Ehternet with PoE

[dmsque]

Hello!
Is it possible (and safe) to connect E4 (197215) via Ethernet cable that connected to PoE-port? NOT for powering, ofcourse)

[ablas]

Empezamos mal si no diferencias entre los 110-240V, de tensión alterna con los que se alimenta el EASYE4 del que tú hablas y “Ethernet PoE”. Sería bueno empezar sabiendo lo que quieres hacer bien explicado para que podamos entender la situación.
E4, no necesita ni usa nada PoE. Una cosa es la comunicación y otra es la alimentación. Cuando existen antenas de comunicación en la aplicación sí que van alimentadas normalmente desde una fuente PoE. No mezclemos churras con merinas.

We're off to a bad start if you don't differentiate between the 110-240V AC voltage that powers the EASYE4 you're talking about and "Ethernet PoE." It would be good to start by clearly explaining what you want to do so we can understand the situation. The E4 doesn't need or use PoE. Communication and power are two different things. When communication antennas are used in the application, they are usually powered by a PoE source. Let's not mix apples and oranges. I'm concerned about your safety; are you an electrician?

[Sparlock]

Hello dmsque!

You could use an PoE splitter. This should be safe.

[ablas]

Okay, I understand now. The situation is as follows: a switch with PoE over Ethernet to which we connect an EasyE4.
The manual says that only lines corresponding to connections 1, 2, 3, and 6 (data) are internally connected; the rest of the connections are marked as free.
I understand that it can be connected without problems (I haven't tested it myself).

Ok, ya lo entiendo, se supone que se da la siguiente situación: un switch con PoE por ethernet al que conectamos un EasyE4.
El manual dice que solo están conectadas internamente las líneas correspondientes a las conexiones 1,2,3 y 6 (datos), el resto de conexiones las marca como libres.
Entiendo que se puede conectar sin problemas (yo, no lo he comprobado).

[Sparlock]

Hello ablas!

There are two modes A and B.
https://en.wikipedia.org/wiki/Power_over_Ethernet#Pinouts
Your example is mode B. But what about mode A or A+B? There is Power on Pins 1, 2, 3 and 6.
It is safer to use an PoE splitter.

[ablas]

Hi Sparlock!
The data wires can only be the same, as they are swapped in pairs:
T568-A
1 Tx+ WHITE/GREEN
2 Tx- GREEN
3 Rx+ WHITE/ORANGE
6 Rx- ORANGE

T568-B
1 Tx+ WHITE/ORANGE
2 Tx- ORANGE
3 Rx+ WHITE/GREEN
6 Rx- GREEN

The remaining wires, corresponding to connections (4, 5, 7, , are PoE, power for very low-power devices. If internally (E4), it doesn't use those connections, I don't see a problem.

Note: only an error in the connector wiring could conduct PoE voltage to the data lines.
Thanks, Sparlock, this helped me catch up. Best regards.

READ TO THE END TO CLARIFY AND UPDATE OLD CONCEPTS.

Sorry Sparlock, to confirm I asked the AI ​​for its opinion on this and here is its response for the forum...

Primera respuesta:
Entonces, solo puede haber PoE, en redes de hasta 100 Mbps?
¡No, esa es una confusión muy común!
El PoE funciona perfectamente en redes Gigabit (1000 Mbps) y superiores. La diferencia es la técnica que se utiliza para enviar la energía.
1. La técnica del "Poder Fantasma" (Phantom Power)
En redes de 10/100 Mbps, como sobran hilos (4, 5, 7 y , es fácil enviar la electricidad por ahí sin molestar a los datos. Pero en Gigabit, los 8 hilos transmiten datos a la vez.
 Planet Technology USA +1
•   ¿Cómo lo solucionan? Se aplica un voltaje continuo (DC) sobre los mismos hilos que llevan los datos (AC).
•   Como la electricidad y los datos viajan en frecuencias totalmente distintas, no se interfieren. El dispositivo en el otro extremo separa la energía de la señal de red mediante transformadores internos.
 UTEPO +4
2. Modos de funcionamiento (Modo A y Modo B)
El estándar IEEE 802.3af/at define dos formas de enviar energía que son compatibles con Gigabit:
•   Modo A (Endspan): La energía viaja por los pares de datos (pines 1-2 y 3-6).
•   Modo B (Midspan): La energía viaja por los pares que serían "sobrantes" en 100 Mbps (pines 4-5 y 7-8).
•   4PPoE (802.3bt): Los estándares más modernos y potentes usan los 4 pares simultáneamente para enviar hasta 90W.
 EtherWAN Systems +3
3. El mito de los 100 Mbps
Si al conectar un dispositivo PoE solo obtienes 100 Mbps en lugar de 1000 Mbps, suele deberse a:
•   Cables de mala calidad: Cables Cat5 (no "e") o cables con solo 4 hilos conectados.
•   Hardware antiguo: Inyectores PoE pasivos muy baratos que solo están diseñados para puentear los pines 4,5,7,8, bloqueando físicamente el tráfico Gigabit.
 Ubiquiti +3
En conclusión: El PoE no limita la velocidad a 100 Mbps por diseño; si tienes el equipo adecuado (Switch Gigabit PoE e inyectores compatibles), puedes tener Gigabit y energía por el mismo cable.

DEFINITION:
Subject: Clarification on T568A/B standards and PoE pinouts
Hi everyone,
I’d like to share some thoughts on Ethernet wiring standards and how they interact with PoE. I've seen some confusion regarding pin usage, so here is a breakdown to clarify:
1. T568A vs. T568B: The "Pair Swap"
Technically, both standards are identical in terms of performance. The only difference is that the Green and Orange pairs are swapped:
•   T568A: Pins 1-2 (Green), Pins 3-6 (Orange).
•   T568B: Pins 1-2 (Orange), Pins 3-6 (Green).
As long as you use the same standard on both ends (straight-through), the device won't care which one you pick.
2. Data vs. Power (PoE)
This is where it gets interesting depending on your network speed:
•   10/100 Mbps (Fast Ethernet): Only pins 1, 2, 3, and 6 are used for data. In many "Mode B" PoE implementations, the "spare" pins (4, 5, 7, , are used to carry DC power.
•   1000 Mbps (Gigabit Ethernet): Unlike Fast Ethernet, Gigabit uses all 8 wires for data. PoE still works here by using a technique called "Phantom Power"—where DC voltage is superimposed onto the data pairs without interference.
3. Safety Warning
A critical point to remember: if there is a wiring error (like accidentally crimping a power-carrying wire into a data pin), you risk sending 48V–57V directly into the data transceiver. While modern active PoE (802.3af/at/bt) performs a "handshake" to prevent this, passive PoE injectors do not and can easily fry non-PoE equipment.
Conclusion:
If your internal device logic (like an E4 module) only expects data on 1,2,3,6 and isn't designed for Gigabit, using the other pins for power is standard practice. However, for any modern Gigabit-capable setup, remember that all 8 pins are active for data.

Un saludo.

[ablas]

Hi Sparlock!

I've been looking into it, and I'm not sure about the splitter option; there are so many, and I'm confused. I think telling DMSQUE to use a "non-PoE" port is the right recommendation. Switches usually have both "normal" and PoE ports. And if you've run out of normal ports, you'll have to replace the switch with a larger one. With the help of AI, I've managed to unravel the confusion, and as you said, this seems to be the second and final option: the TP-Link TL-POE10R PoE Splitter Extractor. The output port is no longer PoE.
Best regards.

ADAM TV5 speakers and a Fiio KA5 DAC. These are highly recommended products for desktop music.

He estado mirando y no me fio de la opción del divisor hay multitud y no me aclaro. Creo que decirle que utilice un puerto “NO PoE” es la recomendación correcta para DMSQUE. Normalmente los switches, disponen de puertos “normales” y PoE. Y si se han agotado los puertos normales, toca cambiar el switch por otro mayor. Con ayuda de la IA, he conseguido descifrar el caos, y como decías tú, esta me parece la segunda y última opción: PoE Splitter Extractor TP-Link TL-POE10R; el puerto de salida ya no es PoE.
Un saludo.