launch Complex 1, Launch Complex 2, Launch Complex 3, Launch Complex 4. The Bumper 8 launch photograph caption includes a source citation.
Copyright 2024 Michael Stephen Wills All Rights Reserved.
Here is the fourth in a series of photographs centered on the early history of space flight on Cape Canaveral mostly taken during a tour organized by the Cape Canaveral Lighthouse Foundation. Google the foundation for details of future tours. Here we explore the sites closests to the Lighthouse: Launch Complex 21 and 22.
“Vengance Weapons” re-purposed
Vergeltungswaffe 1 (Vengance Weapon 1 AKA V-1), produced at Peenemünde on the Baltic Sea was first used against Great Britan by Germany one week after the D-day landings. 8,025 of these flying bombs, the first cruise missles, caused the death of 22,892 people, mostly civilians. The first cruise missles for the USA were developed less than 1,000 feet away from the lighthouse. After touring the lighthouse we boarded the bus to visit these sites, Launch Complex 21 and 22.
Click Any Image for a larger viewe
Launch Complex 21 and 22 are marked with a labled “pin” on this image from Google Earth.
Nature abounds in Cape Canaveral Air Force Station. This ibis hunted near the lighthouse on our way to Launch Complexes 21,22.
We passed close to the blockhouse first viewed in my post, “Lighthouse and Rockets,” and I captured this detail of the long abandoned structure. The last test launch of a Mace missle was June, 1960.
This wreckage photograph was part of my,“Lighthouse and Rockets” post. It was taken from a lighthouse portal. It is a type of cruise missle, although I cannot identify the exact type, comparing the engine, on the right, with available photographs of the “Bull Goose” and “Mace” missles developed here.
Bull Goose and Mace
Rail launched, as was the German V-1, the missles developed here were called “Bull Goose” and “Mace.” Bull Goose was a delta winged craft intended as a decoy, to appear on radar as a strategic bomber during a nuclear attack. At that time, the rails were in the open. The building here was a revampment of the site for development of the Mace. The other side of this structure is open, the launch rail pointed up from the rear. There are two launch rails, numbered 1 and 2. The building placard is “05961,” the numeral “1” designates site 1. The use of numbers of designate a site is unusual. Letters are used elsewhere on Cape Canaveral and Kennedy Space Center.
The powerful rocket exhause was directed though these pipes. Site 1 is on the right.
Guidance or “Cruise Control”
Navigation is a crucial requirement for cruise missles. The Bull Goose used a gyroscope with no reference to surroundings. The guidance system held the launch bearings, a successful flight was completed within 115 nautical miles of the target.
If deployed, the plan was for thousands of these missles to launch 1 hour before the attack craft set out and 1 hour after. The missles were not armed, but would descend in the thousands around the targets. Similar to what the Germans did to civilians in England.
After three years and 136.5 million dollars the Bull Goose was cancelled because it could not simulate either the B-47 Stratojet or B-52 Stratofortress nuclear bomb delivery aircraft. Not a single decoy was fired in anger.
The building sign “05912” identifies this exhaust tube as being launch site 2.
The Mace, for which this building was created, used a guidance ATRAN (Automatic Terrain Recognition And Navigation, a radar map-matching system). The map was produced on a 35 mm film strip carried on the missle, the live radar returns were “matched” against the film with course correction made for differences. The Mace was of limited usefulness due to the lack of radar maps for target areas within the Soviet Union. The Mace was deployed to Germany and South Korea until phase out in 1969.
Sources of information for this post: I used information from the Wikipedia site for the key words V-1, Launch Complex 21, Launch Complex 22, Mace, Bull Goose.
Copyright 2024 Michael Stephen Wills All Rights Reserved.
Here is the third in a series of photographs centered on the early history of space flight on Cape Canaveral mostly taken during a tour organized by the Cape Canaveral Lighthouse Foundation. Google the foundation for details of future tours. Here we start with Roman Numerals and end with Rocket Research.
Inscribed Roman Numerals
We were lucky to be on this tour, for a period of time the Air Force closed off the Lighthouse. The Lighthouse Foundation obtained permission to start this tour in 2016 (this was January 2018) and I happened to discover it while poking around in preparation for the SpaceX “Falcon Heavy” launch in early February 2018.
As Pam and I climbed, each floor docent (volunteer guide) was so helpful with information and hospitality. At the last floor, the stairway to the upper floors was roped off. Top levels were closed, Cape Canaveral Lighthouse is operational. Here is a photograph of the closed off staircase. There is a roman numeral “6” (VI) inscribed in the staircase column. This is the numbering system described in the first post, “Cape Canaveral Lighthouse,” by which the entire 151-foot lighthouse can be disassembled/reassembled as was done in the 19th century.
Stairway to Upper Floors
The fine finish of the handrail termination for the stairs to upper floors is an example of 19th century attention to detail.
Macro of numeral inscription on a lower floor stairway column.
Roman Numeral 43 on staircase column of lower floor
View of Space History from the Portals
The lower staircase support column was much wider with space for illustrations and displays. Here is a reproduction of a watercolor of the lighthouse from the earliest days of rocketry on the cape. The lighthouse keeper, assistant and their families lived alongside the tower. The housing was later razed. The Lighthouse Foundation is raising money to build reproductions of the housing.
I put my copyright on the photograph to control copying. The copyright does NOT refer to the artwork.
The painting is an accurate representation of the tower. The dark spots are the windows, or portals, captured in my last post, “Lighthouse Details.” Every portal offered a view of historical or current rocketry. In the following photograph, beyond the outbuilding, is a blockhouse, protection for the early rocket scientists, now abandoned. The structure services launch complex 21 and 22. More in a later post.
Wreckage with Recollections of Werner von Braun
Depending on your viewpoint, the landscape around the tower is either littered with or graced by relics such as the wreckage in the following photograph.
As we stood on the exterior staircase, looking toward the building in the following photograph, the docent told a story of Werner von Braun, how he loved to smoke cigarettes and watch rocket tests from the top of the lighthouse. After some spectacular failures, for reasons of personal safety he was excluded from the tower. His office during the development of the Minute Man and Persing missiles was in this building.
Building next to the lighthouse where Werner VonBraun had an office during the early days of USA rocket research.
This view overlooks the former sites of Minute Man and Persing rocket development. Beyond the launch towers is Port Cape Canaveral, visible to the right are large cruise ships.
Viewed from the Cape Canaveral lighthouse, the port i is in the distance with cruise ships.
Looking from portals facing northeast is this view across ICBM road and its many launch sites. We will visit these in a future post.
Viewed from the Cape Canaveral lighthouse, these are active launch sites.
Imagine yourself floating in the vast cargo bay of the Space Shuttle Atlantis, surrounded by the essentials of space exploration. Here, in this dynamic space, the dreams of astronauts and scientists converge, where each mission reshapes our understanding of the universe. Curious? Discover more inside.
The cargo bay of the Space Shuttle Atlantis was an extensive, empty compartment located at the shuttle’s aft end, acting as the main storage area for mission payloads. A significant portion of the cargo was housed within a sizable cylindrical module named Raffaello, which contained a year’s supply of necessities—food, clothing, water, replacement parts, and scientific gear.
The dimensions of the payload area were roughly 4.6 meters (15 feet) in width and 18 meters (60 feet) in length. This spacious area enabled the shuttle to transport a diverse array of payloads, ranging from satellites to complex scientific experiments.
Exploring the Cargo Bay
Envision yourself drifting through the cargo bay of Atlantis, encircled by a maze of wires, equipment, and neatly arranged payloads. Astronauts, tethered securely and clad in their voluminous space suits, would navigate this area, ensuring the payloads were fastened correctly for either launch or retrieval operations.
The cargo bay’s configuration was highly adaptable, tailored to meet the specific needs of each mission. It played a pivotal role in the deployment of satellites, execution of repairs, or the transportation of scientific apparatus, adapting its setup as necessary.
The Hubble Servicing Mission
One of the most notable missions involving Atlantis was the Hubble Space Telescope Servicing Mission 4 (SM4). For this mission, Atlantis was loaded with essential items for the Hubble, including new instruments, batteries, and gyroscopes, all carefully organized within the cargo bay for safe transport to and into orbit.
Legacy
The cargo bay of Atlantis bore witness to a myriad of significant events: the release of satellites, the construction of the International Space Station, and numerous scientific investigations. Its design and flexibility were instrumental to the Space Shuttle program’s achievements.
Copyright 2024 Michael Stephen Wills All Rights Reserved
Portrait of a Sea Turtle with fish, sea floor and a rocket launch. 541 Washington Ave, Cape Canaveral, FL 32920 Near Cheri Down Park, Brevard County, Florida
Portrait of a Sea Turtle with fish, sea floor and a rocket launch. 541 Washington Ave, Cape Canaveral, FL 32920 Near Cheri Down Park, Brevard County, Florida
Along the bottom margin is the artist’s signature, “David Roth 2022.”
Copyright 2024 Michael Stephen Wills All Rights Reserved
Step beyond Earth’s bounds and glimpse the astounding intricacies of the Space Shuttle’s journey. Discover the engineering marvels that propelled humanity into orbit and back, navigating the cosmos with precision. Unveil the secrets of the stars now.
The Space Shuttle, officially known as the Space Transportation System (STS), was an iconic spacecraft operated by NASA from 1981 to 2011. It consisted of an orbiter with wings for landing like an airplane, external fuel tanks, and solid rocket boosters. With its multiple missions ranging from satellite deployment to the construction of the International Space Station, the Space Shuttle was a symbol of human ingenuity in space exploration. Central to the Shuttle’s success was its navigational system, which combined state-of-the-art technology of its time with human expertise.
The navigation of the Space Shuttle was a complex orchestration involving both internal and external elements designed to work in the harsh environment of space. The photographs attached illustrate some of the external navigational elements.
External Navigational Elements
The external surface of the Space Shuttle, as seen in the following images, was covered with thousands of thermal protection system tiles. These tiles were crucial not only for protecting the Shuttle from the extreme temperatures experienced during re-entry into Earth’s atmosphere but also housed the critical sensors for navigation.
Reaction Control System (RCS)
One of the key external navigational features was the Reaction Control System (RCS), seen as clusters of small circular ports below the cockpit windows. The RCS was composed of small thrusters that could fire in short bursts to adjust the Shuttle’s orientation or speed in space. This system was vital during the maneuvers in orbit, such as satellite deployment, docking with the International Space Station, and repositioning for re-entry into Earth’s atmosphere.
Internal Navigational Elements
Internally, the Space Shuttle featured a complex avionics system. The following image depicts part of the orbiter’s internal structure with an array of docking mechanisms and sensor housings. The round port, surrounded by a ring of bolts, is likely an interface for the Orbiter Docking System, used for rendezvous and docking with the International Space Station.
The following image shows a close-up of one of the orbiter’s windows, surrounded by reinforced panels. Each window was crucial for manual navigation, allowing astronauts to visually confirm their orientation and position relative to celestial objects and the Earth. The windows were also essential during landing, which was conducted manually by the Shuttle’s commander.
Navigational Avionics
The Shuttle’s navigation was supported by an avionics system that included inertial measurement units (IMUs), star trackers, and various other sensors. IMUs tracked the Shuttle’s position by measuring its velocity and direction, while star trackers used sightings of known star patterns to calibrate the Shuttle’s orientation in the vastness of space.
The navigational computers onboard processed data from these systems to maintain the trajectory and manage the Shuttle’s multiple systems. The computers were capable of autonomous operation, although astronauts were trained to take over manually if necessary.
Ground Support and Telemetry
In addition to onboard systems, navigation relied heavily on ground-based tracking and data relay satellites. The Shuttle communicated with NASA’s Mission Control Center, which monitored its position and trajectory, providing updates and corrections as needed. Telemetry data sent back to Earth included velocity, altitude, and engine performance metrics, which were crucial for ensuring the Shuttle’s safe passage in and out of orbit.
In Summary
The Space Shuttle’s navigational capabilities were a testament to the integration of technology and human skill. From the RCS ports on its tiled exterior to the sophisticated avionics inside, every component played a critical role in the Shuttle’s missions. This harmonious blend of internal mechanisms and external sensors, complemented by vigilant ground support, enabled the Space Shuttle to navigate the cosmos and return safely home, mission after mission.
Copyright 2024 Michael Stephen Wills All Rights Reserved
Peer through the Space Shuttle’s windows, marvels of human ingenuity that withstood the cosmos’s extremes. Experience the awe of Earth’s view from orbit and the intense blaze of re-entry, all behind the clarity of fused silica glass. Dive into the fusion of science and exploration—read the full voyage of these extraordinary panes.
The windows of the Space Shuttle represent a pinnacle of engineering and material science, intricately designed to withstand the harsh realities of space travel while providing astronauts with a vital connection to the outside universe. The journey of these windows, from concept to creation and through their performance in the harsh environment of space, is a testament to human ingenuity and the relentless pursuit of exploration.
At the heart of the Space Shuttle’s windows is fused silica glass, a material selected for its exceptional properties, including high thermal resistance, strength, and optical clarity. This choice was crucial, as the windows had to endure rapid temperature shifts from the cold vacuum of space to the searing heat of re-entry, which could exceed 1,650 degrees Celsius (3,000 degrees Fahrenheit). Corning Incorporated, known for its innovative glass solutions, was responsible for manufacturing this fused silica, utilizing a high-purity synthesis process that ensured the material could withstand the extreme conditions of space without degrading.
The design and assembly process of the Shuttle’s windows was a feat of engineering. Each window was carefully framed and installed to maintain the spacecraft’s integrity and internal pressure in the vacuum of space. This involved a complex sealing mechanism that had to be both robust and fail-safe, ensuring the safety of the crew and the success of the mission. The installation process was rigorous, involving a series of tests that simulated the harsh conditions of space to validate the windows’ performance. These tests were crucial to identifying and rectifying any potential issues that could compromise the mission or the astronauts’ safety.
In space, the Shuttle’s windows faced numerous challenges, from the threat of micrometeoroid impacts to the intense radiation of the sun. Despite these hazards, the windows performed admirably, a testament to their design and the materials used. One notable instance of their resilience was observed during the STS-61 mission, where despite micrometeoroid impacts, the windows’ integrity remained intact, ensuring the crew’s safety and mission success.
The windows also played a critical role during the Shuttle’s re-entry into Earth’s atmosphere, a phase of the mission that subjected the spacecraft to extreme heat. The windows’ ability to withstand this heat while providing the crew with a clear view for navigation was vital for a safe landing. This was achieved through the use of multiple glass layers and protective coatings, which insulated the interior from the re-entry heat.
Beyond their technical specifications and performance, the Space Shuttle’s windows served a more profound purpose. They provided astronauts with a visual connection to the Earth and space, offering perspectives that few humans have experienced. These views not only aided scientific observation and mission operations but also offered moments of unparalleled beauty, inspiring both astronauts and people on Earth.
The legacy of the Space Shuttle’s windows extends beyond their technical achievements, embodying the spirit of exploration and the human quest for knowledge. They were not merely components of a spacecraft but windows to the universe, enabling us to look beyond our planet and dream of the possibilities that lie in the vast expanse of space. Through their resilience, clarity, and performance, the Space Shuttle’s windows stand as a symbol of human ingenuity, a small but significant part of our journey to the stars.
Copyright 2024 Michael Stephen Wills All Rights Reserved
Michael Stephen Wills Photography 