COMPUTERS ARE BAD is a newsletter semi-regularly issued directly to your doorstep to enlighten you as to the ways that computers are bad and the many reasons why. While I am not one to stay on topic, the gist of the newsletter is computer history, computer security, and "constructive" technology criticism.
I have an M. S. in information security, more certifications than any human should, and ready access to a keyboard. This are all properties which make me ostensibly qualified to comment on issues of computer technology. When I am not complaining on the internet, I work in engineering for a small company in the healthcare sector. I have a background in security operations and DevOps, but also in things that are actually useful like photocopier repair.
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Let's discuss the humble thermostat. You probably have one in your house,
and it probably connects to a set of wires. If you've ever replaced your
thermostat, you've probably found those wires a little irritating due to
the lack of well standardized nomenclature for identifying them. This is
particularly clear in the new generation of smart thermostats which attempt
to be "consumer-friendly" to install, and thus must have sort of complex
install wizards (InstallShield (R) for Thermostats) just to generate your
hookup instructions. So what's up with that?
Well, let's take a step back.
Your house is full of a bunch of 120VAC wiring. Well, that's assuming you live
in the United States, and to be fair US residential wiring is typically 240v
split phase, so you have both 240v and 120v wiring, depending on how you count.
The idea of this split phase thing, if you're not familiar, is that the utility
delivers to your house 240VRMS AC with a neutral wire that is at a potential
halfway between the other two pairs. We could label this -120V, 0V, and +120V,
which while "0V" is always arbitrary makes some sense since neutral is bonded
to ground. These are all of course VRMS, which in this context is Volts Root
Mean Square, not Virtual Richard M. Stallman (which is a piece of software that
chastises you for being complicit in your own subjugation). Since AC implies a
voltage that changes constantly, there are a few ways to measure, and VRMS is
conventional. 120VRMS is about 170V peak to zero, or 340V peak to peak. We call
it 120V because, well, that 170V only exists briefly at the two peaks of the
waveform. 120V is a more useful number for actual power calculations, although
AC power calculations can always become a bit complicated because the phase
relationship of potential and current can vary (this is called power factor).
This is all basically an irrelevant tangent, the point I want to make is that
we all understand that residential electrical wiring is 120VAC or 240VAC
depending on how you look at it [1].
But after all that, what if I told you that it is also conventional for
residential electrical systems to have a low-voltage AC supply?
Well, it's true, but in sort of a limited sense and with a lot of variations.
Almost all homes have at least one small transformer mounted on the side of a
junction box in a basement or closet that produces 12-24VAC. There are two
standard residential applications of low-voltage AC: the first is the doorbell,
which typically uses 16VAC although 12VAC and 24VAC doorbells also exist. The
second is the HVAC control circuit, which is nearly always 24VAC. Most of the
time these have two separate transformers but you can use one for both
purposes, although I'm not sure that it's wise or code compliant.
The reason for the low-voltage supply is that, in most cases, the thermostat
switches low-voltage, current-limited (by the transformer) circuits that
energize relays in the actual furnace/AC/etc. This allows thermostat wiring to
be significantly smaller, and thus cheaper and easier to install. Code
requirements for thermostat wiring are particularly lenient due to current
limiting in the transformer, so they're commonly only 18 AWG. 18 AWG is small
enough that the NEC ampacity tables don't even go that small; it's just not
permissible for non-current-limited circuits. The size savings are particularly
important since thermostats are most often hooked up using a five-wire cable.
The wires connected to a thermostat are conventionally identified by letters
(but usage of these letters is not entirely consistent) that primarily refer to
the conventional colors of the wires (while obviously a terrible practice, I
have encountered thermostats where the colors were not used according to
convention). In other words, if you are wondering what the "R" wire is, it's
the Red wire. That's what R means. Similarly G for Green, Y for Yellow, and C
for Blue (not to be confused with B for Blue). That's a joke, C is for Common,
but the wire is conventionally blue, but a lighter blue than the B wire.
Sometimes it's not blue. C is probably the one that varies the most.
Conventional (four|five)-wire systems
What do all these wires do? Well, the R or Red wire is the 24VAC power supply.
Less commonly, there can be separate R wires for heating and cooling, usually
labeled RH and RC. This usually happens when the heating and cooling equipment
are in different locations and installed at different times, so they each have
their own transformer without a connection between them. This actually comes up
a lot in New Mexico because of people replacing swamp coolers with refrigerated
air, which is often easier to do by putting a package unit (condenser and
evaporator in one unit) on the roof on the original swamp cooler plenum. In
this case the entire cooling system, from compressor to indoor air blower, is
all on the roof and usually has its own thermostat wiring run [2].
The basic concept of the thermostat is that it takes the 24VAC supply and
connects it to other wires, which go the coils of relays in the heating or
cooling equipment to actually turn things on and off. The most common of these
wires are W (White) which activates the heat, Y (Yellow) which activates the
cooling, and G (Green) which activates the fan. A typical simple thermostat
installation only provides these four wires: R, W, G, and Y. G is provided as a
separate wire for the fan to enable the fan auto/on switch that most
thermostats have.
But there's sort of a problem with this standard setup: 24VAC is available, but
it cannot be used as a general purpose power supply! The reason is that there's
no neutral wire to connect the 24VAC to that doesn't cause something in the HVAC
equipment to turn on. This is why many digital thermostats are battery powered.
Historically, the thermostat wiring was strictly a control circuit and could not
be used as a power supply.
Modern smart thermostats, though, involve typical computing industry horrors
like running a complete Linux environment, and therefore cannot run off of AAs
with any reasonable lifespan [3]. They require a constant external power
supply. This means they need a common, or C wire, which functions as a general
purpose neutral. The C wire is a relatively new innovation in thermostat wiring
and so a lot of homes don't have one, and on those that do the color can vary.
Both blue and black are fairly typical. The C wire is only used if you have a
thermostat that expects an external power supply; mechanical thermostats and
older digital thermostats typically did not. Many newer digital thermostats can
function off of either a C wire or batteries, but the combination of both is
ideal since it avoids regular battery changing but also allows the thermostat
to keep its clock during a power outage.
So now we have five wires, which as I said is the most common in a modern
residential installation: R and C (24VAC and common), G (fan), and W and Y
(heat and cooling).
There are more.
Some houses have more interesting HVAC equipment that involves extra wires to
control extra features, or that for historic reasons just uses a little
different control scheme.
Two-stage systems
Some homes are equipped with two-stage heat, two-stage cooling, or potentially
both. Two-stage cooling seems more common but that might just be because I live
in a climate that rarely stays below freezing all day, but does require all-day
cooling more often than I'd like to admit. In most cases thermostats exercise
only "bang-bang" control, a term that means that all they can do is turn a fixed
heat or cooling output on or off. But in a two-stage system, there is a "low"
setting and a "high" setting. In AC this is often implemented by having two
compressors.
For two-stage systems, there will be two wires, one for each stage. These are
usually called W1 and W2 for heat, and Y1 and Y2 for cooling. W2 is usually,
but not always, brown, and Y2 is usually, but not always, light blue.
Heat Pumps
Heat pumps usually add one difference and potentially a second. First, heat
pumps typically have some outdoor temperature at which they are no longer
more efficient than resistive heating (or in other words they become 100% or
less efficient, when heat pumps are typically more than 100% efficient.
For newer heat pumps this temperature is usually low enough to be pretty
uncommon, but older heat pumps in colder climates may get into this situation
regularly.
Heat pumps are almost always installed with resistive electric heating for this
situation. Switching to resistive heating in excessively cold weather basically
makes 100% the minimum efficiency. Older heat pumps usually called this feature
"emergency heat," but "emergency" sounds sort of dramatic and may have been a
factor in people avoiding heat pumps ("do heat pumps run into a lot of
emergencies?"). As a result, newer heat pumps and thermostats tend to call this
"auxiliary heat." Either term works but auxiliary is probably better since it
clarifies that the resistive heating is not just for situations where the heat
pump has failed (although it is a cool bonus that heat pumps usually provide
redundant heating, unlike gas or conventional electric heaters).
As you'd imagine, there's a wire for that. It's labeled "X" or maybe "Aux.",
and it can be basically any color. There's no agreed upon norm.
I'm actually oversimplifying somewhat as "emergency heat" and "auxiliary heat"
are technically different things, but it is still largely true that auxiliary
heat has replaced emergency heat. What happened is that older heat pumps
usually only used the resistive heat if the user turned on a switch on the
thermostat, usually in response to loss of heat---an apparent emergency. Newer
heat pumps usually turn on the resistive heat automatically, either when the
outdoor temperature is too cold or when the thermostat is trying to close a
large temperature difference quickly in which case the auxiliary heat just
provides a boost. This is sort of a two-stage heat system. These newer systems
still usually have an "emergency heat" switch on the thermostat which just
forces it to use the auxiliary heat only, should the heat pump have failed.
As an additional complication, some heat pumps use a fundamentally different
control scheme. I have never personally seen one of these, but I have read that
some brands still work this way. To understand it we need to consider how a
heat pump actually works: fundamentally, a heat pump does the same thing to
heat and cool, but the direction of the loop is changed. This is accomplished
by a "reversing valve." While many heat pumps have a heat and cool input (W and
Y) and set the reversing valve and run the compressor based on those two
inputs, some heat pumps use the W wire to run the compressor and then have an
additional wire which sets the reversing valve as a separate function. The
reversing valve wire may be powered for cooling (called B), or powered for
heating (called O) depending on the manufacturer. Trane heat pumps seem to use
a particularly eccentric scheme where B and O are both present but B energized
is the same as the un-powered state, B is used a a common wire (it doesn't do
anything, just like C on most thermostats) except when O is energized.
These wires are usually blue and orange, and called B and O as a result. The
functional equivalency of these wires in certain combinations with W and Y
wires results in a lot of thermostats having terminals that are labeled for
both functions, which leads to further confusion.
Line Voltage
Everything I have said so far relates to conventional control voltage
thermostats, which are most common because of their low install cost and
universal support in forced-air furnaces. But line-voltage thermostats, which
directly switch power to the device, also exist. Line-voltage thermostats are
very common in my region on swamp coolers, which have relatively low current
consumption and are traditionally controlled manually by a rotary switch or set
of light switches. Most swamp cooler upgrades to thermostatic control are just
done by putting a line-voltage thermostat in place of the old manual switches.
These thermostats are somewhat specialized since there are operational factors
specific to swamp coolers, for example the desire to pre-wet the media before
starting the blower and the popularity of two-speed blower motors.
Line-voltage thermostats are also common with radiant electric heating systems
like baseboard heaters and underfloor heating, where they're installed very
near the heater more or less in line with the electrical wiring already going
to it. They're also common for hydronic (water) heating systems, but this is
a bit of an odd case as hydronic thermostats are still usually just actuating
a control circuit... it's just that typical hydronic zone valves operate at
line voltage, not low voltage, and actually have a fairly substantial current
draw.
Wireless
Of course all of this nonsense with wires can be a huge pain, especially on a
retrofit installation of central heat or when relocating a thermostat for
better performance. To ease these kinds of situations and create a fun new set
of failure modes, there are plenty of options for wireless thermostats that
communicate with a box that "emulates" a traditional thermostat. The
receiver/controller can then be connected directly to the HVAC equipment and
the thermostat can go wherever you want. I had one of these once and the
thermostat required 8 AA batteries that died constantly. There have probably
been advancements in recent years.
Commercial thermostats
This simple scheme of the thermostat energizing relay coils is not very
practical in commercial buildings. In fact, it's not that practical in
residential buildings today either, and in modern heaters and air conditioners
the thermostat wires are not necessarily connected to relays but instead may
just be logical inputs to a control board. Still, the necessity of five or more
pair wiring to each thermostat is a cost issue in commercial buildings where
it is typical to have one thermostat in each room.
On top of that, commercial buildings tend to have a more complicated system
design in which variable air volume (VAV) equipment is used, which means that
thermostats control the amount of air delivered to a room instead of whether
or not heating or cooling is active.
Historically, variable air volume commercial HVAC systems were often pneumatic.
Rather than pressure based, they were vacuum based. Somewhere centrally in the
building, a vacuum pump pulled a decent volume of air through a system of tubes
running throughout the building. Vacuum lines were run to variable air volume
dampers (VAVs) and then to thermostats. In response to out of range
temperatures, thermostats would close or open the tube to the room air. In
response to the change in vacuum pressure on the line (which would increase, or
rather go more negative, when the thermostat closed its valve) a pneumatic
servo actuator in the VAV would adjust the damper. If you've heard a thermostat
making a constant faint whooshing noise, that's why... it's a pneumatic
thermostat admitting air into the vacuum line.
Of course this pneumatic scheme had its downsides, and as technology advanced
it became more attractive to use an electronic scheme. I am not very
knowledgeable in this area, having had only very limited interactions with
commercial HVAC equipment that mostly mounted to some collegiate security
research on manipulating the temperature of unpopular faculty member's offices.
Most modern commercial HVAC systems do seem to have consolidated on BACnet,
which is a general purpose communications protocol for building automation
equipment that originated in the HVAC industry (with a trade group called
ASHRAE).
BACnet is a fairly simple protocol (intended for easy implementation on
embedded devices) which has a lot in common with other protocols for similar
use cases. It's primarily what I call a "high level remote memory access"
protocol, meaning that it fundamentally consists of commands to read and write
addresses (called "properties" in BACnet, unlike say modbus which more clearly
shows its RDMA basis by calling them registers). BACnet enhances this model a
bit by adding a simple discovery scheme that makes setup of BACnet networks
easier. BACnet also specifies a set of standardized properties or addresses that
facilitate compatibility between vendors.
BACnet is agnostic to the physical layer, which can be Ethernet but is often
RS-485 or proprietary protocol LonWorks. An interesting property of BACnet
is that it seems to be fairly common for access to the BACnet physical medium
to be fairly easy to obtain, for installer convenience. In other words, a lot
of commercial thermostats just have a Euroblock-type connector on the bottom
that can be used to connect to the BACnet bus. You can imagine the potential.
[1] Unless you're on three phase delta power, which is a weird thing that is
common in apartment complexes. Then you have 120V and 208V for reasons that
require trigonometry.
[2] I live in a house with what I would call the New Mexico Transitional
configuration, meaning that I have a normal AC evaporator mounted on my central
furnace, but the condenser is nonetheless sitting on a platform on the roof on
top of the old swamp cooler plenum. I think when there's already a roof frame
for the swamp cooler this is just easier than putting the condenser on the
ground, especially since the refrigerant lines can be run straight down through
the old plenum or heater combustion air duct. It has the downside that the
central furnace and AC continue to use the old swamp cooler plenum which is
poorly sealed where the swamp cooler was removed and loses a lot of conditioned
air into the attic. Nothing that eighteen cans of Great Stuff can't fix.
[3] This is not strictly a limitation of smart thermostats, I've used an Emerson
Sensi thermostat which is WiFi-connected but still manages a reasonable life off
of battery power. Of course it has a basic LCD display and physical buttons, not
the full color touchscreen that everyone demands these days.
The greatest trend in telephone technology for the last decade or so has been
the shift to all-IP. While this change is occurring inside telco networks as
well (albeit more slowly), it's most visible in the form of IP-based end-user
communications devices. In other words, the ubiquitous office IP phone.
Office IP phones have gone through various forms as vendors have come and gone,
but I still tend to picture the Cisco 7900 series as the prototypical example.
Some of this association probably comes from the 7960's starring role in the
television series 24, where the fictional law enforcement and/or intelligence
agency and/or paramilitary CTU is absolutely lousy with them and their
distinctive ring tone. This is no coincidence, Cisco apparently had a generous
promotional consideration deal with the 24 production team that ensured a
number of Cisco office telecom products were clearly visible... and audible.
I'm not sure how many people can place it, but I think a large portion of
people around my age recognize the
ringtone.
A Tangent About a Ringtone
One wonders, of course, where the sound known to many as the 24 ringtone
actually came from. I wrote several paragraphs about the history of these ring
sounds as I understood it before I did some careful listening and realized I
was entirely wrong. Here's the issue: I thought, and from googling some other
people seem to think as well, that the "24 ringtone" was a stock ringtone on
Cisco 7900 series phones, and that it was a direct copy of a ringtone long
present on AT&T/Lucent/Avaya office phones that dates back to the AT&T Merlin.
The Merlin, a historically notable office key system for several reasons, was
also AT&T's first serious foray into digital, function-generator-based
ringtones. Merlin phones contain a simple sine-wave-only variable frequency
oscillator (VFO) to produce various beeps and blorps like keypress
confirmation. To produce a pleasing ringing sound, the phone drives this VFO
based on a simple "program" that consists of frequencies (in hertz) and time
periods (in milliseconds). This system works well enough that it still sees use
in telephone today, although the VFO is now software. Such "programs" are often
written in a compact text format, and most IP phones today still use this basic
approach for things like dial tone, ringback, etc... but for ringing proper,
they usually expect a "proper" audio file. Not so with the Merlin, which didn't
yet have the hardware to actually play audio samples. Lists of frequencies and
durations were all you got.
Someone at AT&T presumably spent a long time messing around with these simple
programs and it was worth it. The original eight Merlin
ringtones remain, in my opinion, some of the finest
phone ring sounds ever devised, and are still offered by many IP phones today.
Western Electric, which manufactured the Merlin, became AT&T Technologies,
which became Lucent, which became Avaya. These companies have largely honored
AT&T's legacy in this era and Avaya IP phones continue to have a minimalist
and commercial-feeling but also pleasing and thoughtful sound scheme... still
largely based on simple sequences of one or two tones.
This is of course strictly a matter of opinion, but I am incredibly irritated
by the path that phone sound design has taken. A modern smartphone, by default,
offers basically zero ringtones that actually sound like phones. I realize that
this comes from my idea of what a "phone" is having ossified when I was about
four years old, but I do think there's a good objective argument for communications
devices using simple, short, and highly recognizable notification sounds rather
than the sort of bizarre set of one minute compositions you tend to get today.
But let's get back to the first tangent here. It turns out my recollection here
was wrong: first, the "24 ringtone" is not actually a default ringtone on Cisco
phones, but is a "default custom" ringtone that is provisioned to phones by a
default installation of Cisco Call Manager (or Cisco Unified Communications
Manager later, when Cisco was a major driver of the brief Unified
Communications buzzword craze). Cisco IP phones are virtually always used with
Cisco Call Manager because they don't use SIP, but rather a Cisco-proprietary
protocol called SCCP (commonly referred to as "skinny," which was both an
earlier internal name and a reference to SCCP's goal of being simpler and
easier to implement on devices than SIP). As a matter of fact Cisco 7900 series
phones actually did support SIP if you re-provisioned them with a different
firmware image that Cisco provided for that purpose, but this was janky and
it's not something I've actually seen used outside of my own home.
So, since Cisco 7900s are almost always used with Call Manager and Call
Manager, by default, provisions the phones with these "custom" ringtones...
they're pretty much default. The issue is pedantic but still sort of
interesting, as it leads you to wonder what internal politics lead to
additional default ringtones being included as part of the install package for
Call Manager.
Second, though, and more importantly, the ringtone in question is not a
Merlin ringtone. The most widely heard ringtone in 24 is very similar to, but
noticeably different from, Merlin ringtone 6. The other ringtones heard in the
show (which are other Cisco Call Manager defaults) are also "very much but not
quite entirely" like the Merlin options.
This actually addresses a bit of a mystery to me. Cisco got its IP phone
business by acquiring (pretty much immediately after founding) a company called
Selsius. There is no historic business relationship between Cisco/Selsius and
AT&T/Lucent/Avaya, so it would seem surprising for AT&T's classic ringtones to
end up in a Cisco product. Well, they didn't, or at least not exactly. Although
I can't find solid proof, it seems virtually guaranteed to me that the the
Cisco Call Manager default set of custom ringtones are, in fact, ripoffs of the
Merlin tones. The 24 ringtone is a fake! Given the '80s era prestige of the
Merlin system, the Cisco ringtones are practically the "Louise Vittant" handbag
of the telephone world.
To be fair, though, whatever anonymous Cisco employee sat down to copy the
Merlin ringtones made some meaningful improvements. The staccato cadence of the
Cisco ringtones, as opposed to the Merlin's legato, is very distinctive and
probably more recognizable in a loud environment. It also sounds pretty cool,
which sure helps with a TV series about a vague counter-terrorism agency with
apparently superhuman abilities.
So here I'm 100 lines in and on a total tangent. I didn't mean to write about
ringtones, I just like them. What I actually wanted to write about has to do
with the ubiquity of IP phones themselves. Most office workers my age have
probably had an IP phone on their desks for pretty much their entire career. I
have, with the exception of one large institutional employer where I was lucky
enough to be among the last employees issued an ISDN desk phone. This was rare
enough by then that the amused telecom technician made a show of blowing the
dust off of the "voice terminal" that she had pulled out of a closet junk heap.
I actually loved that phone, but I loved it because it was weird and obsolete.
Despite their own eccentricities (which are significant enough that IP phones
are virtually always segregated to their own VLAN), IP phones are an
increasingly pedestrian part of IT infrastructure that lack some of the
intrigue of traditional analog and TDM instruments.
Despite the advantages of IP phones, a lot of organizations that make the
switch to IP end up with various odd analog phones left over that, for various
reasons, are more expensive to replace. It's fairly common to end up keeping
landline telephone service to buildings just to support these devices. And here
is the real purpose of this post: to tell you about a few cases where you will
very frequently find analog phones, even in organizations and facilities that
have otherwise switched to IP. The best part is that these are pretty much all
weird types of phones (that's what makes them hard to replace with IP), and
you know I love talking about weird phones.
Emergency Phones
One common category of holdover analog phones are emergency phones. The most
common case are elevator phones, intended for use by an elevator occupant if
they're stuck. In most cases, code requires elevator phones to use an outside
line to call an attended call center. This means that they're usually proper
phones hooked up to the PSTN. While IP elevator phones are available, they
don't seem to be very common. A big factor here is that the elevator phone is
typically hooked up by the elevator installer who will run an analog phone
line with the elevator travel cable. Adding ethernet later is a pain on its
own.
"Blue light" type emergency phones (whether or not made by the actual company
Code Blue) are also often analog, although new installations are likely to use
the IP versions.
Alarm Communicators
Burglar alarms historically used landline telephone for reporting almost
exclusively. Well, historically meaning since the 1950s or so. Prior to that
point there were a lot more private alarm monitoring networks in use that used
either dedicated pairs per monitored system or telegraph technology. Today, a
variety of burglar alarm reporting methods other than telephone are available,
but there are still plenty of landline phone communicators in service.
Alarm communicators are not limited to burglar alarms. Some devices like
generators and refrigeration equipment may be equipped with a device for
reporting any test failures or alarms. Like burglar alarms, today these are
often cellular and/or IP, but there's still older equipment out there using
analog telephone for reporting.
Access Control Systems
It's fairly common for access control systems, that is electronic door locks,
to be remotely programmable. This is common in small organizations where the
system is fully managed by a locksmith, and in large organizations where it
is managed centrally from a corporate office. Once again, newer systems are
moving to IP but there's a lot out there that relies on something like a
USRobotics modem for external access.
Paging and Radio Bridges
Something that I've personally seen a couple of times is held-over analog phone
lines to support audio bridges to an overhead paging system or to a handheld
radio service. There are plenty of IP bridges available for these kinds of
applications, but this is another area (like elevators) where you run into a
disconnect between contractors: if different organizations service the
telephone system and the paging or radio system, you can get stuck on analog
just because of the lack of coordination (and willingness to pay) for the
switch.
Some Miscellaneous Phone Devices
Analog phone lines lead to a lot of odd situations inside of commercial
buildings, especially smaller ones, both because they were easy to adapt to
many purposes and because adding more lines was pretty expensive. There
was an obvious desire to put more than one device on each phone line.
A common way to achieve this was via a device like "The Stick," which picked up
phone calls, detected the presence of a fax or modem carrier, and directed the
call to different ports as a result. These types of "lightweight switches"
produce some interesting opportunities for phone phreaking. With the popular
Stick, for example, DTMF sent immediately after pickup can be used to force it
to direct the call to a different port. This can reveal devices like modems
that otherwise don't "pick up."
The whole reason I personally know about The Stick is that I've seen it used
for remote programming modem access to the access control system in two
different buildings. There are obvious security implications of this practice.
How Analog Hides Out
So how do organizations that make a switch to IP support these existing analog
telephone devices? To some readers it might seem obvious that an ATA (analog
telephone adapter) could be used to connect them directly to an IP phone
system. In some cases this is true. But it's important to understand that many
VoIP systems use speech codecs that do not preserve enough bandwidth for
digital signaling to work. This is most commonly encountered in the case of fax
machines: a fax machine naively connected to VoIP via an ATA will likely work
unreliably or not at all, depending on the codec selected for the call.
Instead, legacy analog devices are often supported by just keeping conventional
telephone service. In a way this is a good solution, since some of these
devices are safety or security related, and the telephone network is operated
to a higher standard for reliability than most corporate networks. On the other
hand, this can become a real headache when a PABX is in use. Although a
somewhat extreme example (this was a very large organization with many legacy
devices) I have seen one case of an entire 5ESS kept in service basically for
analog (and some ISDN) cruft. This is a telephone switch of a scale that it has
a staff, albeit now a small one. More commonly, there are definitely some
smaller PABX systems that remain installed in commercial buildings to support
fire and access control applications. There may be few people with knowledge
of these switches and how they're configured.
Well, that was sort of a grab bag of topics but I hadn't written for a while
and it was on my mind. I'm in the midst of a remodeling project and life is
hectic in general at the moment, so I'm probably going to be following up with
some more posts on odd topics. For example, I'm thinking a lot about
thermostats right now, and I expect to write a bit on the curious world of HVAC
control signaling.
So we've talked about radio spectrum regulation in some detail, including the
topic of equipment authorization (EA)---the requirement, under 47 CFR, that
almost all electronics receive authorization from the FCC prior to sale. We've
also talked about the amateur radio service (ARS, 47 CFR 97), and I've hinted
that these two topics collide in an unusual way. So this of course raises the
question: does amateur radio equipment require authorization? Or, more fun to
type, does EA apply to ARS?
The answer is... it's complicated.
In fact, it's sort of surprisingly difficult to get a straight answer on this
question. 47 CFR itself is not very clear on this point, because of course the
authors of regulations are a lot more willing to throw in special cases to
resolve special circumstances than to provide a convenient general rule. While
amateur radio is mentioned in various places in Parts 2 and 15, and equipment
authorization is touched on in Part 97, there's no general requirement or
exception to be found in 47 CFR.
Further contributing to confusion, there is a lot of "armchair lawyering"[1] in
the amateur radio community. You will get different answers from different
people on even very basic questions about EA. Part of the reason is that the
rules have changed over time, less due to 47 CFR itself than due to enforcement
actions and regulatory guidance coming from the FCC Enforcement Burea. Part of
the reason is because people are repeating things they heard eighth hand from
somewhere in the 1950s. And, well, part of the reason is that amateur radio
operators enjoy a rather unusual privilege: generally speaking, there are no
EA [2] requirements for amateur radio.
In a way this is intuitive: amateur radio has a substantial tradition of
home-built or home-modified equipment. "Vintage" HF equipment are sometimes
colloquially referred to as "boat anchors" in reference to both weight and
typical market value while sitting on a hamfest vendor's table. But, as a
matter of fact, if you manage to construct a boat anchor into an RF transmitter
you are welcome to use it in the amateur radio service, subject to the
technical requirements of Part 97. A common way to explain this (common enough
that the FCC itself says it in a number of places, even though it is not quite
a literal part of the regulations) is to say that amateur radio privilege rests
entirely with the person holding the license. As a licensed operator, you alone
are responsible for the operation of your station... not the device
manufacturers. You can make use of anything, subject to good engineering and
amateur practice.
But I said it was complicated, didn't I?
The first reason is related to requirements on the sale of scanning
receivers. As a convenience and because it is fairly easy to implement with
modern electronics, almost all amateur transceivers on the market today offer
wide-band reception. Any device capable of monitoring two or more frequencies
between 30 and 960 MHz and switching to one on which a signal is received is
considered a scanning receiver (47 CFR 15.3(v)). As of 1999, all scanning
receivers require certification by the FCC (47 CFR 15.101(a)). Certification
is used here in its current sense in the regulations, meaning that the FCC
must actually review and approve the results of testing. A mere declaration
of conformity from the manufacturer is not acceptable.
In other words, the majority of amateur radio transceivers sold today are
actually subject to equipment authorization under Part 15, Part 97 be damned.
If you remember our talking about the verboten
band, this might be
familiar: the certification requirement for scanning receivers was created
specifically to prevent the sale of devices which would be used to eavesdrop on
analog mobile calls. This ruling somewhat inadvertently introduced a de facto
EA requirement for the amateur radio industry, and it is typical today for
amateur radio devices to somewhat incongruously bear a Part 15 Device label.
Amateur radio transceivers can be marketed and sold without certification under
Part 15 if, and only if, they do not meet the definition of a scanning
receiver... not particularly likely since wideband reception and dual VFO with
"dual watch" have become standard features on even the cheapest HTs. A more
likely type of device to not fall under this requirement are HF transceivers,
which are more likely to omit wideband reception and not have receive
capabilities above 30MHz. Still, this is not especially common.
Given that the first complication boils down to reaction to mobile phone
eavesdropping, it will perhaps be unsurprising (at least if you've read enough
of my radio rambling) that the second complication boils down to citizens band.
For primarily cultural reasons that are hard for anyone under 40 to really
comprehend, citizens band (CB) enjoyed a brief period of mass popularity,
during which it was the primary thorn in the FCC's side. Like other services
which are licensed-by-rule (e.g. FRS and GMRS), CB is available to individuals
without training or registration. To prevent the band becoming unusable, there
are strict limitations on CB equipment in terms of output power: 4 watts. That
doesn't sound like a lot, but remember that unlike the consumer radios we're
used to today, CB is HF. 4 watts travels surprisingly far below 30MHz,
conditions allowing.
What makes CB very different, from a regulatory perspective, from FRS and GMRS
was the absolutely huge extent of rule-breaking. While illegal operations at
e.g. higher than permitted power is not unheard of in FRS and GMRS, it is not
very common. At the height of the CB craze, illegal operation at 100W or more
became practically the norm. While there were higher-than-limit CB radios
available for purchase through various grey market channels, high CB output
powers were most commonly achieved by adding an external power amplifier.
Power amplifiers would probably be unfamiliar to most radio users today,
because we now use mostly VHF and UHF where power levels are relatively low
and linear amplifiers are troublesome for technical reasons. But in the HF
bands, still today in amateur radio, it's fairly normal to use a transmitter
with an output power of, say, 4 watts, and direct that power to an external
linear amplifier which uses it as the gate input for a very big power tube.
Power amplifiers were not legal to sell for CB use, but the CB band is close to
the popular 10 meter amateur band. Close enough, in fact, that a power
amplifier intended for 10M use will typically work acceptably when driven by a
CB radio. The inevitable result: truck stops suddenly diversified into the
lucrative amateur radio power amplifier market. Who amongst us has not stopped
into a Pilot Travel Center to upgrade our 10M rig to 300W output?
The FCC addressed this runaround of the rules by creating 47 CFR 97.315. This
exception to the general lack of EA rules in Part 97 states specifically that
any power amplifier capable of operation below 144 MHz is subject to equipment
authorization. The same section then provides broad exceptions for any such
amplifier that is built, modified, or purchased used, but only when the user
holds an amateur radio license.
What rules must such amplifiers meet to receive EA? 47 CFR 97.317 tells us that
the amplifier must exhibit zero gain between 26 and 28 MHz, not be easily
modified to demonstrate gain on those frequencies, and more broadly not be
usable for services other than amateur radio. 26 to 28 MHz is, of course, the
citizen's band. Just to reinforce this, along with some brief boilerplate
amateur radio is mentioned in Part 2 (which, remember, states the general
requirement for equipment authorization subject to whatever other part applies
to the device) only once... 47 CFR 2.1060(c), which says that "Certification of
external radio frequency power amplifiers may be denied when denial would
prevent the use of these amplifiers in services other than the Amateur Radio
Service." Here, the FCC protects "can be used for CB" as a reason to refuse
authorization under Part 97---in the one case where it's required.
Why the 144 MHz cutoff? I'm not sure exactly but there is an obvious direction
for speculation. 144 MHz is the start of the 2-meter band, which is for most
purposes the lowest amateur band that is not HF. Power amplifiers designed for
VHF and UHF use are fairly substantially different from those designed for HF
and would be unlikely to produce usable output when driven by any HF
transmitter, including a CB radio. The "below 144 MHz" rule seems to just give
a pass for those power amplifiers that are unlikely to be part of the problem.
Now, if an amateur radio power amplifier can be modified for use in CB radio,
what about a whole amateur transceiver? Yes, that's where the off-label CB
market went next. Remember Pilot truck stops? Agents of the FCC Enforcement
Bureau visited eleven of them in 2004---well into the decline of CB radio. They
are not famous for their quick reaction to new trends. Still, the FCC found
that these Pilot locations had oddly diversified again into amateur radio
retail.
It's part of the American tradition to dream big, and it ought to inspire us
all that Pilot aspired to best such barons of industry as Ham Radio Outlet
and.... no, that's it, HRO is actually the only brick and mortar amateur radio
retailer I have ever laid eyes on. The fact that their Portland location is
still open can only be explained by miracle.
Of course this was not really the case, what Pilot was selling as amateur HF
transceivers were just CB radios without equipment authorization. Or more
accurately, they were 10M transceivers that had been intentionally designed to
allow trivial modification to CB. For this bit of not-so-clever deception Pilot
was ordered to pay $125,000 to the FCC. That includes an extra bonus forfeiture
for continuing to sell them after the first set of violation notices was
issued.
This notice of apparent liability for forfeiture[3], FCC docket 04-272 or
better cited as 19 FCC Rcd 23113, is notable mostly because it is now the
primary citation given for the fact that amateur radio equipment does not
generally require equipment authorization. It states explicitly in paragraph 3
that "radio transmitting equipment that transmits solely on Amateur Radio
Service frequencies is not subject to equipment authorization requirements
prior to manufacture or marketing." Had the Enforcement Bureau not provided
that plain statement in this particular NALF, the lack of EA requirements for
amateur radio would remain a largely non-obvious consequence of the lack of any
particular EA requirements in Part 97 (other than the one about sub-144 MHz
power amplifiers).
Note though that, fortunately, the FCC didn't decide to address this problem by
adding an EA requirement for amateur radio transceivers that could transmit
anywhere near 30 MHz. Instead, the Enforcement Bureau finds that the existing
rules are quite clear enough. Any transmitter intended for use in CB must be
type certified for CB, and it was well established earlier in the CB craze that
"easy modifiability" does not work as a loophole. A device which is sold on the
premise that it can be easily modified for CB use is still, in the FCC's view,
a CB radio.
Nonetheless, illegal CB equipment remains pretty easy to obtain. A trivial
Google search found a 100W power amplifier for sale at just $88, apparently
from an Italian manufacturer. The internet has made regulation of the radio
market very challenging, as it has for most markets. Equipment is made for
legal applications in other countries and then imported, or just starts out
as a design for the US gray market.
This problem has become particularly large with the rise of the Chinese radio
manufacturing industry. There is a substantial global market for inexpensive
land-mobile radio equipment for business use, and many countries have rather
lax regulations on radio services and devices. LMR radios in the United States
are generally prohibited from being face-programmable, for example, but many
other countries have no such prohibition. A set of Chinese radio manufacturers
have emerged that sell products into this market. One of the cheaper ones has
become less of a brand and more of a category in the amateur radio market:
Baofeng.
Baofeng, more properly Fujian Baofeng Electronics Co., Ltd, was founded in 2001
by one Wang Jinding. With around 1000 employees, Baofeng produces a large line
of VHF/UHF handheld radios, or Handie-Talkies as amateurs charmingly still like
to call them (a term that dates back to WWII). For several years now, Baofeng
seems to be represented in the United States by Baofeng Tech or BTech. Baofeng
Tech conspicuously promotes themselves as based in the sub-1000 population town
of Arlington, SD, and indeed the Secretary of State has the filings for B-Tech
Distribution Inc, incorporated by one Andrew Brown. The same Andrew Brown at
the same address has formed a variety of LLCs with names like "Three B
Developments" and "Three B Investments," but I can find little else about them.
The About page on the Baofeng Tech website ends in "if you have accepted Christ
as your personal Savior – contact us today here to let us know and we will send
you a one time package of literature."
BTech has also sent a one-time package of literature to the FCC, as they
obtained equipment authorization on a number of Baofeng models based on test
results commissioned from Bay Area Compliance Laboratories of Dongguan. These
equipment authorizations are, in fact, type certifications for Part 90
land-mobile radio operation. As a result, for these models, it is perfectly
legal to market and sell Baofeng radios in the United States. It is, though,
still completely possible to purchase Baofeng models with no such equipment
authorization, often shipping direct from China. This would constitute a
violation of the FCC regulations on the part of the retailer.
But what of amateur radio? Type certifications are done against specific parts
of the FCC rules. The Part 90 certificate for the Baofeng models list specific
bands and modes (emission designators) for which they are authorized. Part 90
(private land-mobile radio) is not Part 97 (amateur radio), and so the radio is
not really authorized per se.
But the trouble here is, amateur radio is largely exempt from equipment
authorization in this way too. Much like Part 97 lacks equipment authorization
requirements (except power amplifiers) on manufacturers, it also lacks any
prohibition on the use of unauthorized equipment. In fact, both Part 2 and Part
97 contain exceptions to equipment authorization requirements that explicitly
preserve the ability of amateur radio operators to use any equipment they
choose. For example, Part 2 provides an exception to general requirements that
modifications be authorized by the FCC: Amateur license holders can freely
modify equipment for use in the amateur radio service. No approvals required.
It has for some time been a generally accepted practice to repurpose Part 90
equipment for amateur use. This was particularly true in the days of
crystal-based mobile radios, when many ex-police HF radios were modified for
amateur operation. I know of club repeaters today running on lobotomized
Motorola P25 (trunking system typically used by law enforcement) equipment. And
an active group of amateurs operates WiFi equipment in amateur bands, based on
their overlap with foreign WiFi allocations.
As a result of this exceptional latitude, amateur radio operators are, as far
as I can tell, completely permitted to use Part 90 authorized radios. Further,
amateur radio operators can use radios that are not authorized at all. This
actually shouldn't be that surprising: most amateur radios today only need
equipment authorization under the 1999 anti-eavesdropping rule. Prior to '99
most all amateurs were operating unauthorized equipment!
Nonetheless, the organizations marketing and selling these unauthorized models
are violating FCC rules. The FCC seems to have taken a light touch on the issue
of selling unauthorized equipment for amateur use, not just a bit because doing
so would only really violate normal Part 15 rules and not nominally harm any
licensed service. But the FCC has increasingly taken an aggressive position on
retailers selling unauthorized radios to non-licensed users. In a prominent
case, hobby vendor Rugged Radios received a threat of a forfeiture notice if
they did not cease sale of the RH5R (apparently a custom case version of the
Baofeng UV-5R) and other models. The target market was primarily offroad and
powersports users, who don't generally hold any radio license [4].
Offroad and powersports users might better be advised to use the
licensed-by-rule services MURS or CB [5], or even apply for an
industrial/business pool license as an organization (although the logistics of
distributing Part 90 radios are somewhat complex, since they must be programmed
externally). But Rugged Radios was selling unauthorized radios along with
materials that included lists of Part 90 and Part 95 frequencies. This clearly
constituted marketing of an unauthorized device to a use for which
authorization is required.
The importation of radios not built to US regulations will continue to be a
challenge in spectrum coordination. Incidents of drone FPV transmitters
directly interfering with aviation radar show the practical effects. I tend to
think, though, that the impact will always be limited: Today, consumer radio
use not controlled by a licensed entity is largely limited to the microwave
oven bands.
[1] This is as opposed to what I'm doing here, which is more like jailhouse
lawyering.
[2] or device certification, type acceptance, or type certification. The FCC
itself is not entirely consistent about how it uses these terms and they have
changed over time, including a find-replace amendment to 47 CFR to swap out
words.
[3] This has sort of come up a couple of times now. The FCC is not properly a
part of the government (it's an independent agency) and so it does not issue
fines. Instead, it issues Notices of Apparent Liability for Forfeiture, which
tell the target how much they are expected to pay as a civil matter. NALFs are
often attached to a Memorandum of Opinion and Order, which give an
interpretation of how the regulations apply to the present situation. Those
memoranda are sort of like court opinions in that they set precedent the
Enforcement Bureau will rely on later.
[4] Unless they happen to also be amateur radio operators. While there are
restrictions on the use of amateur radio for any commercial purpose, it's well
accepted to use amateur radio in the course of other hobbies. That is, an
amateur radio operator who also e.g. participates in off-road racing would be
permitted to use amateur radio equipment and spectrum for that purpose so long
as it is not a commercial activity (in which case the Part 90
industrial/business pool would be applicable). There is a particularly strong
tradition of amateur radio in the RC world, where many amateur radio operators
use amateur equipment and spectrum for telecontrol of RC aircraft and etc.
[5] MURS, the Multi-Use Radio Service, is a licensed-by-rule service similar to
GMRS but in low band where propagation in the open tends to be better. MURS
radios are more commonly mobile (i.e. automotive) than handheld, but ther are
both handheld MURS radios and mobile GMRS radios on offer. GMRS is a slightly
odd situation for that matter and there actually is such thing as a "GMRS
license," which confers privileges beyond those of licensed-by-rule users such
as repeater operation. This might also be attractive to off-road users. If you
chuckle at the common pronunciation "murrs" you are probably going to hell but
I am right there with you. Consult Baofeng Tech for advice on salvation.
One^wTwo days late for 4/20, I return to discuss equipment authorization. This
is a direct followup to my last post about unlicensed radio. I apologize for my
uncharacteristic decision to actually provide a promised follow-up in a prompt
manner, and give you my assurances that it's unlikely to happen again. I will
return to my usual pattern of saying "this is the beginning of a series" and
then forgetting about the topic for two years.
But equipment authorization is sort of an interesting topic, and moreover I
think I really shortchanged the last post by not going into it. Because ISM
bands and other so-called "Part 15" bands are unlicensed, the limitations that
exist on usage of those bands stem pretty much entirely from the equipment
authorization process. I also think I shortchanged the last post a bit by not
providing some background on the regulatory structure, so here that goes first:
when I refer to the "FCC regulations," I of course mean 47 CFR, or the 47th
title of the Code of Federal Regulations. The CFRs are a compiled version of
all of the regulations promulgated by various federal agencies and are not laws
(those are found in the USC) but are sort of like them. The difference is
basically in the way they are developed and changed: laws are set by
legislators, while regulations are set by the staffs of agencies, but typically
with some sort of formalized process that incorporates public comment. This
whole concept of codified regulations is referred to as "administrative law."
In practice, the way it works at the federal level (and simplified somewhat) is
that agencies develop regulations using their normal process, they publish the
new regulations in the Federal Register, and some staff pull the changes out of
the Federal Register and compile them into the CFR which provides a handy
reference to find all the federal regulations.
Because the stuff in the CFR comes from various agencies, it's broadly
organized by those agencies. So 47 CFR is stuff that comes from the FCC, while
the FAA produces what are often called the "Federal Aviation Regulations" but
are more properly known as 14 CFR. This is useful knowledge because the federal
government maintains eCFR.gov, a convenient website where you can browse and
search the current version of the CFRs. This is a lot more convenient than the
old system of going to a federal depository library to look at the big printed
volumes that are already out of date.
When discussing FCC regulations, it is very common to talk about them in terms
of Parts and identify services by the Part that describes them (this is broadly
a common way to refer to federal regulations) [1]. So when we say "Part 15
device" we are describing a device which emits RF radiation under the rules in
47 CFR 15. In 47 CFR 15.1(a) we read:
This part sets out the regulations under which an intentional, unintentional,
or incidental radiator may be operated without an individual license. It
also contains the technical specifications, administrative requirements and
other conditions relating to the marketing of part 15 devices.
So that pretty much lays it out. As a result, "Part 15 device" and "unlicensed
device" are somewhat synonymous. Devices that are used under a license are
discussed under other parts. Many types of license must be applied for, but
there are licensed services that are "licensed by rule." This means that they
are a licensed service covered in another part, but that license is granted
automatically subject to certain conditions. An example of a licensed by rule
service is the family radio service or FRS, which is one of the services used
by the ubiquitous consumer walkie-talkies made by companies like Motorola and
Midland. This is not a Part 15 or unlicensed service, but you also don't need
to apply for a license, as 47 CFR 95 says that you automatically have one.
Now, all of this so far is talking about radio services. This distinction can
be confusing because, particularly in Part 15, there is some crossing of the
lines. Broadly, though, a radio service is a means of using the RF spectrum and
the rules and regulations that apply to it. Point-to-point microwave is a radio
service. Broadcast FM is a radio service. Amateur radio is a radio service.
There is a separate issue of equipment authorization. I tend to refer to this
as device certification because that therm just makes more sense to me, but I
should break the habit because the FCC consistently uses the term equipment
authorization. Equipment authorization is broadly described in 47 CFR 2, and
particularly 2.801 and up (Part 2 is sort of a general or definitions section,
and contains the high-level rules for a lot of things). In 2.901, we read:
In order to carry out its responsibilities under the Communications Act and
the various treaties and international regulations, and in order to promote
efficient use of the radio spectrum, the Commission has developed technical
standards for radio frequency equipment and parts or components thereof.
The technical standards applicable to individual types of equipment are
found in that part of the rules governing the service wherein the equipment
is to be operated. In addition to the technical standards provided, the
rules governing the service may require that such equipment be authorized
under Supplier's Declaration of Conformity or receive a grant of
certification from a Telecommunication Certification Body.
I'll spare quoting all the different sections that really put this together,
but here is the general idea: you cannot market, sell, distribute, or use a
radio frequency device unless it has an equipment authorization (EA). Part 2
lays out the process for getting that EA, which are either a declaration of
conformity (manufacturer pinky promises it meets the rules) or an independent
test depending on the device and service.
But what are the actual restrictions a device must meet? They're contained in
the sections that describe services. For devices not associated with any
service, Part 15 serves as a "catch-all." Part 15 thus covers unintentional and
incidental radiators, and intentional radiators not associated with a licensed
service. Sort of a "miscellaneous" basically.
I'm not going to spend much time on Part 2 because it's mostly procedural and
not all that interesting. However, the prohibition on marketing laid out very
explicitly in 2.801 has important implications that you have probably seen in
the marketing of cellphones. You generally cannot advertise a device until
it has an EA. If you do, you must clearly state that the device cannot yet be
sold. Early marketing for cellphones often includes such a disclaimer:
This device has not been authorized as required by the rules of the Federal
Communications Commission. This device is not, and may not be, offered for
sale or lease, or sold or leased, until authorization is obtained.
Part 2 also provides some general exceptions. The basic idea is that it is
permissible to operate a device that doesn't yet have an EA on an experimental
basis with some protections and restrictions in place. It's even acceptable
to distribute a device prior to EA, as long as distribution is only to people
who will be using the device for testing/engineering/integration purposes and
they are aware of and comply with the restrictions. In other words, the FCC is
fine with prototypes, but requires that the prototypes be restricted to limited
uses.
Finally, when the FCC approves an EA it issues a number usually called an FCC
ID. Devices are required to be labeled with their FCC ID in a fairly
conspicuous way, although because designers hate labels the FCC now allows the
FCC ID to be presented in software and on packaging rather than physically on
the device in some cases. Most smartphones are now like this.
That's probably enough of Part 2. Since the actual certification requirements
are laid out in other parts, let's take a look at some, starting with our
favorite Part 15.
Remember how right up there I quoted 15.1(a) saying that Part 15 applies to
unlicensed devices? Let's just reinforce that real quick with 15.1(b) to remind
us what's up.
The operation of an intentional or unintentional radiator that is not in
accordance with the regulations in this part must be licensed pursuant to
the provisions of section 301 of the Communications Act of 1934, as
amended, unless otherwise exempted from the licensing requirements elsewhere
in this chapter.
So this is basically the converse. If it's unlicensed, it's Part 15. If it's
not Part 15, it needs to be licensed.
First, there's an interesting question of what devices are considered radio
devices and thus subject to EA. It's fairly clear that any device that radiates
RF radiation is either a license device or a Part 15 device and is thus subject
to EA requirements. But what's RF radiation?
(u) Radio frequency (RF) energy. Electromagnetic energy at any frequency in
the radio spectrum between 9 kHz and 3,000,000 MHz.
Okay so I set that up as a bit of a joke because this definition is kind of
funny, but it's funny in an important way. For the purposes of FCC regulation,
the radio spectrum ranges from 9kHz to 3THz. Below and above that range, it's
not considered RF. Above tends not to be an issue because if you go much past
3THz you start being able to see it. Below 9kHz is a different issue: lots of
devices emanate EM fields below 9kHz, but the FCC does not consider them to be
RF devices.
Important implication: with few exceptions, any device that contains a clock or
pulse of 9kHz or greater is a device that emits RF. In fact, the FCC is quite
explicit elsewhere in the Part 15 definition that any digital device with a
clock speed higher than 9kHz is an RF device, because it can be expected to
emit some RF noise within the range considered the RF spectrum. This is the
reason that virtually all electronic devices are subject to Part 15 regulation.
If you don't want to deal with the FCC, 9kHz is effectively the speed limit for
any kind of pulsing or modulation.
Also very important to understanding my previous post is 15.5(a):
(a) Persons operating intentional or unintentional radiators shall not be deemed
to have any vested or recognizable right to continued use of any given
frequency by virtue of prior registration or certification of equipment...
(b) Operation of an intentional, unintentional, or incidental radiator is
subject to the conditions that no harmful interference is caused and that
interference must be accepted that may be caused by the operation of an
authorized radio station, by another intentional or unintentional radiator,
by industrial, scientific and medical (ISM) equipment, or by an incidental
radiator.
In other words, the FCC doesn't give a shit about your WiFi network. There is
some nuance to the term "accepted" here. They're not saying that Part 15
devices aren't allowed to shield themselves from interference. They're saying,
in casual parlance, that Part 15 devices must put up and shut up. They don't
have any regulatory protection from interference.
15.15 provides some very general engineering guidelines for Part 15 devices. I
will not quote them, because they can be well summarized as "do a good job."
The gist is that Part 15 devices must employ good engineering practices to
minimize their RF emissions, and under no circumstances can exceed the
specified limits.
15.23 is the home use exception. This should be of interest to all hobbyists
and "makers." It essentially says that it is permissible to build and operate
an RF device without an EA as long as it's for personal use, you don't market
it, and you build fewer than 5. You are required to use good engineering
practices to limit RF emissions, but you aren't required to perform testing.
"It is recognized that the individual builder of home-built equipment may not
possess the means to perform the measurements for determining compliance with
the regulations" (15.23(b)). Thanks, FCC.
The majority of the remainder of Part 15 involves detailed technical standards.
It lays out the emission limits and the ways that those limits should be
measured. It's fairly long and boring, but also pretty easy to read, so you
can feel free to take a look through it on your own time.
It is useful to understand that the limits and means of measurement vary by
band and sometimes types of device, but for the most part "transmit power" is
not a factor. This makes sense in light of the fact that Part 15 applies to
unintentional or incidental radiators where there is no "transmit power." Part
15 limits are primarily specified in terms of field strength, in volts per
meter, at various distances from the device. Rules about power and antenna
characteristics are mostly reserved for licensed services, although there are
some found in Part 15. For example, WiFi devices are mostly subject to a 1w
transmit power limit, in addition to the limits on field strength, and there
are more restrictive special limits if a high-gain antenna is used. This is
some of the confusion of Part 15: WiFi is not a licensed radio service, but
rules have been added to Part 15 to regulate it sort of like one, as far as
having restrictions on power and antenna characteristics. It also implies
that you can make a WiFi device non-compliant by fitting a high-gain external
antenna. You can!
Notable as well is 15.103 which provides some "soft" exceptions. 15.103 is a
list of types of devices which are subject to the general high level Part 15
rules, but not to the specific testing requirements. They include some major
categories like things used exclusively in vehicles, medical devices used under
supervision of a physician, and some digital devices with clock speed under
1.705MHz which are strictly battery powered (tends to apply to remote
controls). These exceptions combine two different motivations: first, some of
the excepted devices are excepted because they pose a very low risk of emitting
problematic interference (simple battery powered electronics). Second, some of
the excepted devices are subject to other engineering, regulatory, and
application controls that limit the risk of interference (vehicle components
and medical devices).
Finally, remember U-NII from the last post? the spectrum that allows for 5GHz
and 6GHz WiFi? it's not a service, it's still Part 15, and it's discussed
specifically in 15.401 and up. This includes the special characteristics of
U-NII that I mentioned like DFS (radar avoidance) and AFC (automatic
coordination).
Let's compare and contrast Part 15 to parts that cover licensed services. An
obvious one is Part 73, Radio Broadcast Services. This includes your AM and FM
radio stations. Much like Part 15, Part 73 is heavily concerned with limits on
these broadcasters, but unlike part 15 they are generally expressed in terms of
transmit power (which can actually be measured a few different ways, the
regulations clarify how for each service) and antenna characteristics. More
interesting is the type of emission regulation that really distinguishes a
licensed service from Part 15: Part 73 describes the rules to protect broadcast
stations from interference. Methods and calculations are described to
determine, for example, whether or not an AM station is sufficiently far away
from another AM station on the same or nearby frequency to avoid the two
overlapping. Unlicensed devices must accept interference, licensed devices are
generally protected from interference by the regulations.
The exact details of these limits can get fairly technical. Part 15 includes a
number of formulae, Part 73 has even more as it gets even into the modulation
used by transmitters. This is one of the reasons administrative law is
differentiated from legislation: the details of regulation are often very
technical, and so they are developed and evaluated by technical professionals.
These things can be tricky, and so in places Part 73 reads almost like a
textbook. In a number of spots it specifies the formula to be used, and then
provides an example calculation just to make sure you really get it.
There are things like this (47 CFR 73.151(c)(2)(i)):
The computer model, once verified by comparison with the measured base
impedance matrix data, shall be used to determine the appropriate antenna
monitor parameters. The moment method modeled parameters shall be established
by using the verified moment method model to produce tower current
distributions that, when numerically integrated and normalized to the
reference tower, are identical to the specified field parameters of the
theoretical directional antenna pattern. The samples used to drive the
antenna monitor may be current transformers or voltage sampling devices
at the outputs of the antenna matching networks or sampling loops located
on the towers...
Who knew regulations could be so fun! This is basically getting into the
details of how the specifications of a directional antenna array for an AM
radio station can be established. Antenna engineering is complex and I barely
understand the most basic parts of it. When you get into arrays operating at
low frequencies it can get very complex indeed and so the FCC specifies that
computer modeling alone is not enough, the actual performance needs to be
verified against the model.
How about another? Part 90 covers Private Land Mobile Radio Services. Land
mobile radio (LMR) is a broad category of portable radios used on land...
mostly handheld or in vehicles. LMR is a pretty big category because it
encompasses everything from public safety dispatch to some cellular bands (most
cellular bands in use today are part of other services, though). Land is
specified because aviation and marine radio are both their own services.
Part 95C describes the Industrial and Business Pool, a widely-used service for
everything from non-government vehicle fleets to some retail store handheld
radios. A few different types of users are eligible to use the pool but under
47 CFR 90.35(a) it basically comes down to "anyone who is in business, and most
organizations that aren't in business as well."
47 CFR 90.35(b)(3) is a lengthy table that lists the frequencies available for
industrial and business use, which span many bands but are most dense in the
popular VHF mid area (140MHz or so) and UHF low area (460MHz or so). These are
very popular parts of the spectrum in general as they have good propagation and
penetration characteristics and RF electronics for these wavelengths are
relatively easy to construct. Amateur radio operators might recognize these as
being more or less the 2m band and the 70 cm band [2], which are also perhaps
the most popular bands in amateur radio. Most mobile radio services have some
frequencies allocated in these areas and so they are fairly densely packed with
different users. This approach highlights one of the many variations between
different radio services: some radio services are allocated a band, some radio
services are allocated a list of bands or even a list of specific frequencies
scattered across many bands.
As with most things in radio regulation, this table comes with caveats and
exceptions. For example, a number of I/B pool frequencies in the UHF band
overlap UHF aviation radio used by the military. Note 61 on the table
states that these frequencies cannot be licensed near any of a long list of
airports and bases, and are subject to a lower power limit elsewhere.
Let's dwell for a moment on this topic of UHF military aviation radio, as it is
an example of an important complexity of US spectrum regulation. Military
aviation radio is not an FCC radio service. The FCC is an independent agency
created by Congress. This means that while its leadership is appointed by the
President and confirmed by Congress, it is not a part of any branch of
government. For both historic and present reasons, the executive branch of the
federal government maintains its own, separate authority to authorize radio use
in the form of the National Telecommunications and Information Administration,
which derives its authority directly from the President. Because the military
is also part of the executive branch, its authority to use radio is granted by
the NTIA and not the FCC. Obviously the NTIA and FCC must coordinate their
activities to avoid conflicting allocations.
There can be some nuance to the line dividing NTIA and FCC authority. Aviation
is once again a good example. Because VHF aviation radio is used by a wide set
of individuals in the aviation field, and not only by the executive branch, it
is regulated by the FCC (Part 87). The FAA, though, uses radio for its own
internal purposes, such as for communication between control centers and remote
equipment like radars and radio transceivers. Since this use is entirely within
the executive branch, it is regulated by NTIA. Air traffic control thus
simultaneously involves FCC and NTIA services, although the NTIA services are
not exposed to pilots, since they are not part of the executive (except for
military pilots, who are!). Further illustrating this complexity, the FAA has
chosen to fully contract the operation of most of its radio facilities to a
private company (L3Harris), on an M&O basis. Because Harris is not part of the
executive, they must gain authorization from the FCC... leading to a process of
the FAA "turning in" its NTIA licenses so that Harris can apply for an FCC
license for the same equipment.
It is a somewhat common misconception that NTIA authorizations are somehow
secret. This is not the case; while the NTIA has failed to provide the online
records access that the FCC does, you can submit a FOIA request to the NTIA
and receive in response a PDF of over 3,000 pages listing all NTIA frequency
allocations. I have several times started on writing a parser to convert this
report into a more usable database but I fear my lack of a computer science
degree proper shows here and I have not succeeded. Maybe that automata class
everyone else in the department took was good for something.
We will return to the topic of Part 90 to examine one last interesting aspect:
frequency coordination. The role of the FCC is often mis-described as being
coordination of frequencies. While there are exceptions, for the most part the
FCC restricts itself to coordination of services and leaves the more detailed
work to other organizations. In aviation, for example, the FAA does the actual
frequency allocation. In the industrial/business pool, frequency coordination
is entrusted to private corporations that have obtained a certification from
the FCC. So, the first step in applying for an I/B license is typically to
contact one of these organizations and receive their "suggested" frequency.
You then include a letter from the coordinator as an attachment to your
application, to show the FCC that you are requesting that particular frequency
for a good reason. Many variations on these models exist, but the rule of
thumb is that the FCC allocates bands or frequencies to a service, and what
goes on within the scope of that service is coordinated by someone else.
Broadcast radio is a very notable exception, since the FCC itself is also the
agency responsible for non-spectrum regulation of broadcast radio.
Let's wrap up by discussing one last service, and I'll make this a fun one:
Part 97, the amateur radio service. One of the interesting things about Part 97
is that it makes frequent reference to radio-telecommunications as an art, e.g.
listing one of the purposes of the amateur radio service as "continuation and
extension of the amateur's proven ability to contribute to the advancement of
the radio art" (47 CFR 97.1(b)). This is a more aspirational view of
communications technology which I attempt, but mostly fail, to capture in my
writing: since the time of Marconi, Fessenden, etc., radio has been the type of
human achievement that is appealing on both practical and aesthetic grounds.
Unfortunately, just as the consolidation of airlines and decay of entry-level
general aviation has largely robbed flight of its romance, the consumerization
of radio technology has removed much of the fun. Still, though, if you want to
twiddle knobs and strain to hear through static, amateur radio is here for you.
It's a lot of fun! And besides, the promise of advancement to the art seems to
continue to pan out. The new generation of amateur radio operators has
developed a number of innovative digital techniques and built infrastructure
that is useful for theoretical and industrial research on atmospheric physics,
propagation, astronomy, etc. Improvements in technology seem to now be driving
a return to commercial use of HF radio, long of limited use due to a degree of
complexity that tends to require an experienced operator. Many of the methods
being used to automate HF operations are derived at least partially from
dweebs tinkering around with GNU Radio for fun.
Anyway, enough of that. Let's look at the rules. 97.5 lays out the basics,
namely that amateur radio stations must be "under the physical control of" a
person who holds a license. There are various nuances to this rule but for the
most part a very literal reading works. The main caveat is that the licensed
operator need not be physically present; subject to some limitations amateur
radio stations may operate unattended or by remote control as long as
reasonable measures are in place to prevent tampering.
Much of Part 97 is fairly obvious and uninteresting, although there are some
regulatory oddities like the fact that the National Environmental Policy Act
applies to amateur radio and so amateur radio operators may need to complete
environmental impact statements when siting stations or equipment in areas
of environmental, historic, or cultural significance. NEPA is sort of a hobby
interest of mine and I'll probably write about it in more length eventually.
On the flip side, Part 97 provides some positive protection to amateur radio
stations. 97.15(a):
Except as otherwise provided herein, a station antenna structure may be
erected at heights and dimensions sufficient to accommodate amateur service
communications. (State and local regulation of a station antenna structure
must not preclude amateur service communications. Rather, it must reasonably
accommodate such communications and must constitute the minimum practicable
regulation to accomplish the state or local authority's legitimate purpose.
See PRB-1, 101 FCC 2d 952 (1985) for details.)
This was added in response to a series of municipal governments enacting zoning
regulations that prohibited antenna structures. Radio, though, is regulated by
the federal government, which claims supremacy on the topic. State and local
laws generally cannot prevent activities which the FCC permits. A similar
situation exists in aviation, where the FAA has supremacy, and leads to a
confusing paradox related to bans on UAS or "drones" enacted by state and local
governments. They lack the authority to do so, and so these bans are actually
bans on ground operations, not flight. This whole federation thing can be
complicated.
What about frequency coordination? 97.101 tells us that "Each station licensee
and each control operator must cooperate in selecting transmitting channels and
in making the most effective use of the amateur service frequencies. No
frequency will be assigned for the exclusive use of any station." In other
words, in keeping with the nature of amateur radio as a loosely regulated,
hobbyist service, frequency coordination is light. Various organizations,
typically the ARRL or organizations under its auspices, perform various types
of frequency coordination in the amateur service. For the most part, this is
purely voluntary and does not have the force of regulation, although one could
argue (and the FCC has) that willfully ignoring organized frequency
coordination constitutes a failure to operate in accordance with "good amateur
practice" as is required at the beginning of 97.101.
97.111-97.117 regulate the use of amateur radio. The general idea is that
amateur radio cannot be used for commercial purposes and is intended only for
two-way (that is, not broadcast) use with limited exceptions. 97.119-97.221
provide regulations related to the operations of different types of stations
and functions. 97.301 lists the authorized bands, with many caveats depending
on the particular band. A notable thing about amateur radio is that it often
shares its bands with other services. This is pretty common overall: a lot of
radio services are allocated bands or frequencies on a secondary or shared
basis, which makes more efficient use of the spectrum but does require radio
users to take precautions to avoid interfering with other band users.
The rest of Part 97 deals with administrative details; things like exams,
licensing, reporting, etc. It's the kind of thing that isn't much fun to read,
but is useful to be familiar with a an amateur radio operator.
This concludes our general tour of 47 CFR. This has gone on for quite a while,
and the great thing is that I still didn't get to the thing I meant to
explain... the sort of odd rules regarding equipment authorization and amateur
radio. But still, there's a lot here that gets towards that point: equipment is
almost always required to be authorized by the FCC, and the specific
requirements for authorization come either from Part 15 or from the Part that
covers the service for which the equipment is to be used. As a result,
equipment authorization is specific to a service. Generally speaking, a Part
15 device cannot be used in any licensed service. A device authorized under
another Part can be used only with the specific service for which its
authorized. The FCC itself sometimes refers to this as "type certification" or
"type acceptance," and it is the dominant area where device manufacturers,
marketers, and users are currently getting in trouble. So let's get into that
topic properly... later.
[1] The CFRs are actually organized into chapters and subchapters for reading
convenience, but the parts are numbered straight through. So no one ever writes
"47 CFR I.A.15," just "47 CFR 15" or "Part 15" will do.
[2] For historic reasons amateur radio has a habit of referring to bands by
wavelength rather than frequency, which I have always found frustrating. This
is no longer common in most forms of commercial radio, where the IEEE radar
band designations are more common (VHF low/mid/high, L band, C band, etc).
Not that these are really any more convenient.
I had a strong feeling that I had written a post at some point in the past
that touched on license-free radio services and bands. I can't find it now,
so maybe it was all a dream. I wanted to expand on the topic, so here we are
either way.
As a general principle, radio licensing in the United States started out being
based on the operator. As an individual or organization, you could obtain a
license that entitled you to transmit within certain specifications. You could
use whatever equipment you wanted, something that was particularly important
since early on most radio equipment was at least semi-custom.
In some cases licenses rested with individuals, and in others they rested with
organizations. It tended to depend on the type of service; in the maritime
world in particular radio operators needed to hold licenses regardless of the
separate station licensing of the ship.
In other services like most land-mobile radio, a license held by an
organization may entitle its staff to use radios (within license parameters)
with no training or qualifications at all. These types of radio services impose
limitations intended to prevent unqualified users from causing undue
interference. A common example is the prohibition on face programming of most
land-mobile radios in business or government use: restricting users to choosing
from pre-programmed channels prevents use of unlicensed frequencies, based on
the assumption that the pre-programming was done by a competent radio
technician. This doesn't always hold true in real organizations [1] but the
idea, at least, is a good one.
Today, though, we most commonly interact with radio in a different form:
services that are fully unlicensed. We use WiFi constantly, but neither
ourselves nor our organizations have a radio license authorizing it. You might
think that the manufacturer of the equipment, perhaps, holds a license, but
that's not really the case. The reality is strange and a result of
happenstance.
Early in the history of radio, it was discovered that radio frequency had
applications other than communications. As a form of electromagnetic radiation,
RF can be a useful way to deliver energy. In 1933, Westinghouse demonstrated
the use of a powerful shortwave transmitter as an oven. This idea was not
especially practical due to the physics of heating with low-frequency RF, but
the basic concept became quite practical around a decade later when a Raytheon
engineer famously noticed that a specialized type of transmitter tube used for
radar systems melted a chocolate bar in his pocket. One wonders if the
localized heating to his body this would have involved as well was noticeable,
but presumably RF safety was less of a workplace priority at the time.
This specialized transmitter tube was, of course, the magnetron, which has
largely fallen out of use in radar systems but is still used today as the RF
transmitter in microwave ovens. A magnetron is a vacuum tube that exploits some
convenient physics to emit RF at a fairly high level of efficiency, and with
a fairly compact device considering the power levels involved. As a downside,
the output of magnetrons is not particularly precise in terms of frequency
control, and is also not very easy to modulate. This makes them unattractive
for modern communications purposes, but quit suitable for non-communications
use of strong RF emissions such as Totino's pizza rolls.
This whole tangent about the history of the microwave is a way to introduce a
field of RF engineering different from what those of us in the information and
communications industry usually think of. We could broadly refer to these
applications as "RF heating," and while the microwave oven is the most
ubiquitous form there are quit a few others. The use of RF for localized
heating, for example, is useful in a number of situations outside of the
kitchen. Synthetic textiles, particularly for more technical applications like
tents and life jackets, are sometimes "seamed" using RF welding. RF welders
clamp the fabric and then put a strong HF signal through the join to cause
heating. The result is similar to direct thermal welding but can produce a more
reliable join for some materials, since the heating process is more even
through the thickness of the material. Similarly, a variety of instruments are
used in medicine to cause RF heating of specific parts of the body. While
normally RF heating of the body is a Bad Thing caused by poor safety practices,
surgeons can apply it to destroy tumors, cauterize wounds, etc.
RF is also useful for non-heating purposes due to the way it penetrates
materials, and there are various measurement instruments that pass RF through
materials or emit RF and observe reflections. I am of course basically
describing bistatic and monostatic radar, but many of these devices are far
smaller and lower power than radar as we typically think of it and so it's
useful for them to be available without complex licensing or coordination
requirements. A somewhat extreme example of such devices are the millimeter
wave imagers used in airport security, which take advantage of the minimal
water penetration of very high frequencies in the range of 60GHz and above.
This whole category of RF devices is an interesting one because they are not
"radios" in the typical sense, but they still use the same spectrum and so
impact radio use. This is a particularly important issue since many RF heating
devices operate at very high power levels... few people possess a radio
transmitter in the range of a kilowatt, but most people have a microwave oven.
As a result, radio spectrum regulators like the FCC need to coordinate these
devices to prevent them causing severe interference with communications
applications. It was the microwave oven which first revealed this need, and so
it's no surprise that shortly after the Raytheon chocolate accident the FCC
proposed a set of bands which it called Industrial, Scientific, and Medical, or
ISM---this term intended to encompass the set of non-communications RF
applications known at the time (microwave ovens had not yet become practical
for home use).
The microwave oven continues to serve as an excellent case study for the
evolution of unlicensed radio, because for several reasons microwave ovens
operate at around 2.4GHz, and so one of the original ISM bands is the 2.4GHz
band. That number will be familiar because most WiFi standards except very old
ones and very new ones operate in that same band. What gives? Why does a
sensitive, high-rate digital radio system operate in a band that was explicitly
reserved for being hopelessly splattered by a thousand microwave ovens?
The answer is licensing. Because the ISM bands were basically reserved to be a
no-man's land that non-communications devices could freely emit into, there are
no licensing requirements for ISM emissions. ISM devices must pass only a
device certification process which exists mostly only to ensure that they do
not produce external emissions outside of safety limits or emit in other bands.
In other words, WiFi uses the 2.4GHz band because it's the easiest one to use.
Other ISM bands show the same problem. 900MHz is reserved for ISM applications,
also mostly for heating, but was widely used by cordless phones and baby
monitors. The lower ISM bands, in the HF range, are typically not used by
consumer devices due to the higher cost of HF power electronics, but there are
exceptions.
These unlicensed communications applications of the ISM bands have been
formalized over time, but remain from their origin a workaround on licensing
requirements. This original sin of many consumer radio devices is the reason
that, early on, microwave ovens were a major source of problematic interference
with radio devices. The thing is, everyone blamed the microwave ovens even
though it was actually WiFi that was intruding in spectrum that rightfully
belonged to hot pockets.
One might wonder why these unlicensed systems use bands that are allocated to
ISM applications, instead of bands that are actually intended for unlicensed,
low-power communications. The short answer is politics, and the longer answer
is that no such bands existed at the time (in usable parts of spectrum) and the
process to create them was a long one. Remember that for most of the history of
spectrum regulation radios were big, expensive devices that required expertise
to operate. It was the expectation that everyone using a radio either had a
license or had been issued it by a licensed organization. It was cordless phones
and baby monitors that really started to chip away at that expectation, and WiFi
caused it to completely collapse.
We talked about 2.4GHz WiFi, and so you might be wondering about 5GHz WiFi...
the band used by 802.11a, and at least optionally in 802.11n, 802.11ac, and
802.11 "WiFi 6" ax. There's good news: 5GHz is not an ISM band. Instead, it's
allocated for "Unlicensed National Information Infrastructure," or U-NII. The
term is both weirdly vague (Information Infrastructure) an weirdly specific
(National), but U-NII's history is revealing. The 5GHz band was first widely
applied by the HIPERLAN standard, an ultimately unsuccessful competitor to WiFi
in Europe. The model of HIPERLAN, though, caused none other than Apple Computer
to start the regulatory process to allocate a similar band in the US for
computer networking. Originally, in 1995, Apple largely envisioned the band
being used for wide-area networking, or what we might now call WISPS, but the
rules were made sufficiently general to allow for local area applications as
well. Apple never succeeded in this product concept but the band was selected
for 802.11a. 801.11a had limited success due to higher cost and poorer range,
and subsequent WiFi standards returned to 2.4GHz... but as interference became
a major problem for WiFi that lower range became more attractive, along with
the many advantages of a more dedicated band allocation.
The U-NII band was allocated relatively late, though, and so it comes with some
complexities. By the time it was allocated for U-NII it had already been in use
for some time for radar, and indeed the issue of 5GHz WiFi interfering with
radar proved severe. To resolve these issues, many 5GHz U-NII devices are now
required to implement a feature called Dynamic Frequency Selection or DFS. This
might be better referred to as "radar dodging," because that's what it does.
5GHz WiFi APs actively monitor the channel they're using for anything that
looks like a radar emission. If they detect one, they switch to a different
channel to avoid it. Because radar is relatively sparsely deployed, this
usually works quit well. If you live near an airport, for example, there may be
a terminal weather radar at 5GHz that will quickly scare your WiFi network off
of a particular channel. But it's almost always the only such radar anywhere
nearby, so there are still other channels available. The issue becomes a bit
trickier for higher-performance WiFi standards like WiFi "802.11ax" 6 that use
wider channels, and so some people might see more issues caused by DFS
(probably the 5GHz AP shutting off entirely), but this should remain uncommon.
WiFi continues to grow as a radio application, and so too does its allocated
spectrum. Just a couple of years ago, the FCC allocated a huge swath---5.925 to
7.125GHz---to unlicensed communications systems, as secondary users to existing
mostly point-to-point microwave links. This range has effectively been glued on
to the top of the existing U-NII, and so it is referred to as U-NII 5 through
U-NII 8 (U-NII 1-4 being the original 1997 allocation). Once again, WiFi must
take actions to play nice with existing spectrum users. Indoor WiFi APs don't
have to do anything too special but are limited to very low power levels to
ensure that their emissions do not substantially leak outside of the building.
Outdoor APs are allowed a higher power level since potential interference is
inevitable in an outdoor environment... but there's a cost.
Outdoor 6GHz WiFi APs must use "automatic frequency coordination." AFC is not
yet completely nailed down, but the general idea is that someone (I put my
money on L3Harris) will operate an online database of 6GHz spectrum users. AFC
WiFi APs will have to automatically register with this database and obtain a
coordinated frequency allocation, which will be selected by the database to
prevent interference with existing fixed users and, to the greatest extent
practical, other 6GHz WiFi APs. This system doesn't actually exist yet, but
we can expect it to add a layer of management complexity to outdoor use of
the 6GHz band that might limit it to campus operators and other enterprise
WiFi systems, at least in the short term.
But then the issue is kind of moot for the moment, because there are very few
actual 6GHz WiFi devices. In keeping with the decision to brand 802.11ax as
"WiFi 6," 6GHz application is called "WiFi 6E." We can all ponder the direct
parallels to the confusing, but the other way, marketing term DECT 6.0. At the
moment only indoor WiFi 6E APs are available (due to AFC not yet being
standardized), and only the very cutting edge of client devices support it.
This includes the Pixel 6, but not yet any iPhone, although it's a pretty safe
bet that the iPhone 14 announcement will change that. A few mini-PCI-e form
factor WiFi 6E adapters are available, often called "tri-band," and are
starting to pop up in high-end laptops. As usual with new bands, it will be
some years before WiFi 6E finds common use.
Of course I am upgrading my home APs to 6E models, so that whenever I use my
Pixel 6 Pro I can feel just a little but smug. That's the important thing about
new WiFi standards, of course: spending nearly a grand on an upgrade that only
even theoretically helps for your phone, where real-world performance is
actually limited by JavaScript execution. Twitter.com still takes 10 seconds to
render 140 characters of text, but it's getting that text at the better part of
a gigabit per second!
There's some more complexity to this situation related to FCC certification of
devices, which has become more complex and important over time, but that's a
story for another time...
[1] Everyone grumbles about Baofeng people, but I've had some contact with
rural police and fire departments and you would be amazed at the things their
"radio technician" (chief's nephew) thinks are a good idea.