Comment by Scoundreller

In the context of the full article (https://en.wikipedia.org/wiki/Iridium_satellite_constellatio...), it's clear they're talking about the polar orbits used by the Iridium constellation, which have "seams" around the Atlantic and the Pacific as the "first" set of satellites passing north-to-south overlap with the "last" set of satellites coming back south-to-north on the other side of their orbits. So of the 6 orbital planes used by the Iridium satellites, each plane covers 1/12th of the globe for each "half" of its over-the-poles orbit. So there are two "seams" where handoff is not supported, one off the eastern seaboard and one roughly over Japan.

There's an animation on linked article that explains this pretty well: https://upload.wikimedia.org/wikipedia/commons/thumb/9/90/Ir...

The Iridium satellites are in what you might call "parallel" orbits, if you stretch the meaning of the word a little bit.

The wikipedia link above explains it well:

""" Orbital velocity of the satellites is approximately 27,000 km/h (17,000 mph). Satellites communicate with neighboring satellites via Ka band inter-satellite links. Each satellite can have four inter-satellite links: one each to neighbors fore and aft in the same orbital plane, and one each to satellites in neighboring planes to either side. The satellites orbit from pole to same pole with an orbital period of roughly 100 minutes.[8] This design means that there is excellent satellite visibility and service coverage especially at the North and South poles. The over-the-pole orbital design produces "seams" where satellites in counter-rotating planes next to one another are traveling in opposite directions. Cross-seam inter-satellite link hand-offs would have to happen very rapidly and cope with large Doppler shifts; therefore, Iridium supports inter-satellite links only between satellites orbiting in the same direction. """

The 'seams' have interesting implications for latency when I was working on Global Data Broadcast.