EthernetExtensions: Difference between revisions
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{{Project | |||
|Name=EthernetExtensions | |||
|Picture= | |||
|Omschrijving=Exploring Ethernet PHYs features, faillures, and timing | |||
|Status=Initializing | |||
|Contact=cmpxchg | |||
}} | |||
==Problem description== | |||
Ethernet is very ubiquitous in today's world. Many of the courseware is about ARP, DHCP, and TCP/IP. | |||
But, what happens at the layers below, that provided us with 10, 100 and 1000 megabits per second ? | |||
* What can cause such link to fail ? | |||
* Are there any propietary extensions known that can be triggered by older or newer hardware ? | |||
* Which bandwidth limits apply to the physical layer, relative to the theoretical bandwidth ? | |||
* How can one push that bandwidth limit to the fullest, so that no time on the cable gets wasted ? | |||
* Would using a VPN or IPV6 waste bandwidth by adding more headers to each ethernet frame, or does the time-slotted nature of a real link make this less relevant ? | |||
* There are ways to not only distribute data over ethernet, but also provide accurate time-stamping of all or specific ethernet frames. This way timing can be distributing along with data. This can be beneficial for multimedia-purposes, synchronising multiple audiostreams, or aligning delays with multiple conference-calls going on in the same room (echo cancellation). | |||
* IEEE 1588 can be used https://en.wikipedia.org/wiki/Precision_Time_Protocol | |||
==Exploring problem space== | |||
10 megabits per second, or 10-Base-T is using manchester-coding, a simple signal with an embedded clock. | |||
In the ethernet PHY, it is converted to a 2.5 MHz, 4-bit parallel signal. | |||
When using 100 megabits per second, or 100-Base-T, 4B5B encoding is used, next to MLT-3 encoding. | |||
This allows for a few ambiguities that can be turned into (propietary) extensions between ethernet PHYs. | |||
In the ethernet PHY, these ambiguities are resolved and lead to a 25 MHz, 4-bit parallel signal to | |||
the microcontroller. | |||
==Specific PHY implementation of 10/100 megabit== | ==Specific PHY implementation of 10/100 megabit== | ||
Some STM32 development board have have a SMSC / Microchip ethernet PHY mounted, the LAN8742 RMII 10/100 ethernet PHY. | Some STM32 development board have have a SMSC / Microchip ethernet PHY mounted, the LAN8742 RMII 10/100 ethernet PHY. | ||
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* 100 mbps TX | * 100 mbps TX | ||
The bitrate after of 25 MHz/4 bits or 50 MHz/2 bits (100 mbps). After the 4B/5B encoding it is actually 125 mbps. After this is additionally, scrambled, serialized, NRZI encoded, and MLT-3 modulated onto | The bitrate after of 25 MHz/4 bits or 50 MHz/2 bits (100 mbps). After the 4B/5B encoding it is actually 125 mbps. After this is additionally, scrambled, serialized, NRZI encoded, and MLT-3 modulated onto two differential lines, amplified, and routed to a pin on the chip. External to the chip, there are four transformers that remove DC components and prevent large voltages to be dissipated by a receiving chip. | ||
* 100 mbps RX | * 100 mbps RX | ||
| Line 12: | Line 39: | ||
* 10 mbps TX | * 10 mbps TX | ||
The signal is accepted by the PHY from the microcontroller as a 5 MHz 2-bit wide signal | The signal is accepted by the PHY from the microcontroller as a 5 MHz 2-bit wide signal. | ||
* 10 mbps RX | * 10 mbps RX | ||
The signal is generated by the PHY to the microcontroller as a 5 MHz 2-bit wide signal. | The signal is generated by the PHY to the microcontroller as a 5 MHz 2-bit wide signal. | ||
Revision as of 23:12, 9 June 2020
| Project EthernetExtensions | |
|---|---|
| Exploring Ethernet PHYs features, faillures, and timing | |
| Status | Initializing |
| Contact | cmpxchg |
| Last Update | 2020-06-09 |
Problem description
Ethernet is very ubiquitous in today's world. Many of the courseware is about ARP, DHCP, and TCP/IP. But, what happens at the layers below, that provided us with 10, 100 and 1000 megabits per second ?
- What can cause such link to fail ?
- Are there any propietary extensions known that can be triggered by older or newer hardware ?
- Which bandwidth limits apply to the physical layer, relative to the theoretical bandwidth ?
- How can one push that bandwidth limit to the fullest, so that no time on the cable gets wasted ?
- Would using a VPN or IPV6 waste bandwidth by adding more headers to each ethernet frame, or does the time-slotted nature of a real link make this less relevant ?
- There are ways to not only distribute data over ethernet, but also provide accurate time-stamping of all or specific ethernet frames. This way timing can be distributing along with data. This can be beneficial for multimedia-purposes, synchronising multiple audiostreams, or aligning delays with multiple conference-calls going on in the same room (echo cancellation).
- IEEE 1588 can be used https://en.wikipedia.org/wiki/Precision_Time_Protocol
Exploring problem space
10 megabits per second, or 10-Base-T is using manchester-coding, a simple signal with an embedded clock. In the ethernet PHY, it is converted to a 2.5 MHz, 4-bit parallel signal. When using 100 megabits per second, or 100-Base-T, 4B5B encoding is used, next to MLT-3 encoding. This allows for a few ambiguities that can be turned into (propietary) extensions between ethernet PHYs. In the ethernet PHY, these ambiguities are resolved and lead to a 25 MHz, 4-bit parallel signal to the microcontroller.
Specific PHY implementation of 10/100 megabit
Some STM32 development board have have a SMSC / Microchip ethernet PHY mounted, the LAN8742 RMII 10/100 ethernet PHY. http://ww1.microchip.com/downloads/en/DeviceDoc/8742a.pdf
It nicely details all design decisions that go into making an Ethernet link work, or potentially make it fail.
- 100 mbps TX
The bitrate after of 25 MHz/4 bits or 50 MHz/2 bits (100 mbps). After the 4B/5B encoding it is actually 125 mbps. After this is additionally, scrambled, serialized, NRZI encoded, and MLT-3 modulated onto two differential lines, amplified, and routed to a pin on the chip. External to the chip, there are four transformers that remove DC components and prevent large voltages to be dissipated by a receiving chip.
- 100 mbps RX
For reception, a clock must be recovered, as each ethernet transceiver has it's own clock and will wander tens of kHz around the advertised frequency/bitrate. On the short-term, lots of clock wandering can be expected. This clock is recovered, a PLL has a VCO that is steered towards the average bitrate the is received.The wander in speed/frequency can pose a limit on the length of a packet, in this case 1588 bytes. The end result is a 50 MHz, 2-bit wide signal transmitted to the microcontroller.
- 10 mbps TX
The signal is accepted by the PHY from the microcontroller as a 5 MHz 2-bit wide signal.
- 10 mbps RX
The signal is generated by the PHY to the microcontroller as a 5 MHz 2-bit wide signal.