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Orbital Embrace: The Art and Science of Spacecraft Docking
The Axiom-4 spacecraft will dock with the ISS at around 4:30 PM IST.
Axiom 4 Mission: Today marks a golden chapter in India's space journey. At exactly 12:01 PM IST (2:31 AM EDT), Group Captain Shubhanshu Shukla lifted off aboard the Axiom-4 mission from NASA's Kennedy Space Center in Florida, becoming the first Indian astronaut to travel to the International Space Station (ISS).
The spacecraft is scheduled to dock with the ISS at around 4:30 PM IST (7:00 AM EDT) on Thursday, June 26, after nearly 28 hours in space. This mission is more than just a personal triumph for Shukla—it is a proud milestone for India in international space collaboration.
As Shukla journeys toward the ISS, it's worth exploring the fascinating and complex process that will connect his spacecraft to humanity's orbital home; spacecraft docking. What Is Spacecraft Docking?
Imagine trying to park your car in a garage—except both the car and the garage are moving around Earth at 28,000 kilometers per hour. Docking is the incredibly precise process of linking a visiting spacecraft with the space station to form a safe, airtight bridge that astronauts can use to move between them.
The ISS has multiple docking ports—standardized connection points designed to accommodate different spacecraft from around the world, much like a universal charging port.
The Journey to Connection
Before docking can happen, a spacecraft must find and approach the station through a process called rendezvous This phase requires extremely accurate navigation and control.
The Approach Phase
Using radar systems, cameras, and antennas, the spacecraft locates the ISS and begins its approach. Every move must be carefully calculated—this is like playing a complex game of 3D chess in space. A single misstep could risk collision and endanger the mission.
Two Types of Docking
Different missions use different methods, depending on the type of spacecraft involved:
Cargo Vehicles: The Gentle Touch
Uncrewed cargo ships use a method called berthing. These ships hover close to the ISS, where astronauts use a robotic arm to gently capture and guide them to a port. This method reduces risk to fragile equipment onboard.
Crewed Vehicles: Direct Docking
Spacecraft carrying astronauts use automated docking systems to connect directly with the station. This approach is faster and safer in emergencies, allowing quick access to the ISS without external help.
SpaceX's Crew Dragon: A Technological Leap
Today's Axiom-4 mission uses SpaceX's Crew Dragon—a cutting-edge spacecraft that showcases the next generation of docking technology.
Equipped with cameras, sensors, and onboard computers, Dragon performs docking autonomously, constantly adjusting its course in real-time. While astronauts can take manual control, the system is built to complete the task on its own.
This Dragon capsule—the fifth and final one in SpaceX's current active rotation—will be officially named by the crew once in orbit. It docks with the International Docking Adapter, a modern standard built for international cooperation in space.
Inside the Docking Mechanism
Docking may seem seamless, but it's a highly engineered process involving: Three Phases of Docking Soft Docking: A probe from the spacecraft latches into a cone-shaped 'drogue' on the ISS—this is the first contact. Load Attenuation: Springs and dampeners absorb the shock, ensuring stability without damage. Hard Docking: The spacecraft is pulled tightly into place, forming an airtight, rigid connection.Docking Systems Around the World Docking Systems Around the World – How Spacecraft Connect to the ISS
The International Space Station (ISS) is like a large space home that welcomes astronauts and cargo from different countries. Each visiting spacecraft needs a way to safely connect, or 'dock,' with the ISS. Different types of docking systems are used depending on the country and purpose of the mission. Here's a simple look at the main systems:
This is one of the oldest and most reliable docking systems in space history. It's used by Russia's Soyuz spacecraft (which carry astronauts) and Progress spacecraft (which bring cargo).
The system works like this: a long probe from the spacecraft slides into a cone-shaped opening called a drogue on the ISS. It then locks in place securely. This docking is usually automatic and has been working well since the early days of human spaceflight. This is a universal docking system—like a common charger—that lets modern spacecraft from different countries connect to the ISS safely. It's used by SpaceX's Crew Dragon and Boeing's Starliner, both of which carry astronauts. The spacecraft automatically lines itself up with the ISS using cameras and sensors, then gently docks without needing manual help. IDS was made so that any future spacecraft from around the world can also use it, making space travel more connected and cooperative. It's fast, safe, and allows for quick departure in emergencies.
This system is mainly used for uncrewed cargo missions, like Northrop Grumman's Cygnus spacecraft. Instead of docking by itself, the cargo ship floats close to the ISS, and a robotic arm operated by astronauts grabs it and attaches it firmly to the station.
This is called 'berthing' instead of docking. It's a slower but very precise process, and it helps bring large cargo loads to the station.
Together, these systems make sure that all kinds of spacecraft—whether old or new, Russian or American, crewed or cargo—can safely reach the ISS and support life and research in space. A Constant Flow of Traffic
The ISS functions like a busy harbor in space. At any time, it may host several spacecraft—including SpaceX Dragons, Russian Soyuz, and Progress ships—all docked together.
This non-stop traffic supplies the station with food, water, spare parts, and scientific equipment, and allows for regular crew rotations, ensuring smooth operations on board.
The Future of Docking
Space docking is evolving. Missions to the Moon, Mars, and beyond will demand more sophisticated and flexible systems. The knowledge gained from ISS missions like Axiom-4 is already shaping the next era of space infrastructure. A Symbol of Joy—and Progress
Shortly after reaching orbit, a plush toy named 'Joy' floated into the Dragon cabin—a tradition in spaceflight symbolizing the onset of microgravity. It's a charming gesture that reflects the wonder and optimism of space exploration.
As Shubhanshu Shukla prepares to dock with the ISS, he joins the elite group of astronauts who have helped extend humanity's reach beyond Earth. For India, this is more than just a space mission—it's a symbol of its rising stature in the global space community.
So, the next time you glance at the night sky and spot the ISS drifting silently across the stars, remember: it's not just a spacecraft—it's the beating heart of humanity's shared future in space.
( Girish Linganna is an award-winning science communicator and a Defence, Aerospace & Geopolitical Analyst. He is also the Managing Director of ADD Engineering Components India Pvt. Ltd., a subsidiary of ADD Engineering GmbH, Germany. Contact: girishlinganna@ )
