What are the two types of networking devices defined by power over Ethernet

An easy way to explain the primary function of PoE is to use a security camera as an example. Under normal circumstances, a digital security camera needs both power and network connections using two different cables. In a PoE-enabled device, the camera receives both power and network connections via a single cable.

This is a major breakthrough in terms of network design. Whereas previously it was necessary to include both a network connection and power connection to all devices on the network, PoE makes it possible to cut those connections in half by consolidating the two.

Devices like phones, cameras, routers and more can now leverage PoE to both power the devices and transfer important data.

Power over Ethernet (PoE) is a technique for delivering DC power to devices over copper Ethernet cabling, eliminating the need for separate power supplies and outlets. While PoE doesn't add Ethernet data capabilities, it does offer expanded options for how and where Ethernet end devices can be placed.

POE is a recently-developed technology, and many people are put off adopting it by the raft of conflicting or out-of-date information that is available on the subject.  Here are the most common misconceptions:

POE has compatibility problems. Not so. It is true that the early days of POE, many home-brewed and proprietary schemes were employed to get power over network cables.  However, the IEEE 802.3af standard has gained universal adoption as POE's popularity has spread, meaning that compatibility between all modern POE equipment is assured.

POE requires electrical knowledge. Again, early ad-hoc implementations may have required careful design, but IEEE 802.3af POE is designed to ensure reliable operation in any configuration that would be possible with regular Ethernet.  All the user has to do is wire up the network as normal, and the equipment will take care of power delivery.

POE requires special wiring. Not at all, the same cabling - Cat 5e, Cat 6, etc - and "RJ45"-style connectors are used for both regular and PoE-enabled local area networks.

Power is forced into devices. This misconception is surprisingly common, however it is important to remember that power ratings quoted by manufacturers are upper limits and are not fixed.  Plugging a 5 watt camera into a 15 watt injector does not result in 10 watts of power being lost somewhere; the camera will simply draw as much electrical power as it needs.

High power POE

The 802.3af POE standard is fine for network devices that require up to around 13 watts of electrical power, but many devices in the markets that have adopted POE require just that little bit more.  It is certainly possible for network cable and connectors to handle more power, but high-power POE systems have been proprietary and not always backwards-compatible with regular 802.3af POE.

For this reason a new standard was introduced by the IEEE to increase the available power: 802.3at, or POE Plus.  POE Plus has the following features:

Increased electrical power - POE Plus nearly doubles the amount of electrical power available to powered devices, to 25.5 watts.

Compatible with 802.3af POE - POE Plus switches and injectors will recognise 802.3af powered devices and enable POE to them as normal.  POE Plus powered devices can also be connected to 802.3af POE switches or injectors, and are supposed to restrict how much power they use accordingly.

Smart power budgeting - 802.3at includes scope for power sources and powered devices to communicate with each other to negotiate an allowance of electrical power.

POE Plus means that a more complete range of network equipment can now be POE-powered, including IP cameras with heater/blowers, and multichannel wireless access points.

Note that 802.3at exists alongside the 802.3af standard; it does not replace it.  802.3af will still be employed by the majority of Power over Ethernet devices for the foreseeable future.

How does POE work?

Network cables, such as Cat 5e and Cat 6, comprise eight wires arranged as four twisted pairs.  In 10 and 100BASE-T Ethernet, two of these pairs are used for sending information, and these are known as the data pairs.  The other two pairs are unused and are referred to as the spare pairs (Gigabit Ethernet uses all four pairs).

Because electrical currents flow in a loop, two conductors are required to deliver power over a cable.  POE treats each pair as a single conductor, and can use either the two data pairs or the two spare pairs to carry electrical current.

Power over Ethernet is injected onto the cable at a voltage between 44 and 57 volts DC, and typically 48 volts is used.  This relatively high voltage allows efficient power transfer along the cable, while still being low enough to be regarded as safe.

This voltage is safe for users, but it can still damage equipment that has not been designed to receive POE.  Therefore, before a POE switch or midspan (known as a PSE, for power sourcing equipment) can enable power to a connected IP camera or other equipment (known as a PD, for powered device), it must perform a signature detection process.

Signature detection uses a lower voltage to detect a characteristic signature of IEEE-compatible PDs (a 25kOhm resistance).  Once this signature has been detected, the PSE knows that higher voltages can be safely applied.

Classification follows the signature detection stage, and is an optional process.  If a PD displays a classification signature, it lets the PSE know how much power it requires to operate, as one of three power classes.  This means that PSEs with a limited total power budget can allocate it effectively.  POE power classes are as follows:

POE Power Class123PSE Power available4.0W7.0W15.4WMax device power3.84W6.49W12.95W

The differences between power delivered by the PSE and power received by the PD account for power that is lost as heat in the cable.  If a PD does not display a signature, it is class 0 and must be allocated the maximum 12.95 watts.

POE Plus equipment has a power class of 4.  If a regular 802.3af POE source detects this class it will simply enable power as if it was a class 0 device.  However, an 802.3at PSE will not only recognise the PD as a POE Plus device, it will also repeat the classification stage, as a signal to the PD that is connected to a power source with full POE Plus power available.  (In theory the PD should also be able to request the extra power by communicating across the network link.)  POE Plus PSEs can supply up to 30 watts and available device power is 25.5 watts.

The final stage after detection and classification of a newly connected device is to enable power: the 48V supply is connected to the cable by the PSE so the PD can operate.  Once enabled, the PSE continues to monitor how much electrical current it is delivering to the PD, and will cut the power to the cable if too much, or not enough, power is drawn.  This protects the PSE against overload, and ensures that POE is disconnected from the cable if the PD is unplugged.

Want to know more?

For an introduction to POE and its applications and benefits, see the first part of this article: POE Explained, Part 1

Our Power Without the Struggle white paper makes the case for POE deployment in more detail, and explains how POE can be used effectively.

We also have a POE Explained white paper, which describes the functionality of POE in technical, but straightforward, detail.

Or simply contact Veracity or one of our representatives, to see how we can help you make the most out of your POE application.

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