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Interpreting Cable Test Data
Selecting the appropriate communication cable for a project can be challenging. Whether you are
a consultant designing an infrastructure for a major customer or an IT professional who is tasked
with turning a large open area into a cubicle farm, choosing the best cable for the project can be
daunting. One factor that can make it even more challenging is the manner in which some
companies provide the performance data for their cables. Terms like “Average”, “Typical”, “Max”
and “Guaranteed” are being used by different manufacturers to describe their cable’s performance.
Which term or terms most accurately depict the cable’s performance and, more importantly, the
company’s obligation to that performance?
This document will attempt to shed light on some of the confusing terminology used in the cable
industry and will hopefully make readers better informed for their next cable project.
What are the cables tested to?
When it comes to Category cable, such as Category 5e, 6 and 6A, the physical and electrical
testing parameters were established by an industry organization known as the Telecommunications
Industry Association and put forth in a document knows as Telecommunications Cabling for
Customer Premises. The current version of this standard is known as TIA-568-C. This is the
standard to which all cable and connectivity manufacturers should design and build their products.
For example, the standard states what color the conductor’s insulation is to be, the maximum
allowable length for an installed horizontal cable (90m), the copper size to utilize (22 AWG to 24
AWG) and where on a jack each conductor is to be terminated, among many other specifics. The
purpose of the standard is to ensure that if someone purchases products compliant to the standard,
regardless of the manufacturer, that they will work together. Products with characteristics that fall
outside the limits identified in the standard should be avoided. Also, to correct a belief that some
perpetuate, there is no Category 6e (or 6E) standard. This is merely marketing gone awry. Many
companies manufacture enhanced Category 6 cables. And, that is how they should be marketed.
And, since “enhanced” is subjective, it is up to the buyer to determine how much enhancement they
desire. Unfortunately, some in the industry continue to refer to enhanced Category 6 cables as
6e(E), only exacerbating the problem.
In the TIA-568-C.2 standard, cables and connective hardware are placed into different categories.
The standard identifies electrical performance tests and parameters for each category. The tests
include a number of electrical tests performed within a specific electrical frequency range. Table 1
shows the test frequency range for each recognized category of cable.
Cable Category
Category 3
Category 5e
Category 6
Category 6A
Frequency Range
1 – 16 MHz
1 – 100 MHz
1 – 250 MHz
1 – 500 MHz
Table 1.
The main tests for categories 5e through 6A are Insertion Loss, Return Loss, Near-End Crosstalk
(NEXT), Power Sum Near-End Crosstalk (PSNEXT), Attenuation-to-Crosstalk Ratio Far-End
(ACRF) and Power Sum Attenuation-to-Crosstalk Ratio Far-End (PSACRF).
PSANEXT
(Powersum Alien Near-End Crosstalk) and PSAACRF (Powersum Attenuation to Alien Crosstalk
Ratio, Far end) are important tests for Category 6A cable. For each of these tests, except Insertion
Loss, there are minimum values that the cable must perform to at a given frequency to be
considered complaint to the standard. Due to the nature of Insertion Loss, the standard indicates a
maximum performance level. For the purposes of this paper, we will not define each test
parameter. We merely wish to point out that numerous tests, including some not referenced
above, are required by the standard.
To complicate things slightly, the TIA-568-C.2 standard provides three different levels of electrical
performance for cables and connective hardware to meet. There are parameters which are utilized
by cable and connectivity manufacturers for stand-alone testing of their products. There are
permanent link parameters in which cable and the connective hardware are measured as one.
There are also channel parameters that include the cable, the hardware connected to it and the
patch cords that are attached to each end of the link. All three have distinct performance values for
the range of frequencies referenced for each performance category. It is worth noting that
handheld testers used at the installation site can test permanent link and channel performance
only. Some testers, however, do have adapters to test patch cords.
The purpose of the three levels of testing is to establish performance goals for the individual
components in the infrastructure, to have a performance goal once those components are mated
together, and to finally have a tertiary performance goal that includes the patch cords used to plug
directly from the jacks and patch panels directly into devices. The three methods of testing exist to
ensure product uniformity, regardless of manufacturer, and product performance post installation.
For example, you can pass a permanent link test, but you could then fail a channel test if low
quality or faulty patch cords are used. Conversely, you could pass a channel test, which includes
the patch cords, but then move or swap cords and result with a failing circuit if you perform the
channel test again.
What should I look at when comparing cables?
Directly comparing test parameters.
Depending on your specific needs, there are a few
ways that you can compare cables. If you wish to
compare multiple cables on a strictly cable
performance level, you can look at some of the test
parameters and compare those parameters between
your choices. For example, you plan on operating
gigabit Ethernet on your network so you are looking
for a Category 6 solution. When comparing Category
6 cables, you can choose the test parameters NEXT
and PSNEXT at a specific frequency, such as 250
MHz, which is the maximum frequency for Category
6. Just remember that for all parameters, except
Insertion Loss (previously referred to as Attenuation)
a higher value is preferred. You can also compare
ACR and PSACR values, if they are provided. If not,
you can calculate them from the NEXT, PSNEXT and
Insertion Loss values.
ACR & PSACR, which are often thought of as being
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Table 2: Hitachi Category 6 Plus™ Performance (cropped
section taken from product transmission specifications)
tests in the standard, but actually are not, are an abbreviation for Attenuation-to-Crosstalk Ratio
and PowerSum Attenuation-to-Crosstalk Ratio. Values for ACR and PSACR are derived from an
equation involving two test parameters. ACR is NEXT minus Insertion Loss and PSACR is
PSNEXT minus Insertion Loss. So, for every frequency at which Insertion Loss, NEXT and
PSNEXT is tested, an ACR and PSACR value can be obtained. ACR and PSACR are considered
important telltales in regards to a cable’s performance. Often referred to as headroom, the ACR
and PSACR values demonstrate how well a product performs above the standard. It is often the
focal point when comparing cables. For example, when comparing Category 6 cables, comparing
ACR and PSACR values at a given frequency, such as 250 MHz, will give you an idea of how
much additional performance the product has over the standard. The cable with the higher values
is typically superior.
When comparing cables based on their published performance, keep in mind that if the values
between two manufacturers’ cables are within 1 dB or so of each other, or if one cable shows
slightly higher values in one parameter but slightly lower values in another parameter when
compared to the other cable, they are likely to perform similarly. These slight differences in
manufacturers’ published specifications become less apparent after the cable has been installed
and connectors have been attached. Variables that will influence final cable performance include
the skill of the installers, the quantity and quality of cable support devices (J-hooks), the quality and
size of conduit, ladder rack, tray, etc., the temperature both during and after installation, humidity,
the quality of the connectors and how well they are attached, the quality of the testing unit (when
was it last certified?), the quality of the test cables for the testing unit, etc. So, if the electrical
performance of two cables is within 1 dB or so of each other, they could be considered similar.
Does the cable’s maximum test frequency matter?
Another piece of test data often touted by cable manufacturers is the maximum frequency to which
their cable was tested. Many manufacturers, including Hitachi Cable, choose to sweep test some
cables out beyond the maximum frequency identified in the 568-C.2 standard. Since the Category
6 standard only goes up to 250 MHz, the purpose of higher frequency sweep testing is to identify
the cables behavior beyond that which is required by the standard. The electrical performance for
frequencies above the standard act as valuable process indicators to assist the cable manufacturer
in monitoring and controlling their manufacturing processes. Keep in mind that the applications
designed to run on Category 6 cable do so within the Category 6 test frequency range identified in
the standard.
If a manufacturer provides performance values beyond the frequencies in the standard, usually the
higher the frequency at which the ACR, or headroom, values are positive, the better the cable is.
For example, the Hitachi Cable Category 6 PLUS™ is sweep tested to 555 MHz. Its ACR is
positive beyond 300 MHz. If a competitor’s cable is positive only to 260 MHz, then the Hitachi
cable could be considered more robust. However, the maximum indicated test frequency for a
Category 6 cable, when beyond 250 MHz, by itself, should play little to no role when evaluating
cables. It’s like knowing the top speed of the Ford Taurus you just purchased. It’s interesting, but
not particularly relevant. There are no values for Category 6 beyond 250 MHz. in the TIA-568-C.2
standard. A cable tested to a higher frequency than another cable simply means the manufacturer
chose to sweep test it to that higher frequency. A higher frequency also has no bearing on a
cable’s “speed” as some might believe. There is no connection between a cable’s performance
and the maximum frequency to which it is tested. A Category 6 cable could be sweep tested to
850 MHz. But, knowing the cable’s performance at 850 MHz is, like the top speed of the Taurus,
irrelevant.
Why do some cable manufacturers use different terms from others?
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When comparing the test data from one cable manufacturer to that of another, there are additional
challenges that can arise. These challenges revolve around how a company chooses to present
their data and how they support those performance claims. As stated previously, in the TIA
standard, there are distinct values for each performance parameter at a given frequency. A
company may choose to provide their performance values while also showing the values
referenced in the standard. Table 2 above shows how Hitachi Cable America presents the
electrical performance data. The values from the TIA-568-C.2 standard are provided as well as the
anticipated minimum (or maximum) performance from our cable. In this case, the cable is Hitachi
Cable’s Category 6 PLUS™. The PLUS™ is Underwriters Laboratories verified to the Category 6
standard and is internally tested beyond the standard’s requirements of 250 MHz. Table 2
represents a portion of the test data provided.
Table 2 clearly shows the performance values required by the standard and the “Min” or “Max”
performance provided by the cable. Hitachi Cable America’s minimum and maximum values are
guaranteed. These are the performance values that our cables are tested to in our lab, before they
are allowed to ship from the facility. These increased levels of performance provided by Hitachi
Cable America cables offer the customer an additional performance cushion that ensures the
highest level of data throughput. The additional headroom can also help mitigate installation issues
that may have a negative impact on link performance. Using experienced, certified installers is, of
course, always strongly recommended as well.
Not all manufacturers, however, present performance data in this manner. Some provide results
under headings entitled Typical or Average and some even use a completely unique title, such as
their name. What does that mean? One manufacturer entitles their performance values Expected
Performance. How much confidence does that instill? One should be critical of values provided
under any of these headings especially when they lack clear definition. What are typical or
average values based on? If there is no explanation regarding the term used, how much weight
should the term carry? Some manufacturers also provide guaranteed values alongside their typical
values. If there is any difference between their typical values and their guaranteed values,
shouldn’t one question the validity of the typical data? What is the point of claiming very high
typical performance values but guaranteeing something substantially lower?
Typical values should never be used when comparing cables. Here’s a simple analogy. You work
for a police department and you are tasked to buy bullet proof vests for your fellow officers. You
are looking at products from two companies. One guarantees that their vests will stop a 9mm
round. The other company says that their vests will typically stop a 9mm round, but they guarantee
it will stop a .22 caliber round. Which vest would you want to wear?
The analogy is intended to demonstrate that many manufacturers choose to use vague terms to
exaggerate the actual performance of their products. This trend has made comparing cables very
challenging. Some speculate that that is the intent. Additionally, some cable manufacturers
(though they themselves may not actually make the cable) who also sell connectivity, often choose
not to make cable performance data readily available. Rather, they choose to provide the channel
test data for their solution, making it very difficult for consumers to compare that cable to another.
Channel test data includes all the components of a channel, i.e. cable, jacks, patch panels,
consolidation points (devices onto which cables can be terminated to and then extended from) and
patch cords. So, if a manufacturer only provides channel test data, how can you compare the
cable being identified in that channel to another cable? The answer is you really can’t.
Can I compare cables when only using Channel or Permanent link test data?
Channel testing is one of the testing methods identified in the TIA-568-C.2 standard. The values in
the TIA standard for channel testing differ from those for cable testing. They are more relaxed than
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those for just the cable. The cable is the performance maker in a circuit. The other components;
jacks, patch panels and consolidation points, all borrow performance from the cable. So you can
have a circuit that has a good cable and low performing devices and it provides performance X.
You can also have a circuit that has a low performing cable and high performing devices and also
get performance X. Regardless, channel test data should only be used when comparing channel
performance. It’s not a viable data source when trying to compare the cables in those channels.
This is also one of the reasons why many cable manufacturers provide multiple Category 6 cables,
each with a specific level of performance. Hitachi Cable currently offers four different Category 6
cables with four levels of performance available. By using a higher performing Category 6 cable,
such as Hitachi Cable’s Premium™ or Supra 660™, you bring additional performance to the
channel, so the performance of the connective hardware and the patch cords has less of an impact
on the channel’s overall performance. The use of higher performing cable frees you to choose
from a wider range of connectivity without performance concerns.
Some manufacturers maintain that only channel testing can provide an accurate measure of a
circuits performance. When a channel is tested, the patch cords are included in the test. In reality,
most circuits in a new construction environment are tested as a permanent link, which includes only
the cable, jacks and patch panel. This is often due to the construction site environment and the
customer’s move-in schedule. The addition of patch cords when testing in a construction
environment is not often practical. For a channel test to be of value, the patch cords for a particular
circuit need to remain with that circuit post testing to deliver the performance identified in the test
results. In reality, patch cords often get moved around or replaced, often with another
manufacturer’s cord. If the patch cords get substituted, it will impact the channel performance,
rendering channel test data irrelevant.
Conclusion
When selecting components for your infrastructure, it is important to compare the products on a
level playing field. Evaluate “typical” and “average” test results with skepticism. Compare channel
test results with channel test results and likewise with permanent link test results. Evaluate the
warranty of the manufacturer’s involved. What type of restrictions might the warranty have? Some
solution manufacturers will void the warranty for an entire building if another manufacturer’s cables
or jacks are used on the site. Most importantly, evaluate the manufacturer. What is their track
record? Where do they manufacture their products? Are they willing to let you tour their
manufacturing facility?
The products are ultimately only as good as the manufacture making them. To learn more about
the high-performance cables from Hitachi Cable America, visit our website at www.hca.hitachicable.com.
HCA products are distributed by:
200 Hembree Park Drive, Suite 1
Roswell, Georgia 30076-3890
Toll free 888-222-8832
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