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Updated reference from UniPro 1.0 to 1.1 (the link should work soon; the main article has a link to version 1.0 as well) |
m →Physical Layer (L1): Move the D and M Phy table to the end of the L1 section. Was between D and M subsections. |
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The D-PHY also supports a Low-Power Data Transmission (LPDT) mode and various other low-power modes for use when no data needs to be sent.
===M-PHY===▼
Versions 1.5 and beyond of UniPro plan to support both the D-PHY as well as M-PHY technology. The M-PHY technology is still unreleased, but is expected to support data rates starting at about 1000 Mbit/s (the M-PHY was named after the Roman number for 1000). In addition to higher speeds, the M-PHY will use fewer signal wires because the clock signal is embedded with the data through the use of industry-standard [[8B/10B encoding|8b10b encoding]].▼
The D- and M-PHY are expected to co-exist for multiple years because the D-PHY is a less complex technology while the M-PHY provides higher bandwidths despite using fewer signal wires.▼
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▲===M-PHY===
▲Versions 1.5 and beyond of UniPro plan to support both the D-PHY as well as M-PHY technology. The M-PHY technology is still unreleased, but is expected to support data rates starting at about 1000 Mbit/s (the M-PHY was named after the Roman number for 1000). In addition to higher speeds, the M-PHY will use fewer signal wires because the clock signal is embedded with the data through the use of industry-standard [[8B/10B encoding|8b10b encoding]].
▲The D- and M-PHY are expected to co-exist for multiple years because the D-PHY is a less complex technology while the M-PHY provides higher bandwidths despite using fewer signal wires.
==PHY Adapter Layer (L1.5)==
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