Because Power over Ethernet (PoE) delivers power over the same cable as data, it’s popular for powering devices such as VoIP phones, wireless access points, and security cameras. It often... more/see it nowleads to significant savings by eliminating the need to install a separate power outlet.
Most PoE today is standards-based IEEE 802.3af or the newer higher-powered IEEE 802.3at PoE, which are very safe because power source equipment (PSE) doesn’t add power to the data line unless it detects a compatible powered device (PD) connected to the other end of the cable. This protects devices that do not support PoE. PSEs and PDs also negotiate power requirements, so a PD never receives too much power. Both PSEs and PDs have power supplies and regulators isolated from ground to minimize shock hazard.
But here’s where it gets complicated…
Because most PoE available today is standards-based 802.3af or 802.3at, it’s easy to forget that there are versions of PoE that are NOT standards based. Some of these non-standards-based versions of PoE feature power injectors that inject power without checking compatibility—and that can be very bad news for an innocent network device.
Non-standard PoE tends to fall into three categories: proprietary PoE, high-wattage proprietary PoE, and passive PoE.
Before the ratification of the 802.3af standard in 2003, PoE was a free-for-all with many vendors offering their own method of delivering power over data lines. Some vendors still offer their own proprietary PoE. These proprietary solutions offer varying degrees of communication between PSE and PD. Our Black Box® Wireless Point-to-Point Ethernet Extender Kit (LWE100A-KIT) uses Prorietary PoE in the form of 12 VDC running at 12 W, which is well below the 48 VDC and 15.4 W provided by standard 802.3af.
High-wattage Proprietary PoE.
Many vendors offer high-wattage PoE solutions designed to deliver from 50 watts to 100 or even 200 watts per port. High-wattage proprietary PoE is often used with high-powered outdoor wireless radios.
Passive PoE injects power into an Ethernet cable on Pins 4 and 5 with negative return on Pins 7 and 8 and absolutely no communication between PSE and PD. This method was once a very common “home brew” method of transferring power over data cable and is still commonly used in telecomm applications.
Document and label.
There’s nothing wrong with PoE that’s not standards based—these power methods work as well as 802.3af/at PoE to power network devices. You do, however, need to be aware of what kind of Power over Ethernet you have and what it will work with. Good network documentation and labeling are the keys that enable you to know that, for instance, that power injector is a high-wattage proprietary injector that will fry the IP camera you’re about to connect. Proper documentation, which is good practice in any case, becomes absolutely vital when you have components that may damage other components.
Black Box Explains...Wireless Ethernet standards.
The precursor to 802.11b, IEEE 802.11 was introduced in 1997. It was a beginning, but 802.11 only supported speeds up to 2 Mbps. And it supported two entirely different... more/see it nowmethods of encodingFrequency Hopping Spread Spectrum (FHSS) and Direct Sequence Spread Spectrum (DSSS). This led to confusion and incompatibility between different vendors equipment.
802.11b is comfortably established as the most popular wireless standard. With the IEEE 802.11b Ethernet standard, wireless is fast, easy, and affordable. Wireless devices from all vendors work together seamlessly. 802.11b is a perfect example of a technology that has become both sophisticated and standardized enough to really make life simpler for its users.
The 802.11b extension of the original 802.11 standard boosts wireless throughput from 2 Mbps all the way up to 11 Mbps. 802.11b can transmit up to 200 feet under good conditions, although this distance may be reduced considerably by the presence of obstacles such as walls.
This standard uses DSSS. With DSSS, each bit transmitted is encoded and the encoded bits are sent in parallel across an entire range of frequencies. The code used in a transmission is known only to the sending and receiving stations. By transmitting identical signals across the entire range of frequencies, DSSS helps to reduce interference and makes it possible to recover lost data without retransmission.
The 802.11a wireless Ethernet standard is new on the scene. It uses a different band than 802.11b—the 5.8-GHz band called U-NII (Unlicensed National Information Infrastructure) in the United States. Because the U-NII band has a higher frequency and a larger bandwidth allotment than the 2.4-GHz band, the 802.11a standard achieves speeds of up to 54 Mbps. However, its more limited in range than 802.11b. It uses an orthogonal frequency-division multiplexing (OFDM) encoding scheme rather than FHSS or DSSS.
802.11g is an extension of 802.11b and operates in the same 2.4-GHz band as 802.11b. It brings data rates up to 54 Mbps using OFDM technology.
Because it's actually an extension of 802.11b, 802.11g is backward-compatible with 802.11b—an 802.11b device can interface directly with an 802.11g access point. However, because 802.11g also runs on the same three channels as 802.11b, it can crowd already busy frequencies.
Super G® is a subset of 802.11g and is a proprietary extension of the 802.11g standard that doubles throughput to 108 Mbps. Super G is not an IEEE approved standard. If you use it, you should use devices from one vendor to ensure compatibility. Super G is generally backwards compatible with 802.11g.
80211n improves upon 802.11g significantly with an increase in the data rate to 600 Mbps. Channels operate at 40 MHz doubling the channel width from 20 MHz. 802.11n operates on both the 2.4 GHz and the 5 GHz bands. 802.11n also added multiple-input multiple-output antennas (MIMO).
Multiple-Input/Multiple-Output (MIMO) is a part of the new IEEE 802.11n wireless standard. It’s a technique that uses multiple signals to increase the speed, reliability, and coverage of wireless networks. It transmits multiple datastreams simultaneously, increasing wireless capacity to up to 100 or even 250 Mbps.
This wireless transmission method takes advantage of a radio transmission characteristic called multipath, which means that radio waves bouncing off surfaces such as walls and ceilings will arrive at the antenna at fractionally different times. This characteristic has long been considered to be a nuisance that impairs wireless transmission, but MIMO technology actually exploits it to enhance wireless performance.
MIMO sends a high-speed data stream across multiple antennas by breaking it into several lower-speed streams and sending them simultaneously. Each signal travels multiple routes for redundancy.
To pick up these multipath signals, MIMO uses multiple antennas and compares signals many times a second to select the best one. A MIMO receiver makes sense of these signals by using a mathematical algorithm to reconstruct the signals. Because it has multiple signals to choose from, MIMO achieves higher speeds at greater ranges than conventional wireless hardware does. collapse