The IDSS docking mechanism can be androgynous, uses low impact technology, and allows both docking and berthing.^[2] It supports both autonomous and piloted docking and features pyrotechnics for contingency undocking. Once mated, the IDSS interface can transfer power, data, commands, air, communication, and in future implementations, will be able to transfer water, fuel, oxidizer and pressurant as well.^[3]

The passage for crew and cargo transfer has a diameter of 0.8 meters (31 in).^[4]

The IDSS has a 2-phase docking procedure consisting of a soft capture and hard capture system.

Active and passive docking roles edit

During a docking maneuver, one vehicle assumes the "active" role and the other vehicle assumes the "passive" role. A particular IDSS port can be manufactured to be able to act in the active role, the passive role, or either role. If a port (e.g., the ones on the ISS) is passive-only, then the other spacecraft must implement the active role. If a port is active-only (e.g., the ports on Crew Dragon and Cargo Dragon, and Starliner), then the other spacecraft must implement the passive role. This means that spacecraft with active-only ports cannot dock with each other using these ports.^[4]

Soft Capture System edit

The soft capture system (SCS) of the active docking system is extended while the passive system remains retracted. Each SCS includes 3 equally spaced petals around the docking ring. As the spacecraft approach each other, the petals on the SCS align the two docking rings and the two become mechanically latched. 6 servo-actuated legs then remove any relative motion and may begin to retract. The use of the SCS allows for 6 degrees of freedom, reducing the accuracy requirement of initial docking procedures.

Hard Capture System edit

Once soft capture is achieved, the hard capture system (HCS) can begin final structural mating. It consists of 12 pairs of mechanical hooks on both the passive and active port. Guide pins are used to ensure accurate alignment of the docking rings to properly allow the hooks to engage. Once the hooks are fully driven, the docking ports' electrical connectors can begin transferring data and the docking procedure is complete. ^[5]

The NASA Docking System is NASA's implementation of the IDSS.^[6] The International Docking Adapter (IDA) converts older Russian APAS-95 docking systems to the International Docking System Standard. IDA implements the passive IDSS role. NASA set June 2016 as the starting date to construct 4 of the NASA Docking System units for the Commercial Crew Development program.^[7] Two International Docking Adapters were added to the International Space Station, and another was destroyed on ascent.^[8] As of September 2023^[update] these ports have been used during nineteen SpaceX Dragon 2 missions and one Boeing Starliner mission.

Boeing Starliner uses the NASA Docking System version of IDSS, implementing the active role.

The ESA's International Berthing and Docking Mechanism is their IDSS compatible docking system.

Lunar Gateway will be assembled in lunar orbit from modules that connect to each other using IDSS ports. Visiting spacecraft (Orion, HLS, GLS) will connect to Gateway using IDSS ports.

In March 2020, Space.com reported that a Chinese crew capsule is possibly IDSS compatible.^[9]

SpaceX designed and implemented an IDSS port for the Crew and Cargo Dragons.^[10] The ports implement the active role.

• http://www.internationaldockingstandard.com/ (Website containing Revision E, October 2016)