I started writing a post about media container formats, and then I got severely
sidetracked by explaining how MPEG elementary streams aren't in a container but
still have most of the features of containers and had a hard time getting back
to topic until I made the decision that I ought to start down the media rabbit
hole with something more basic. So let's talk about an ostensibly basic audio
format, PCM.
PCM stands for Pulse Code Modulation and, fundamentally, it is a basic
technique for digitization of analog data. PCM is so obvious that explaining it
is almost a bit silly, but here goes: given an analog signal, at regular
intervals the amplitude of the signal is measured and quantized to the nearest
representable number (in other words, rounded). The resulting "PCM signal" is
this sequence of numbers. If you remember your Nyquist and Shannon from college
data communications, you might realize that the most important consideration in
this process is that the sampling frequency must be twice the highest frequency
component in the signal to be digitized.
In the telephone network, for example, PCM encoding is performed at 8kHz. This
might seem surprisingly low, but speech frequencies trail off above 3kHz and so
the up-to-4kHz represented by 8kHz PCM is perfectly sufficient for intelligible
speech. It is not particularly friendly to music, though, which is part of why
hold music is the way it is. For this reason, in music and general digital
audio a sampling rate of 44.1kHz is conventional due to having been selected
for CDs. Audible frequencies are often defined as being "up to 20kHz" although
few people can actually hear anything that high (my own hearing trails off at
14kHz, attributable to a combination of age and adolescent exposure to nu
metal). This implies a sampling rate of 40kHz; the reason that CDs use 44.1kHz
is essentially that they wanted to go higher for comfort and 44.1kHz was the
highest they could easily go on the equipment they had at the time. In other
words, there's no particular reason, but it's an enduring standard.
Another important consideration in PCM encoding is the number of discrete
values that samples can possibly take. This is commonly expressed as the number
of bits available to represent each sample and called "bit depth." For example,
a bit depth of eight allows each sample to have one of 255 values that we might
label -127 through 128. The bit depth is important because it limits the
dynamic range of the signal. Dynamic range, put simply, is the greatest
possible variation in amplitude, or the greatest possible variation between
quiet and loud. Handling large dynamic ranges can be surprisingly difficult in
both analog and digital systems, since both electronics and algorithms struggle
to handle values that span multiple orders of magnitude.
In PCM encoding, bit depth has a huge impact on the resulting bitrate. 16-bit
audio, as used on CDs, is capable of a significantly higher dynamic range than
8-bit audio at the cost of doubling the bitrate. Dynamic range is important in
music, but is also surprisingly important in speech, and a bit depth of 8
is actually insufficient to reproduce speech that will be easy to understand.
And yet, due to technical constraints, 8kHz and 8-bit samples were selected for
telephone calls. So how is speech acceptably carried over 8-bit PCM?
We need to talk a bit about the topics of compression and companding. There can
be some confusion here because "compression" is commonly used in computing to
refer to methods that reduce the bitrate of data. In audio engineering, though,
compression refers to techniques that reduce the dynamic range of audio, by
making quieter sounds louder and louder sounds quieter until they tend to
converge at a fixed volume. Like some other writers, I will use "dynamic
compression" when referring to the audio technique to avoid confusion. For both
practical and aesthetic reasons (not to mention, arguably, stupid reasons),
some degree of dynamic compression is applied to most types of audio that we
listen to.
Companding, a portmanteau of compressing and expanding, is a method used to
pack a wide dynamic range signal into a channel with a smaller dynamic range.
As the name suggests, companding basically consists of compressing the signal,
transmitting it, and then expanding it. How can the signal be expanded, though,
given that dynamic range was lost when it was compressed? The trick is that
both sides of a compander are non-linear, compressing loud sounds more than
quiet sounds. This works well, because in practice many types of audio show a
non-linear distribution of amplitudes. In the case of speech, for example,
significantly more detail is found at low volume levels, and yet occasional
peaks must be preserved for good intelligibility.
In practice, companding is so commonly used with PCM that the compander is
often considered part of the PCM coding. When I have described PCM thus far, I
have been describing linear PCM or LPCM. LPCM matches each sample against a set
of evenly distributed discrete values. Many actual PCM systems use some form of
non-linear PCM in which the possible sample values are distributed
logarithmically. This makes companding part of PCM itself, as the encoder
effectively compresses and decoder effectively expands. One way to illustrate
this is to consider what would happen if you digitized audio using a non-linear
PCM encoder and then played it back using a linear PCM decoder: It would sound
compressed, with the quieter components moved into a higher-valued, or louder,
range.
Companding does result in a loss of fidelity, but it's one that is not very
noticeable for speech (or even for music in many cases) and it results in a
significant savings in bit depth. Companding is ubiquitous in speech coding.
One of the weird things you'll run into with PCM is the difference between
µ-law PCM and A-law PCM. In the world of telephony, a telephone call is usually
encoded as uncompressed 8kHz, 8-bit PCM, resulting in the 64kbps bitrate that
has become the basic unit of bandwidth in telecom systems. Given the simplicity
of uncompressed PCM, it can be surprising that many telephony systems like VoIP
software will expect you to choose from two different "versions" of PCM. The
secret of telephony PCM is that companding is viewed as part of the PCM codec,
and for largely historic reasons there are two common algorithms in use. The
actual difference is the function or curve used for companding, or in other
words, the exact nature of the non-linearity. In the US and Japan (owing to
post-WWII history Japan's phone system is very similar to that of the US), the
curve called µ-law is in common use. In Europe and most other parts of the
world, a somewhat different curve is used, called A-law. In practice the
difference between the two is not particularly significant, and it's difficult
to call one better than the other since both just make slightly different
trade offs of dynamic range for quantization error (A-law is the option with
greater dynamic range and greater possible distortion).
Companding is rarely applied in music and general multimedia applications. One
way to look at this is to understand the specializations of different audio
codecs: µ-law PCM and A-law PCM are both simple examples of what are called
speech codecs, Speex and Opus being more complex examples that use lossy
compression techniques for further bitrate reduction (or better fidelity at
64kbps). Speech codecs are specialized for the purpose of speech and so make
assumptions that are true of speech including a narrow frequency range and
certain temporal characteristics. Music fed through speech codecs tends to
become absolutely unlistenable, particularly for lossy speech codecs, which
hold music on GSM cellphones painfully illustrates.
In multimedia audio systems, we instead have to use general-purpose audio
codecs, most of which were designed around music. Companding is effectively a
speech coding technique and is left out of these audio systems. PCM is still
widely used, but in general audio PCM is assumed to imply linear PCM.
As previously mentioned, the most common convention for PCM audio is 44.1kHz at
16 bits. This was the format used by CDs, which effectively introduced digital
audio to the consumer market. In the professional market, where digital audio
has a longer history, 48kHz is also in common use... however, you might be able
to tell just by mathematical smell that conversion from 48kHz to 44.1kHz is
prone to distortion problems due to the inconveniently large common multiple of
the two sample rates. An increasingly commonly used sample rate in consumer
audio is 96kHz, and "high resolution audio" usually refers to 96kHz and 24 bit
depth.
There is some debate over whether or not 96kHz sampling is actually a good
idea. Remembering our Nyquist-Shannon, note that all of the extra fidelity we
get from the switch from 44.1kHz to 96kHz sampling is outside of the range
detectable by even the best human ears. In practice the bigger advantage of
96kHz is probably that it is an even multiple of the 48kHz often used by
professional equipment and thus eliminates effects from sample rate conversion.
On the other hand, there is some reason to believe that the practicalities of
real audio reproduction systems (namely the physical characteristics of
speakers, which are designed for reproduction of audible frequencies) causes
the high frequency components preserved by 96kHz sampling to turn into
distortion at lower, audible frequencies... with the counterintuitive result
that 96kHz sampling may actually reduce subjective audio quality, when
reproduced through real amplifiers and speakers. In any case, the change to
24-bit samples is certainly useful as it provides greater dynamic range.
Unfortunately, much like "HDR" video (which is the same concept, a greater
sample depth for greater dynamic range), most real audio is 16-bit and so
playback through a 24-bit audio chain requires scaling that doesn't typically
produce distortion but can reveal irritating bugs in software and equipment.
Fortunately the issue of subjective gamma, which makes scaling of non-HDR video
to HDR display devices surprisingly complex, is far less significant in the
case of audio.
PCM audio, at whatever bit rate and bit depth, is not so often seen in the form
of files because of its size. That said, the "WAV" file format is a simple
linear PCM encoding stored in a somewhat more complicated container. PCM is far
more often used as a transport between devices or logical components of a
system. For example, if you use a USB audio device, the computer is sending a
PCM stream to the device. Unfortunately Bluetooth does not afford sufficient
bandwidth for multimedia-quality PCM, so our now ubiquitous Bluetooth audio
devices must use some form of compression. A now less common but clearer
example of PCM transport is found in the form of S/PDIF, a common consumer
digital audio transport that can carry two 44.1 or 48kHz 16-bit PCM channels
over a coaxial or fiber-optic cable.
You might wonder how this relates to the most common consumer digital audio
transport today, HDMI. HDMI is one of a confusing flurry of new video standards
that were developed as a replacement for the analog VGA, but HDMI originated
more from the consumer A/V part of the market (the usual Japanese suspects,
mostly) and so is more associated with televisions than the (computer industry
backed) DisplayPort standard. A full treatment of HDMI's many features and
misfeatures would be a post of its own, but it's worth mentioning the forward
audio channel.
HDMI carries the forward (main, not return) audio channel by interleaving it
with the digital video signal during the "vertical blanking interval," a concept
that comes from the mechanical operation of CRT displays but has remained a
useful way to take advantage of excess bandwidth in a video channel. The term
vertical blanking is now somewhat archaic but the basic idea is that
transmitting a frame takes less time than the frame is displayed for, and so
the unoccupied time between transmitting each frame can be used to transmit
other data. The HDMI spec allows for up to 8 channels of 24-bit PCM, at up to
192kHz sampling rate---although devices are only required to support 2 channels
for stereo.
Despite the capability, 8-channel (usually actually "7.1" channel in the A/V
parlance) audio is not commonly seen on HDMI connections. Films and television
shows more often distribute multi-channel audio in the form of a compressed
format designed for use on S/PDIF, most often Dolby Digital and DTS (Xperi).
In practice the HDMI audio channel can move basically any format so long as the
devices on the ends support it. This can lead to some complexity in practice,
for example when playing a blu-ray disc with 7.1 channel DTS audio from a
general-purpose operating system that usually outputs PCM stereo. High-end HDMI
devices such as stereo receivers have to support automatic detection of a range
of audio formats, while media devices have to be able to output various formats
and often switch between them during operation.
On HDMI, the practicalities of inserting audio in the vertical blanking
interval requires that the audio data be packetized, or split up into chunks so
that it can be divided into the VBI and then reassembled into a continuous
stream on the receiving device. This concept of packetized audio and/or video
data is actually extremely common in the world of media formats, as
packetization is an easy way to achieve flexible muxing of multiple independent
streams. And that promise, that we are going to talk about packets, seems like
a good place to leave off for now. Packets are my favorite things!
Later on computer.rip: MPEG. Not much about the compression, but a lot about
the physical representations of MPEG media, such as elementary streams,
transport streams, and containers. These are increasingly important topics as
streaming media becomes a really common software application... plus it's all
pretty interesting and helps to explain the real behavior of terrible Hulu TV
apps.
A brief P.S.: If you were wondering, there is no good reason that PCM is called
PCM. The explanation seems to just be that it was developed alongside PWM and
PPM, so the name PCM provided a pleasing symmetry. It's hard to actually make
the term make a lot of sense, though, beyond that "code" was often used in the
telephone industry to refer to numeric digital channels.
I have sometimes struggled to justify my love for barren deserts. Why is it
that my favorite travel destinations consist of hundreds of miles of sandy
expanse? Today, I'm going to show you one reason: rural deserts have a habit of
accumulating history. What happens in the desert stays there---in corporeal
form. Slow growth of vegetation, little erosion, and extraordinarily low
property values turn vast, empty deserts into time capsules... if you spend
enough time looking for the artifacts.
Also, we're going to talk about telephones! But first...
While the Mojave Desert was long open to homesteading claims, the extremely
arid climate along with the distance to urban centers has always made the area
challenging to put to use, and so has kept its population low. Places like
Death Valley and Joshua Tree National Park are the best known Mojave
destinations for their distinct geography and flora, but a different swath of
the Mojave Desert began to attract a less formal sort of attention long ago.
The development of the US Highway System, specifically highways 91 and 66,
created a pocket of desert that was remote and yet still readily accessible
from both Los Angeles and Las Vegas. Post-WWII, power sports (specifically dirt
biking) lead to significant use of and impact on open land along highways.
Combined, these created a bit of a contradiction: the empty desert was getting
a little too crowded.
Through a series of political and administrative moves, the area of the Mojave
desert roughly defined by US-91 to the north (now I-15) and US-66 to the south
(now I-40 although the alignments vary) became first the East Mojave National
Scenic Area of the Bureau of Land Management (the first such National Scenic
Area established) and then, in 1994, the Mojave National Preserve of the
National Park Service [1]. It is the third largest unit in the national park
system, and due to its vast size, history, character, and perhaps most of all,
miniscule budget, it remains surprisingly undeveloped and untamed.
Roughly in the center of the Preserve is a tiny town called Kelso. Kelso was
established by the Los Angeles and Salt Lake Railroad (later part of Union
Pacific) as a railroad depot and base for "helper" locomotives added to trains
to help them make it up a steep grade eastwards towards the next tiny
settlement, Cima. During its distinguished life as a railroad town, from the
1910s to the 1980s, it also supported a few surrounding mines. Elsewhere in
what is now the National Preserve, many small mines, a few large ones, and a
few major ranches made up the entire tiny population of the region. The nearest
present-day town, Baker, has become little more than a row of gas stations and
a surprisingly compelling Greek diner. In an earlier era, the multi-hour trip
to Baker on horseback was the only connection to the outside world available to
miners and ranchers out in the desert. Back then it was like a different world,
and today it largely still is.
Situated roughly halfway between LA and Vegas, in San Bernardino County,
California, the Mojave National Preserve's more than one and a half million
acres display two wars worth of military collaboration by the Bell System, two
generations of long-distance telephone infrastructure, and four distinct types
of long-distance telephone lines. There is perhaps nowhere else that one can
gain as powerful of an appreciation for the feat that is the long-distance
telephone call. A call to Los Angeles requires of you only dialing and waiting.
First, though, it required teams of workers digging thousands of huge post
holes by hand. The Mojave has been described as "a nowhere between two
somewheres" [1]. This is true not only on the ground but also in the wires, as
a large portion of telephone calls in and out of one of America's largest
cities had to pass through one hundred miles of blowing sand. They still do
today.
It's hard to say when, but we can safely how the first telephones arrived in
the Mojave: by rail. The railroads made extensive use of telegraphy and, later,
telephony. By the 1920s the railroad depot at Kelso, and later some of the
homes of railroad employees, were equipped with telephones on the Los Angeles
and Salt Lake Railroad's (LA&SR) private system [2]. While railroad telephones
operated on separate, wholly railroad-owned infrastructure that was not
interconnected with the Bell system, railroad telephone departments enjoyed a
close relationship with the Bell System and largely used the same techniques
with equipment from the same manufacturers.
The LA&SR would have installed a series of multi-armed utility poles, likely
as part of the original construction of the railroad. While these poles would
have initially carried only telegraph circuits, they later gained telephone
circuits, signal logic circuits, and even "code" circuits which used an early
form of digital signaling to communicate with trackside equipment. Many of
these circuits would have looked substantially similar to open-wire telephone
leads, because they were: railroads employed the same open-wire design that
AT&T used.
Railroad telephones went through generally the same technological progression
as public telephones. The first equipment installed would have been magneto
phones. To make a call, you would turn a crank on the phone which generated a
high voltage "ringing" signal. Once an operator noticed and connected to the
line, you asked the operator to connect your call. Individual phones were
expensive to install. As a result, the Kelso depot started with only a single
phone in the dispatcher's office, along with the telegraph. At some point, this
telephone was placed in a specially built rotating cabinet that allowed the
station agent in the dispatch office to spin it around, presenting it through
the other side of the wall for someone in the lobby to take a call [2]. The
clever pass-through phone was probably designed by a local worker as a
practical solution to the problem that dispatchers often called the phone
wanting to speak to visiting train crews, but railroad security policy forbade
anyone other than a qualified agent in the dispatch office. The station agent
must have quickly tired of relaying conversations sentence-by-sentence through
the window.
Later, as the technology progressed and more resources became available, the
railroad connected additional phones to other buildings. These extra extensions
most commonly appeared in the homes of senior staff such as the station agent
and track gang foreman; they would be the only way to reach someone at the
depot (or, for that matter, in the entire town of Kelso) during an after-hours
emergency. In this era an "extension" was a literal extension of the existing
wiring; all of these phones would have rung together. Kelso Depot also featured
another clever solution to the difficulties of reaching a remote employee
before the widespread availability of radio: after the installation of
electrical (CTC) signaling on the rail line, the dispatch office's semaphore
display that once electromagnetically dropped flags to alert the agent that a
train had passed a signal point approaching the station was rewired to drop a
flag whenever the depot phone rang. This way, if the agent missed a call while
attending to something outside of the office, they would at least know to call
dispatch back when they returned [2].
Elsewhere, in 1915, the first transcontinental telephone line went into
service. This line, generally from New York to San Francisco, passed through
Northern California far from our area of interest. It ignited a fire that
quickly spread, though, and the 1920s saw extensive construction of new long
distance telephone lines in the West. In parts of Southern California, Pacific
Telephone and Telegraph (PT&T) competed with the Home Telephone Company, until
it acquired it. Much of PT&T's advantage over Home was its status as a member
of the Bell System: Home had no long distance service. PT&T did.
The history of this early era is difficult to construct, as very few records
remain and most of the artifacts have been removed. Around the Mojave National
Preserve, though, two PT&T long-distance open-wire toll leads survive. One
roughly paralleled US-91 (now I-15) from the area of Los Angeles (probably San
Bernardino) towards, ultimately, Salt Lake City. This was one of the most
important connections between the West Coast and the rest of the country.
Another, further south, roughly paralleled US-66 (now I-40). This was the
fourth transcontinental line, constructed around 1938. Its Western terminus was
likely Whitewater, which was less a town and more a particularly important
telephone office in the early AT&T system. Whitewater is notable for existing
in the territory of General Telephone & Electronics or GTE, a particularly
long-lived non-Bell competitive telephone carrier. When GTE was later acquired
by a Bell operating company, the two adopted the name Verizon. Back in the
pre-WWII era, GTE's dominance in far southern California meant that AT&T had
few actual customers but a great need to move long-distance traffic.
Whitewater was thus a bit of an oddity: a major telephone office, in the middle
of nowhere, with no customers but a surplus of traffic. At the other end, this
southern open wire lead probably connected into Bullhead City or Laughlin, in
the area of Needles.
Sections of both open wire routes remain and can be seen today. The northern
one includes a particularly spectacular crossing of the freeway, employing a
seldom seen today technique in which two steel "messenger" ropes suspended
between stout poles hold up a series of wooden frames that substitute for poles
and crossarms. These "floating poles" supported the actual telephone wires for
the long canyon crossing. Today, a single multi-pair cable hangs sadly from the
five-arm frames, apparently placed to provide telephone service to a nearby
mine after the removal of the open-wire route. On the southern route, remaining
poles are clearly visible from US-66 during its departure from the present-day
I-40 alignment near Cadiz (itself an oddity, a town owned by a natural
resources company with long-failed plans to pump and sell the groundwater to
LA).
At the dawn of WWII, these two leads represented some of the only long toll
leads on the West Coast. Following the attack on Pearl Harbor, Japanese
invasion, or at least opportunistic sabotage, was a major concern for military
planners. Concerningly, the handful of telephone connections between major
western cities had poor redundancy and were mostly near the coast. They would
be easy for a small team of Japanese soldiers, delivered by boat under cover of
night, to find and destroy. This easy move would effectively decapitate
military leadership on the West Coast, impairing the ability of the United
States to mount a defense. Here, years before the nuclear bomb or mutually
assured destruction, survivable C2 and the telecom infrastructure to support it
became a national priority [3].
In early 1942, and in collaboration with the War Department, PT&T embarked on a
project that would rival the first transcontinental: a new wartime long
distance route called the Defense Backbone Route, or DBR. Over a span of under
a year, with a monumental level of effort ranging from logistical innovations
to the sheer manpower of hundreds of laborers working from roving camps, the
DBR's open-wire spanned nearly 900 miles from the Mojave desert to Yakima. Most
importantly, its entire route was well inland (including a large stretch in
Nevada), making it difficult for any military force arriving via the coast to
reach. The DBR presaged later developments like the L-3I by providing a
survivable toll lead dedicated to military use, particularly for the purposes
of defense and reprisal.
The southern terminus of the DBR is sometimes described as Los Angeles, but
that seems to have been only by interconnection to the existing open-wire lead
along US-66, south of the Preserve. The DBR itself ends at a location
optimistically described as Danby, California, although Danby is not much of a
town and the end of the DBR is not that near it. The "Danby" station,
consisting of one small building which presumably originally contained carrier
multiplexing equipment, is still there today, and seems to still be in use with
an added microwave antenna. As we will see, telephone infrastructure in rural
areas is often reused for cost efficiency. It appears that there are still
active customers served by a modern multipair telephone cable installed using
the open-wire route's right of way, and the Danby station remains with a
microwave link to provide local loop connections to these customers.
From Danby, the DBR continued northwest and then north, almost right through
the middle of the present-day Preserve. It wanders through valleys, passing
within a few miles of Kelso, before reaching the northern open-wire lead at
US-91, which it joins to head towards Las Vegas. The poles and wire of the DBR
remain largely intact within the Preserve and can be seen from Kelbaker Road
(shortened from Kelso Baker Road), in Kelso and on Kelso Cima Road, and later
where it crosses the Mojave Road and numerous dirt mine and ranch roads. It can
even be seen from I-15 if you look carefully, although the span near I-40 has
been removed.
Not so long after the DBR was constructed, and shortly after it was converted
to civilian use, the owners of the Cima mine (a small cinder mine in what is
now the eastern portion of the Preserve) contacted PT&T or AT&T to request a
telephone. Under a California law, PT&T was required to furnish telephones for
use in very rural areas where no other phones existed. At the time, it was a
multi-hour trip from the Cima mine to reach Kelso or Baker where, in an
emergency, help could be summoned. To improve safety, but moreover to comply
with California law, AT&T came to the desert with a "toll station." Toll
stations, an artifact of the early phone system no longer seen today, can be
thought of as telephones that are a long distance call from anywhere. Toll
stations were used to connect very rural areas, and were often located on party
lines and required operator assistance to call. The reason for these oddities
is simple: toll stations were connected directly to long-distance wires, not
via local exchanges, and so they represented an odd exception in the general
architecture of the telephone system. On the upside, they were far easier to
install in very rural areas than conventional local telephone service.
In 1948, the Cima mine's requested phone was unceremoniously placed dead center
in the middle of the desert. Located at the intersection of the DBR and a dirt
access road, the new phone was still some way from the Cima mine but much
closer than any town. It was a magneto phone connected directly to the DBR
(likely using the "voice frequency" or non-carrier "channel" of one of the sets
of pairs). Lifting the handset and turning the crank prompted a long-distance
operator in San Bernardino to pick up and ask where the user wanted to call.
If one wanted to call the phone, they would have to ask their operator to be
connected to the San Bernardino long distance operator, and then ask for the
phone by name. The long distance operator would ring the phone, and someone
would have to be waiting nearby. It is said that some local user left a chair
by the phone, as a convenience to those waiting for incoming calls. Telephone
users would sometimes adopt a regular schedule of visiting the phone during set
hours in case someone wanted to reach them. Locals driving by the phone on the
dirt road would roll down their window, just in case it rang, so that they
could take a message that would almost certainly be for someone they knew.
While far from convenient, it was the only phone service for both mines and
ranchers in the area [2,4].
This lonely phone would prove to have remarkable staying power. The owners of
the Cima mine seem to have continued to use it as their main telephone into the
'90s. Over time the phone was modernized to a more conventional payphone and
given a more conventional switching arrangement and phone number. In 1997,
after a series of chance discoveries, it came to be widely known in
counter-cultural circles as the Mojave Phone Booth. It was difficult to
comprehend: an aluminum and glass telephone booth, in a way a symbol of
modernity and urbanism, sitting in a lonely desert impossibly far from the
civilization it connected to [2,4].
The phone booth's sudden fame, and significant increase in users, lead directly
to its demise. Some combination of Park Service concern about environmental
impact by visitors to the phone booth and upset by a local rancher who didn't
appreciate the raucous visitors lead to its removal in 2000. Today nothing
remains of the Mojave Phone Booth except for the DBR itself. Its segment in the
northern Preserve, apparently maintained to keep the single connection to the
phone booth, is still in good shape today (albeit with only one crossarm
remaining) [2]. Unfortunately, while the Mojave Phone Booth is widely described
in media ranging from Geocities-esque phone phreaking websites to an episode of
99% Invisible, few people know that the cross-desert phone line its wires
once hung off of was itself an oddity, an artifact of WWII which had been
hidden from the Japanese in the desert. The Mojave Phone Booth was a
contradiction in an even deeper way than it might first seem: a phone placed
for convenient access along a phone line placed specifically to avoid
convenient access. That is how you get a phone booth in the middle of nowhere.
Elsewhere along the DBR, World War II had ended but the Cold war was just
beginning. Early in the Cold War the greatest fear was the delivery of nuclear
weapons by bombers. Air defense, before mature radar technology, was a
difficult problem. In the style successfully employed by the UK during the
battle for Britain, the Air Force established a Ground Observer Corps (actually
the second, after one which operated during WWII). The Corps consisted of
volunteers who, when activated, would search the sky by eye and ear for enemy
aircraft and report them to a "filter center" where such reports were
correlated and forwarded to the Air Defense Command.
Being the only thing for a very long ways, the Kelso railroad depot was an
obvious choice for a Corps observation post. While not recorded, the volunteers
were probably railroad employees who lived in railroad-provided housing in
Kelso. There was one problem: the observers would need a telephone to report
their sightings to the filter center, and the filter center was not on the
railroad telephone network. As a result, the first public network telephone was
installed in the lobby of the Kelso railroad depot in 1956 [1,2]. It is unclear
today how exactly this phone was connected. I find it likely, although I cannot
prove, that it was connected via railroad open-wire leased by AT&T and tied
into an AT&T exchange in a larger town. It is also possible that it was a toll
station attached to the DBR much like the Mojave Phone Booth, although
inspection of the cabling which now exists from the DBR to Kelso suggests that
it is a much newer connection than 1956.
In 1974, the Kelso depot phone was apparently still in service although it was
likely connected differently (as we will later discuss). A railroad employee,
responsible for the operation of the Depot, requested that PT&T move the phone
outside under a covered walkway so that it would be accessible 24/7 after they
introduced the practice of locking the depot doors at night (this on the advice
of a UP police Special Agent who feared a midnight robbery of the depot's small
restaurant, formerly 24/7 but by then closed nightly). There was, reportedly,
also a phone at Kelso's small general store, across the street from the depot,
which likely shared the line [2].
The DBR thus served two local telephones within the Preserve in addition to
long-distance traffic. There is some reason to believe that the payphone, at
least, was on a party-line circuit shared with phones installed in the homes of
some local residents (probably ranch houses relatively near the DBR). The Kelso
phone may have been as well, or may have been party-lined with other phones in
railroad facilities if it was indeed on leased railroad open-wire. The general
pattern of an open-wire toll lead with a single party line used to connect a
few toll stations for local users was common in very rural areas at the time.
Not just ranch houses and mines but also rural gas stations and businesses
relied on this type of service, as toll leads often followed the same highways
that rural businesses clustered near.
The Cold War would have a much bigger impact on the Mojave than a phone in the
Kelso depot, although the introduction of telephone service to such remote
sites as the Mojave Phone Booth and even the Kelso Depot (which did not even
have an electrical connection, relying instead on a small on-site power plant
operated by the railroad until 1960) was no small feat. The need for
long-distance capacity between Los Angeles and the east had grown
exponentially. More troubling, the genesis of nuclear weapons and the doctrine
of mutually assured destruction created an exponentially greater need for fast,
reliable, and survivable telecommunications. The "Flash Override" button on the
President's telephone, intended foremost for use when ordering a nuclear
strike, would be useless without a telephone network that could connect the
President to their military branches... even after nuclear attack, and even
through the remote Mojave.
Southern California, outside of its major cities, was rich with military
installations (a result in part of the extensive use of the Mojave for WWII
training) but poor in infrastructure. This created a particular challenge: in
Southern California AT&T suddenly had a bevy of customers for AUTOVON (the
Automatic Voice Network, a survivable military telephone system operated by
AT&T on contract to the War Department), but very few customers for civilian
service and thus very little capability to connect new phones. The Mojave
needed strong telephone infrastructure, and it needed it very fast.
I feel fairly confident in stating that the greatest single achievement in the
construction of AUTOVON, if not of the entire history of survivable military
communications, was the L-3I transcontinental telephone line. This coaxial
cable, analog, high capacity toll lead, installed mostly in 1964, could carry
thousands of calls from coast to coast. Moreover, it was completely underground
and hardened against nearby nuclear detonations. Manned L-3I support
facilities, which were found every 100 miles, were underground bunkers staffed
24/7 and equipped with supplies for staff to survive two weeks in isolation.
Because it was impractical to harden such facilities against direct nuclear
attack, their survivability relied in part on remoteness. The L-3I was
intentionally routed through rural areas, well clear of likely targets for
nuclear attack. At the same time, it needed reliable connectivity to military
installations that were almost certainly targets. This required a hybrid
approach of both the hardened L-3I and multiple, redundant connections of
other types.
The L-3I transcon adopted a southern route in the western United States and
dipped into the western edge of Texas before crossing through the Southwest:
New Mexico, Arizona, and then Southern California. There was an underground
L-3I "main station" at Kingman, Arizona, after which the cable crossed under
the Colorado River at Riviera and proceeded almost directly west into the
Preserve. The L-3I cable passed about eight miles north of Kelso, roughly
parallel to and not far south of the Mojave Road. After a northern jog it
turned back west south of Baker until it met US-91, now I-15, and followed the
highway to Beacon Station (which appears to be a former CAA intermediary
airfield) where the next L-3I main station is found just north of the freeway.
L-3I cables were buried underground (actually pushed directly into the ground
by means of a special plow), but their presence was clearly indicated on the
surface by repeater stations and right of way (ROW) markers. Repeater stations
were installed in buried concrete vaults every four miles, but a metal hut was
installed on top of each vault to house test equipment and provide technicians
a clean and dry workspace. ROW markers consisted of frequently placed tall
wooden posts with orange metal bands wrapped around the tops, intended both to
help repair crews locate the cable in the ground and to warn farmers and
construction workers to dig with care.
In the Mojave, though, none of this can be seen today. The L-3I cable saw use
through the Cold War, carrying both military and civilian traffic. In the '80s,
it was upgraded to carry a digital protocol called P140. The 140Mbps capacity
of P140 was limited, though, and the L-3I cable required significantly more
maintenance and support than the fiber optic technology increasingly used by
1990. In 1997, AT&T disclosed its intentions to fully abandon the L-3I cable
west of Socorro (although portions of the ROW would be reused for fiber). In
response, the NPS and BLM performed an environmental analysis on abandonment of
the cable in federal land. The analysis revealed several potential long-term
environmental impacts from not only the cable and repeaters but also the ROW
markers themselves. The marker posts provided an ideal perch for birds of prey,
in a desert environment that offered very few other tall objects. The effect
was increased predation of small animals, a particular problem for several
endangered species in the region.
To mitigate the problem, the NPS required an effort that was rather unusual for
L-carrier routes: complete removal. Repeater huts, vaults, ROW marker posts,
and the cable itself were all demolished and hauled away throughout most of
Arizona and California. Today, all that remains of the L-3I in the Preserve
is the still visible scar of the trenching and excavation, marked on many maps
as "Utility Road."
The western destination of the L-3I cable was the L-3I Main Station at Mojave,
around one hundred miles west of the Preserve, which despite the retirement of
the L-3I has grown into a large complex that remains an important long-distance
switching center today. The AUTOVON switch at Mojave connected via microwave
and buried cable to a long list of cities and military installations in
Southern California.
Microwave radio systems can move large numbers of telephone calls over
point-to-point radio links. Because they avoid the need to run cable through
many miles of land, microwave can be a much more affordable option for
long-distance telephone infrastructure. As a downside, the microwave technology
of the time (called TD-2) could carry fewer calls and required a line-of-sight
of generally under 50 miles between stations. To extend this range, simple
stations called relays received a signal on one side and transmitted it again
out the other. The microwave antennas used at the time were large, heavy, and
required fairly regular maintenance, all of which made very tall towers
impractical. Instead, to find a line of sight, microwave facilities were built
on peaks and in high mountain passes.
Much of the microwave telephone infrastructure in the area of the Preserve was
built at the same time as the L-3I cable, as both were part of the same larger
AUTOVON project. The L-3I was a high-capacity, high-durability, but high-cost
backbone, while microwave links were a more affordable technology that used
redundancy rather than physical strength to ensure reliability. The lower cost
and greater flexibility of microwave also made it ideal for shorter connections
between the telephone network and defense facilities, encouraging more local
microwave stations. This is why the mid-1960s AUTOVON effort lead to the
creation of not one, but three independent east-west long-distance routes
through the area of the Preserve: the L-3I cable, a northern microwave route,
and a southern microwave route.
Although they were relatively inexpensive, microwave stations were not left
undefended. AUTOVON microwave facilities were above ground but used hardened
building techniques including thick concrete walls, blast shielded vents, and
reinforced towers and antennas to survive nuclear strikes at a moderate
distance. Most microwave stations were simple relays that operated unattended
except for periodic visits by maintenance technicians, but larger stations with
switching equipment were staffed 24/7 and supplied for two weeks of isolation,
much like L-3I main stations.
The center of the microwave network in the Mojave, if not all of Southern
California, was a remote mountaintop site called Turquoise. Located just north
of the preserve, about five miles north of I-15 at Halloran Springs, Turquoise
was a staffed facility with an AUTOVON switch. Its squat square tower bristled
with horn antennas. Every day several shifts of exchange technicians made their
way up Halloran Springs Road to the site and supervised the switching of
military and civilian calls to destinations throughout southern California, as
well as onto the L-3I and other cables for cross-country transit. Turquoise had
direct or indirect connections to four different major long-distance microwave
routes. As a secondary function, Turquoise included Ground Entry Point antennas
for a system called ECHO FOX that provided radiotelephone service to Air Force
One... directly to AUTOVON, for use in a nuclear emergency if necessary [6].
One pair of antennas on Turquoise's crowded tower pointed south towards a
station called Kelso Peak. Kelso Peak, located in the Preserve a little under
ten miles northwest of Kelso, served as a relay station on both a north-south
route (north to Turquoise) and an east-west route (west to Hector, a relay
not very close to anything but perhaps closest to Ludlow).
To the east, Kelso Peak connected to Cima, another AT&T relay in the Preserve.
Cima station sits on a hill five miles due East of the town of Cima, and relays
traffic northeast to a station in Nevada, almost to Las Vegas, charmingly
called Beer Bottle.
To the south, Kelso Peak connects to the Granite Pass station. Granite Pass is
directly next to Kelbaker Road 14 miles south of Kelso. Across Kelbaker Road
from the Granite Pass microwave station is a much smaller tower installed by
the National Park Service to relay internet and phone service to Kelso today.
South from Granite Pass, the next station is Sheep Hole, south of the preserve
and northeast of Twentynine Palms.
Putting these stations together, the northern east-west telephone route through
the Mojave runs north of the preserve mostly parallel to I-15. The southern one
(actually perhaps better called the "middle" route as there is yet another
further south and nearer to Joshua Tree National Park) runs through the center
of the Preserve, and would be visible on the horizon just north of Kelso if you
could see microwaves. The north-south route runs directly through the western
side of the Preserve.
Construction of these stations in 1964 was a formidable project. Crews from
Southern California Edison installed many miles of new power lines, starting
from Kelso and running outwards, to bring power to the Granite Pass and Kelso
Peak stations (Kelso itself had only been connected to the grid a few years
earlier). The microwave stations, like the L-3I cable, were built by PT&T
crews for AT&T Long Lines. Crews from both SoCal Edison and PT&T occupied
employee hotel rooms at the Kelso Depot while performing work, often for
months long stays that irritated the station agent and stretched the depot's
capacity to house and feed [2].
Each of the AT&T stations in the Preserve, like others in the Mojave, included
an unusually large gravel apron around the facility. This leveled gravel lot
served as a helipad; due to the remoteness of the facilities maintenance
technicians were delivered by helicopter. The sandstorms which sometimes occur
in the Preserve posed a maintenance and reliability challenge, and maintenance
crews were kept busy.
Along with the L-3I and TD-2 came the end of open-wire, but in such a remote
area it's hard to really tear out old infrastructure. Instead, when the
decision was made to decommission much of the open wire by 1989, alternative
arrangements were made for the few local customers once served by the DBR.
South of Granite Pass and north of Kelso portions of the DBR were removed, but
the Granite Pass microwave station was connected to the DBR open-wire as it
passed by. East of Kelso where the DBR crossed the railroad, a section of new
wire was used to connect pairs on the DBR to pairs on the railroad open-wire,
which was removed except between the DBR and Kelso. The result was a direct
local loop from the Kelso phones to the Granite Pass microwave station, a very
unconventional setup to avoid the need for a new phone line to Kelso. A 1924
rail depot connected to a 1964 microwave station by reuse of a 1942 open-wire
toll lead: the kind of thing you run into in the desert.
The phone booth seems to have found an alternate arrangement. The DBR was
removed for a span north of Kelso, disconnecting the phone booth from the span
to Granite Pass. Instead, the phone booth seems to have been reconnected along
old DBR wire pairs to somewhere further north, likely Baker, where the phone
booth had been assigned a regular local number.
Because of these two legacy arrangements, large spans of the DBR have remained
intact in the Preserve to this day. On Kelso Cima Road just east of Kelso, the
intersection of the DBR and the railroad can be seen, including the somewhat
awkward interconnection of the DBR to the railroad open wire. Just north of
this point the DBR abruptly ends, the remaining wires tied around the base of
the last pole. The DBR is only absent for about two miles though, follow its
route north and the poles will start again just as abruptly as they ended. 16
miles further, the ghost of the phone booth sits under the poles of the former
DBR. Look carefully and you can see many details of this old infrastructure.
I have posted a few photos I took at https://pixelfed.social/jbcrawford,
although I intend to get better and more thorough ones on a future trip.
Today, the original TD-2 microwave equipment is long removed, and some of the
large KS-15676 horn antennas have been removed as well (although they remain at
some sites including the highly visible Granite pass). Even so, radio sites,
once built, have a tendency to live on. Most of these microwave sites are still
in use, either by a telco or under ownership of a leasing company such as
American Tower. The remoteness of the Mojave means that radio remains an
important technology and many of these microwave sites still carry telephone
calls, using more modern equipment, and either as the primary route to some
rural telephone exchanges or as a backup in case of damage to buried fiber
optic lines. The late life of these facilities can sometimes be confusing. At
Granite Pass, a much newer tower and small utility enclosure on the west side
of Kelbaker road, next to the small NPS relay, are used by AT&T for telephone
service. The original AT&T tower on the east side of the road is no longer used
by AT&T but lives again as a relay site for the Verizon Wireless microwave
backhaul network, which provides cell towers their connection to the rest of
the phone system. Many microwave sites have also been reused as cellular
towers.
Various newer telecommunications infrastructure can be found within the
Preserve as well. At the town of Cima, a large radio tower erected by Union
Pacific provides radio communications with trains and trackside equipment.
Smaller towers found up and down the railroad link trackside equipment together
as a replacement for the old open-wire lines. Just south of I-40 near the Essex
exit, a modern small microwave relay site provides backhaul communications for
several cellular carriers on solar power alone. At Goffs Butte, a conspicuous
cinder cone south of Goffs, a busy radio site includes cellular and telephone
microwave relays alongside broadcast radio stations. Cellular towers at Baker,
Mountain Pass, Goffs, Ludlow, and others now provide coverage to some, but
far from all, of the Preserve.
There is a very real sense, though, in which modern telecommunications
technology has still failed to tame the desert. Satellite networks such as
Globalstar and Iridium can be reached throughout the Preserve, but slowly and
at significant cost. Cellphones are unreliable to unusable in many parts of the
Preserve, and there are few landline phones to be found. Despite all of this
infrastructure, the Mojave is still far from civilization. That's another great
thing about the open desert, besides the memories it keeps: it's hard to get
to, and even harder for anyone to bother you once you're there.
[1] "From Neglected Space to Protected Place: An Administrative History of the
Mojave National Preserve," Eric Charles Nystrom for the National Park Service,
2003.
[2] "An Oasis for Railroaders in the Mojave: The History and Architecture of
the Los Angeles and Salt Lake Railroad Depot, Restaurant, and Employees Hotel
at Kelso, California, on the Union Pacific System," Gordon Chappel et al. for
the National Park Service, 1998.
[3] "DBR: 'Damned Big Rush' or the Building of the Defense Backbone Route,"
The Electric Orphanage. https://the-electric-orphanage.com/the-damned-big-rush-or-building-of-the-defense-backbone-route/
[4] Correspondence, Telephone Collectors International mailing list.
[5] "Draft Environmental Impact Statement: Mojave National Preserve, P140
Coaxial Cable Removal Project," National Park Service, 1997.
[6] "Turquoise, California AT&T Long Lines Site," Path Preservation.
http://www.drgibson.com/towers/turquoise.html
I think I've mentioned occasionally that various devices, mostly cellular
modems, just use the Hayes or AT command set. Recently I obtained a GPS
tracking device (made by Queclink) that is, interestingly, fully configured via
the Hayes command set. It's an example of a somewhat newer trend of converging
the functionality of IoT devices into the modem baseband. But what is this
Hayes command set anyway?
Some of you are no doubt familiar with the "acoustic coupler," a device that
has two rubber cups intended to neatly mate with the speaker and microphone of
a telephone handset. The acoustic coupler allowed a computer modem to be
connected to the telephone system via audio instead of electrically, which was
particularly important because, pre-Carterfone, nothing could be connected to
the telephone system that was not leased from the telco. Acoustic couplers
were also just convenient, as back in the days when all equipment was leased
from the telco phones were fairly expensive, most houses did not yet have a
panoply of telephone jacks, and so it was just generally handy to be able to
easily use a normal phone with computer modem without having to swap around
cabling.
Unfortunately, this scheme had a major limitation: the computer interacted with
the telephone just like you would, via audio. The computer had no way, though,
of taking the phone on or off hook or dialing. That was all up to the user. So,
you'd pick up the phone, dial a number, and then set the phone down on the
acoustic coupler. When you were done, you would take the phone off of the
coupler and hang it back up. Besides being a bit of a hassle and sometimes
prone to mistakes, this effectively ruled out any kind of automatic or
scheduled modem usage.
Through the '70s, modems capable of automatic dialing and on/off hook were
available but were expensive, large machines intended for commercial-scale
use. For example, they were somewhat widely used by retail point of sale
systems of the era to send regular reports back to corporate headquarters
for accounting. For the home computer enthusiast, there were essentially
no options, and among other implications this ruled out the BBS ecosystem
that would emerge later since there was no way for a computer to
automatically pick up the line.
Everything changed in 1981. Actually, the first fully computer-controlled modem
came somewhat earlier, but because it was designed specifically for S-100
computers (like the Altair) and later Apple II, its popularity was limited to
those platforms. Hayes, the same company that developed this early internal
modem, released the Hayes Smartmodem in '81---which truly started the PC modem
revolution. The basic change from their earlier internal modems was that the
Smartmodem interfaced with the host computer via serial. RS-232-esque-ish
serial ports were by this time ubiquitous on microcomputers, so the
Smartmodem could be used with a huge variety of hardware.
It might be surprising that a modem that allowed programmatic control of
the hook and dialing took so long to come around. It might be more obvious
why if we think about the details of the modem interface to the host PC.
The task of a modem is, of course, to send and receive data. In order to
do so, modems have traditionally acted like transparent serial channels.
In other words, modems have behaved as if they were simply very long
serial cables between two computers. Whatever data was sent to the modem
it transmitted, and whatever data it received it returned on the serial
interface.
We could thus refer to the serial connection to the modem as being the data
plane. How is the modem commanded, then? Well, originally, it wasn't... the
user had to handle all aspects of call control manually. To bring about
automatic call control, Hayes had to come up with a command set for the modem
and a way to send those commands. Hayes solution is one that vi users will
appreciate: they created two modes. A Hayes Smartmodem, in data mode, acted
like a normal modem by simply sending and receiving data. A special escape
sequence, though, which defaulted to "+++", caused the modem to change to
command mode. Once in command mode, the computer could send various
commands to the modem and the modem could reply with status information.
The modem would switch back to data mode either after an explicit mode
switch command or implicitly after certain connection setup commands.
All commands to a Hayes modem began with the letters "AT". There are a few
reasons for this. Perhaps most obviously (certainly to any vim users), the use
of two distinct modes creates a huge opportunity for "mode errors" in which the
modem is somehow not in the mode that the software controlling it thinks it is.
Prefixing all command strings with "AT" serves as an additional check that a
line of text is intended to be a command is not actually data errantly sent
during command mode, which might cause the modem to take all kinds of strange
actions. Second, AT was used for automatic baud detection and clock recovery in
the modem, since it was a known bit sequence that would be sent to the modem
after the modem first powered on and before it was used to make a call.
It's because of this "AT" prefix, which in principle stands for "attention,"
that the Hayes command set is commonly referred to as the AT commands. If
either Hayes or AT rings a bell, it will be because the influence of the Hayes
Smartmodem on the computer industry has been incredibly long lasting:
essentially all telephone network modems, whether landline or cellular,
continue to use the exact same Hayes interface. In most cases, the operating
system on your smartphone is, as we speak, using the Hayes command set to
interact with the cellular baseband. If you buy an LTE module for something
like an IoT application, you will need to send it Hayes commands for setup
(under Linux the ModemManager daemon is responsible for this background work).
If you use a USRobotics parallel telephone modem, well, you will once again be
using the Hayes command set, but then that's less surprising.
Let's take a quick look at the Hayes commands. The format of them is somewhat
unconventional and painful by modern standards, but keep in mind that it was
intended for easy implementation in '80s hardware, serial interfaces were slow
back then, and in general it is designed more for economy than
user-friendliness. On top of that, it's been hugely extended over the years
since, meaning that the awkward "extension" commands are now very common.
A Hayes command string starts with "AT" and ends with a carriage return (line
feed may or may not be used depending on configuration). In between, a command
string can contain an arbitrary number of commands concatenated
together---there is no whitespace or other separation, rather the command
format ensures that it is possible to determine where a command ends. You can
imagine this has become a bit awkward with extension commands and so, in
practice, it's common to only put one command per line except for rather
routing multi-step actions.
The basic commands consist of a single capital letter which is optionally
followed by a single digit. Most of the time, the letter indicates an action
while the digit indicates some kind of parameter, but there are exceptions.
Some commands take an arbitrary-length parameter following the command, and
some commands accept a letter instead of the one trailing digit. Actually
even the original Hayes command set is so inconsistent that it's hard to
succinctly describe the actual syntax, and now it's been added on to so many
times that exceptions outweigh the rules. It might be easier to just look at
a few examples.
To do perhaps the most obvious thing, instruct the modem to go off hook and
dial a telephone number, you send "ATDT" (D=Dial, T=Touch-Tone) followed by a
string which specifies the phone number... and can also contain dialing
instructions such as pausing and waiting for ringback. For example when dialing
into a PABX that uses extensions, you might use "ATDT5055551234@206;". This
tells the modem to dial (D), touch-tone (T), 505-555-1234, wait until ringback
(@), dial 206, then stay in command mode (;). Without the semicolon, the D
command usually causes an implicit switch to data mode.
Answering a call is simpler, since there are fewer parameters. The "A" command
is answer. The command string would sort of technically be "ATA0" since A
ostensibly conforms to the "one letter one digit" convention, but when the
digit is 0 it can be omitted.
But wait... how would the computer know that the modem is "ringing" in order
to answer? Well, for that you'll have to jump back to the post on RS-232,
and study up on why the Hayes Smartmodem used a 25-pin connector. There's
just a dedicated wire to indicate ringing, as well as a dedicated wire to
indicate when the modem is ready to move data (i.e. when a data carrier
is present). The serial interface in the computer was expected to expose
the state of these pins to software as needed.
Some of you may remember that, in the days of dial-up, it was common to hear
the modem dial and negotiate the data connection aloud. This too dates back to
the Hayes Smartmodem, and it's somewhat related to the reason that fax machines
usually provide a handset. If you misdial or there is a problem with the
destination phone number or one of a number of other things, you may get an
intercept message or someone answering or some other non-modem audio upon the
call connecting. The Smartmodem featured a speaker to allow the user to hear
any such problems, but of course few users wanted to listen to the whole data
session. The Hayes "M" command allowed the host computer to set the behavior of
the speaker, and "ATM1" was commonly sent which caused the modem to enable the
built-in speaker until a data carrier was established, at which point it was
muted.
The Hayes Smartmodem also included a number of registers in which configuration
could be stored in order to affect the behavior of later commands. For example,
the duration of a standard dialing pause could be adjusted by changing the value
in the register. The "S" command allowed for selecting a register (e.g. ATS8 to
select register 4), and the "?" and "=" commands could be used to query and set
the value of a register. "=" of course took an argument, and so "ATS8=8" could
be used to set the pause duration to 8 seconds. This might look like one long
command but it's not, we could just as well send "ATS8" followed by "AT=8".
The = is a command, not an operator.
As modems became faster and more capable and gained features, the Hayes command
set gained many additions and variants. While the core commands remain very
consistently supported, the prefixes "&", "%", "\", and "+" are all used to
indicate various extended commands. Some of these are defined by open
standards, while others will be proprietary for the modem manufacturer. For
example, the GSM standard specifies extended Hayes commands useful for
interacting with cellular modems. For example, "AT+CSQ" can be used to ask a
cellular modem for the current signal strength (RSSI). The "+" prefix is, in
general, used for ITU-standardized additional commands, and "+C" used for
commands related to cellular modems. You'll see these prefixes very frequently
today, as the Hayes command set is more and more seen in the context of
cellular modems rather than telephone modems.
Of course, "+CSQ" being a command seems to violate the syntax I explained
earlier for Hayes commands, and vendor proprietary commands frequently take
this much further by introducing multi-parameter commands with parameter
separators and all types of lengthier command names. For example, for a
personal project I wrote software around a Telit LTE module that made use of
the command string "AT#CSURV" (note non-standard prefix "#"). This command
causes the modem to search for nearby cells and return a listing of cells with
various parameters, which is useful for performing site surveys for cellular
network reliability.
Many modern cellular modems have GPS receivers built-in, and it's possible to
use the GPS receiver via Hayes commands. On the Telit module, a command string
of "AT$GPSACP" causes the modem to return the current position, while the
command string "AT$HTTPGETSTSEED=1,2199" (note two parameters) can be used to
command the embedded GNSS module to load AGPS data from an HTTP source (the
details of AGPS will perhaps be a future topic on this blog).
Brief tangent: some of you may be aware (perhaps I have mentioned it before?)
that dialing emergency calls on GSM and LTE cellphones is, well, a little
weird. Much of that is because the GSM specifications have built-in support for
emergency calling, independent of phone numbers, that is intended to allow
cellular phones to present a consistent emergency calling method regardless of
the dialing conventions of a country/area the user might be roaming in. The
exact commands are unstandardized, but on the Telit module "AT#EMRGD" initiates
an emergency call (note that no phone number is specified) while "AT#EMRGD?"
(it is a common convention in extended AT commands for a trailing "?" to change
the command to a status check) causes the modem to report which phone numbers
the GSM network has indicated should be used for different types of emergency
calls---chiefly for display to the user. This is why dialing common
international emergency numbers like 999 and 110 on a US cellular phone still
results in a connection to 911---in actuality no dialing happens at all, when
the dialer app determines that the number entered appears to be an emergency
call it instead issues an AT command with no phone number at all. Part of the
reason for this is due to enhanced GSM features for position reporting, which
relate to what is called "e911" in the US and provide essentially a basic, slow
data channel between a cellular phone and a PSAP that can be used by the phone
operating system to report a GPS position to the PSAP. There are, of course,
a half dozen AT commands on most cellular modems to facilitate this [1].
Now keep in mind that all of these commands happen over a channel that is
also intended to send data. So, after dialing a call or by issuing the command
string "ATO" (go online) further data sent over the serial connection will
instead go "through" the modem to the other end. In practice, though, mode
switching introduces a set of practical problems (not least of which is
having to make sure the escape sequence "+++" does not appear in data) and
so most modern modems actually don't do it any more. Instead, the Hayes
protocol serial connection is usually used purely for modem commanding and
a separate data channel is used for payload.
This is clearest if we look at the most common modern incantation of Hayes
commands, a cellular modem connected to a host running Linux. Traditionally,
ModemManager would issue a set of commands to the modem to set up the
connection after which it would place the modem into data mode and then trigger
pppd to establish a ppp connection with the modem serial device. In practice,
most cellular modems today are "composite devices" in some sense (i.e. present
multiple independent data channels, whether physically or as a virtual product
of their driver) and appear as both a serial device and a network interface.
The serial device is for Hayes commands, the network interface is, well, a plain
old network interface, which makes network setup rather easier than having to
use PPP. There are various ways that this happens mechanically; in the case of
USB modems it is usually by presenting a composite USB device that includes
some type of network interface profile like CDC Ethernet [2].
In fact, a lot of modems don't just present a serial interface and a network
interface... it's not unusual for modems to present several. One will be for
Hayes commands, but there's often a second to be used as a dedicated channel
for PPP over serial (in case a different method of network connection isn't
used) and then a third dedicated to GPS use. Since applications often want
regular (unsolicited) updates from the GPS module and it's a bit silly to have
to constantly poll via Hayes command or switch modes around, it's common for
LTE modems to allow the host to issue a Hayes command that enables unsolicited
GPS updates, after which they continuously generate GPS fix messages on a
dedicated channel. These are usually in NMEA format, a widespread standard for
GNSS information over simple serial channels that was originally developed to
allow a single GNSS receiver on a boat to disseminate position information to
multiple navigation devices. Yes, specifically a boat---NMEA is the National
Marine Electronics Association, but they came up with a solid standard first
and everyone else has copied it.
Despite the partial shift away, Hayes commands have a lot of staying power due
to their simplicity. Some devices are going to the direction of using more
Hayes commands, since it can actually eliminate the need for any "data channel
proper" in some cases. Many LTE modems oriented towards IoT or industrial use
provide extension Hayes commands that perform high level actions like "make a
POST request". The modem implements HTTP internally so that developers of
embedded devices don't have to. The Telit modules even support HTTPS, although
setting up the TLS trust store is a bit of a pain.
The latest hotness in cellular modules is the ability to load new functionality
at runtime. IOT LTE modems made by Digi, for example, include extra
non-volatile and volatile storage and a MicroPython runtime so that business
logic can run directly in the modem. You can bet that there are Hayes commands
involved.
So 40 years later, a huge variety of modern electronics using cutting-edge
cellular data networks are still, at least for initial setup, pretending to be
a 300-baud Hayes Smartmodem. Maybe you can still find a case out there where
coercing another computer to attempt to send "+++" followed by, after a
sufficient pause, "ATH" will cause it to drop off the network.
A final tangent on Hayes commands, and what brought them to my mind: through a
combination of good luck and force of will I have managed to get a dealership
to take my money for a new car (this proved astoundingly difficult). Since
Albuquerque is quite competitive in its effort to regain the recently lost
title of Car Theft Capitol of the USA I have fit it with a tracking device.
This device, made by a small Chinese outfit, runs the entirety of its logic
within a modem with extended firmware. This is sometimes called a
"microcontroller-less" design, although obviously the modem is essentially
functioning as a microcontroller in this case. For configuration, the tracker
exposes the modem's Hayes serial interface on an external connector, and the
vendor provides a software tool that generates very long Hayes command strings
to configure the tracker behavior (endpoint, report frequency, immobilize
logic, etc). It's possible to use AT commands on this interface to send and
receive SMS, for example, which makes the tracker a more flexible device than
it advertises.
Actually, I lied, one more tangent: Wikipedia notes that the Smartmodem used
a novel design of an extruded aluminum section that the PCB slid into, and a
plastic cap on each end. This was an extremely common case design for '90s
computer accessories. Cheaper plastic injection molding seems to have mostly
killed it off, but it was super convenient to take these types of cases apart
and I rather miss them now.
[1] In fact a new and somewhat upcoming GSM feature called "eCall" enables
"data-only" emergency calls, mostly intended for use by in-vehicle assistive
technologies that may connect an emergency call and then send a position and
status report under the assumption that the occupants may be incapacitated and
unable to speak.
[2] Note that newer modems and operating systems are starting to use MBIM more
often, a newer USB profile that includes a newer command channel. If you have
an LTE modem and do not see the expected Hayes serial device, MBIM may be the
reason... but on most modems a Hayes command must be issued to switch the modem
to MBIM mode, so the Hayes command set is still in use even if only briefly.
I have admitted on HN to sometimes writing computer.rip posts which are
extensions of my HN comments, and I will make that admission here as well. A
discussion recently came up that relates to a topic I am extremely interested
in: the fundamental loss of peer-to-peer capability on the internet and various
efforts to implement peer-to-peer distributed systems on top of the internet.
Of course, as is usual, someone questioned my contention that there really is
no such thing as a distributed system on the internet with the example of
Bitcoin. Having once made the mistake of a graduate thesis on Bitcoin
implementation details it is one of the things I feel most confident in
complaining about, and I do so frequently. Rest assured that Bitcoin's
technical implementation is 1) a heaping pile of trash which ought to
immediately dispel stories about Nakamoto being some kind of engineering
savant, and 2) Bitcoin is no exception to the fundamental truth that the
internet does not permit distributed systems.
But before we get there we need to start with history... fortunate since
history is the part I really care to write about.
Some time ago I mentioned that I had a half-written blog post that I would
eventually finish. I still have it, although it's now more like 3/4 written.
The topic of that post tangentially involves early computer networks such as
ARPANET, BITNET, ALOHAnet, etc. that grew up in academic institutions and
incubated the basic concepts around which computer networks are built today.
One of my claims there is that ARPANET is overrated and had a smaller impact on
the internet of today than everyone thinks (PLATO and BITNET were probably both
more significant), but it is no exception to a general quality most of these
early networks had that has been, well, part of the internet story: they were
fundamentally peer to peer.
This differentiation isn't a minor one. Many early commercial computer networks
were extensions of timeshare multiple access systems. That is, they had a
strictly client-server (or we could actually call it terminal-computer)
architecture in which service points and service clients were completely
separated. Two clients were never expected to communicate with each other
directly, and the architecture of the network often did not facilitate this
kind of use.
Another major type of network which predated computer networks and had
influence on them were telegraph networks. Telegraph systems had long employed
some type of "routing," and you can make a strong argument that the very
concept of packet switching originated in telegraph systems. We tend to think
of telegraph systems as being manual, morse-code based networks where routing
decisions and the actual message transfer were conducted by men wearing green
visors. By the 1960s, though, telegraph networks were gaining full automation.
Messages were sent in baudot (a 5-bit alphabetical encoding) with standardized
headers and trailers that allowed electromechanical equipment and, later,
computers to route them from link to link automatically. The resemblance to packet
switched computer networks is very strong, and by most reasonable definitions
you could say that the first wide-scale packet network in the US was that of
Western Union [1].
Still, these telegraph networks continued to have a major structural difference
from what we now consider computer networks. Architecturally they were
"inverted" from how we think of hardware distribution on computer networks:
they relied on simple, low-cost, low-capability hardware at the customer site,
and large, complex routing equipment within the network. In other words, the
"brains of the operation" were located in the routing points, not in the users
equipment. This was useful for operators like Western Union in that it reduced
the cost of onboarding users and let them perform most of the maintenance,
configuration, upgrades etc. at their central locations. It was not so great
for computer systems, where it was desirable for the computers to have a high
degree of control over network behavior and to minimize the cost of
interconnecting computers given that the computers were typically already
there.
So there are two significant ways in which early computer networks proper were
differentiated from time-sharing and telegraph networks, and I put both of them
under the label of "network of equals," a business term that is loosely
equivalent to "peer to peer" but more to our point. First, a computer network
allows any node to communicate with any other node. There is no strict
definition of a "client" or "server" and the operation of the network does not
make any such assumptions as to the role of a given node. Second, a computer
network places complexity at the edge. Each node is expected to have the
ability to make its own decisions about routing, prioritization, etc. In
exchange, the "interior" equipment of the network is relatively simple and does
not restrict or dictate the behavior of nodes.
A major manifestation of this latter idea is distributed routing. Most earlier
networks had their routes managed centrally. In the phone and telegraph
networks, the maintenance of routing tables was considered part of "traffic
engineering," an active process performed by humans in a network operations
center. In order to increase flexibility, computer networks often found it more
desirable to generate routing tables automatically based on exchange of
information between peers. This helped to solidify the "network of equals"
concept by eliminating the need for a central NOC with significant control of
network operations, instead deferring routing issues to the prudence of the
individual system operators.
Both of these qualities make a great deal of sense in the context of computer
networking having been pioneered by the military during the Cold War.
Throughout the early days of both AUTODIN (the military automated telegraph
network) and then ARPANET which was in some ways directly based on it, there
was a general atmosphere that survivability was an important characteristic of
networks. This could be presented specifically as survivability in nuclear war
(which we know was a key goal of basically all military communications projects
at the time), but it has had enduring value outside of the Cold War context as
we now view a distributed, self-healing architecture as being one of the great
innovations of packet-switched computer networks. The fact that this is also
precisely a military goal for survival of nuclear C2 may have more or less
directly influenced ARPANET depending on who you ask, but I think it's clear
that it was at least some of the background that informed many ARPANET design
decisions.
It might help illustrate these ideas to briefly consider the technical
architecture of ARPANET, which while a somewhat direct precursor to the modern
internet is both very similar and very different. Computers did not connect
"directly" to ARPANET because at the time it was unclear what such a "direct"
connection would even look like. Instead, ARPANET participant computers were
connected via serial line to a dedicated computer called an interface message
processor, or IMP. IMPs are somewhat tricky to map directly to modern concepts,
but you could say that they were network interface controllers, modems, and
routers all in one. Each IMP performed the line coding to actually transmit
messages over leased telephone lines, but also conducted a simple distributed
routing algorithm to determine which leased telephone line a message should
be sent over. The routing functionality is hard to describe because it evolved
rapidly over the lifetime of ARPANET, but it was, by intention, both simple and
somewhat hidden. Any computer could send a message to any other computer, using
its numeric address, by transferring that message to an IMP. The IMPs performed
some internal work to route the message but this was of little interest to the
computers. The IMPs only performed enough work to route the message and ensure
reliable delivery, they did not do anything further and certainly nothing
related to application-level logic.
Later, ARPANET equipment contractor BBN, along with the greater ARPANET
project, would begin to openly specify "internal" protocols such as for routing
in order to allow the use of non-BBN IMPs. Consequentially, much of the
functionality of the IMP would be moved into the host computers themselves,
while the routing functionality would be moved into dedicated routing
appliances. This remains more or less the general idea of the internet today.
Let's take these observations about ARPANET (and many, but not all, other early
computer networks) and apply them to the internet today.
Peer-to-Peer Connectivity
The basic assumption that any computer could connect to any other computer at
will proved problematic by, let's say, 1971, when an employee of BBN created
something we might now call a computer worm as a proof of concept. The problem
was far greater as minicomputers and reduced connectivity costs significantly
increased the number of hosts on the internet, and by the end of the '90s
network-based computer worms had become routine. Most software and the
protocols it used were simply not designed to operate in an adversarial
climate. But, with the internet now so readily accessible, that's what it
became. Computers frequently exposed functionality to the network that was
hazardous when made readily available to anonymous others, with Windows SMB
being a frequent concern [2].
The scourge of internet-replicating computer worms was stopped mostly not by
enhancements in host security but instead as an incidental effect of the
architecture of home internet service. Residential ISPs had operated on the
assumption that they provided connectivity to a single device, typically using
PPP over some type of telephone connection. As it became more common for home
networks to incorporate multiple devices (especially after the introduction of
WiFi) residential ISPs did not keep pace. While it was easier to get a subnet
allocation from a residential ISP back then than it is now, it was very rare,
and so pretty much all home networks employed NAT as a method to make the
entire home network look, to the internet, like a single device. This remains
the norm today.
NAT, as a side effect of its operation, prohibits all inbound connections not
associated with an existing outbound one.
NAT was not the first introduction of this concept. Already by the time
residential internet was converging on the "WiFi router" concept, firewalls
had become common in institutional networks. These early firewalls were
generally stateless and so relatively limited, and a common configuration
paradigm (to this day) was to block all traffic that did not match a
restricted set of patterns for expected use.
Somewhere along this series of incremental steps, a major change emerged... not
by intention so much as by the simple accretion of additional network controls.
The internet was no longer peer to peer.
Today, the assumption that a given internet host can connect to another
internet host is one where exceptions are more common than not. The majority
of "end user" hosts are behind NAT and thus cannot accept inbound connections.
Even most servers are behind some form of network policy that prevents them
accepting connections that do not match an externally defined list. All of this
has benefits, there is an upside, but there is also a very real downside, which
is that the internet has effectively degraded to a traditional client-server
architecture.
One of the issues that clearly illustrated this to many of my generation was
multiplayer video games. Most network multiplayer games of the '90s to the
early '00s were built on the assumption that one player would "host" a game and
other players would connect to them. Of course as WiFi routers and broadband
internet became common, this stopped working without extra manual configuration
of the NAT appliance. Similar problems were encountered by youths in
peer-to-peer systems like BitTorrent and, perhaps this will date me more than
anything else, eD2k.
But the issue was not limited to such frivolous applications. Many early
internet protocols were designed with the peer-to-peer architecture of the
internet baked into the design. FTP is a major example we encounter today,
which was originally designed under the assumption that the server could open a
connection to the client. RTMP and its entire family of protocols, including
SIP which remains quite relevant today, suffer from the same basic problem.
For any of these use-cases to work today, we have had to clumsily re-invent the
ability for arbitrary hosts to connect to each other. WebRTC, for example, is
based on RTMP and addresses these problems for the web by relying on STUN and
TURN, two separate but related approaches to "NAT negotiation." Essentially
every two-way real-time media application must take a similar approach, which
is particularly unfortunate since TURN introduces appreciable overhead as well
as privacy and security implications.
Complexity at the Edge
This is a far looser argument, but I think one that is nonetheless easy to make
confidently: the concept of complexity at the edge has largely been abandoned.
This happens more at the application layer than at lower layers, since the
lower layers ossified decades ago. But almost all software has converged on the
web platform, and the web platform is inherently client-server. Trends such as
SPAs have somewhat reduced the magnitude of the situation as even in web
browsers some behavior can happen on the client-side, but a look at the larger
ecosystem of commercial software will show you that there is approximately zero
interest in doing anything substantial on an end-user device. The modern
approach to software architecture is to place all state and business logic "in
the cloud."
Like the shift away from P2P, this has benefits but also has decided
disadvantages. Moreover, it has been normalized to the extent that traditional
desktop development methods that were amenable to significant complexity at the
client appear to be atrophying on major platforms.
As the web platform evolves we may regain some of the performance, flexibility,
and robustness associated with complexity at the edge, but I'm far from
optimistic.
Peer-to-Peer and Distributed Applications Today
My contention that the internet is not P2P might be surprising to many as there
is certainly a bevy of P2P applications and protocols. Indeed, one of the
wonders of software is that with sufficient effort it is possible to build a
real-time media application on top of a best-effort packet-switched network...
the collective ingenuity of the software industry is great at overcoming the
limitations of the underlying system.
And yet, the fundamentally client-server nature of the modern internet cannot
be fully overcome. P2P systems rely on finding some mechanism to create and
maintain open connections between participants.
Early P2P systems such as BitTorrent (and most other file sharing systems)
relied mostly on partial centralization and user effort. In the case of
BitTorrent, for example, trackers are centralized services which maintain a
database of available peers. BitTorrent should thus be viewed as a partially
centralized system, or perhaps better as a distributed system with centralized
metadata (this is an extremely common design in practice, and in fact the
entire internet could be described this way if you felt like it). Further
BitTorrent assumes that the inbound connection problem will be somehow solved
by the user, e.g. by configuring appropriate port forwarding or using a local
network that supports automated mechanisms such as UPnP.
Many P2P systems in use today have some sort of centralized directory or
metadata service that is used for peer discovery, as well as configuration
requirements for the user. But more recent advances in distributed methods have
somewhat alleviated the needs for this type of centralization. Methods such as
distributed hole punching (both parties initiating connections to each other at
the same time to result in appropriate conntrack entries at the NAT devices)
allow two arbitrary hosts to connect, but require that there be some type of
existing communications channel to facilitate that connection.
Distributed hash tables such as the Kademlia DHT are a well understood method
for a distributed system to share peer information, and indeed BitTorrent has
had it bolted on as an enhancement while many newer P2P systems rely on a DHT
as their primary mechanism of peer discovery. But for all of these there is a
bootstrapping problem: once connected to other DHT peers you can use the DHT to
obtain additional peers. But, this assumes that you are aware of at least a
single DHT peer to begin with. How do we get to that point?
You could conceivably search the entire internet space, but given the size of
the internet that's infeasible. The next approach you might reach for is some
kind of broadcast or multicast, but for long-standing abuse, security, and
scalability reasons broadcast and multicast cannot be routed across the
internet. Anycast offers similar potential and is feasible on the internet, but
it requires the cooperation of an AS owner which would be both centralized and
require a larger up-front investment than most P2P projects are interested in.
Instead, real P2P systems address this issue by relying on a centralized
service for initial peer discovery. There are various terms for this that are
inconsistent between P2P protocols and include introducer, seed, bootstrap
node, peer helper, etc. For consistency, I will use the term introducer,
because I think it effectively describes the concept: an introducer is a
centralized (or at least semi-centralized) service that introduces new peers
to enough other peers that they can proceed from that point via distributed
methods.
As a useful case study, let's examine Bitcoin... and we have come full circle
back to the introduction, finally. Bitcoin prefers the term "seeding" to refer
to this initial introduction process. Dating back to the initial Nakamoto
Bitcoin codebase, the Bitcoin introduction mechanism was via IRC. New Bitcoin
nodes connected to a hardcoded IRC server and joined a harcoded channel, where
they announced their presence and listened for other announcements. Because IRC
is a very simple and widely implemented message bus, this use of IRC had been
very common. Ironically it was its popularity that lead to its downfall:
IRC-based C2 was extremely common in early botnets, at such a level that it has
become common for corporate networks to block or at least alert on IRC
connections, as the majority of IRC connections out of many corporate networks
are actually malware checking for instructions.
As a result, and for better scalability, the Bitcoin project changed the
introduction mechanism to DNS, which is more common for modern P2P protocols.
The Bitcoin Core codebase includes a hardcoded
list
of around a dozen DNS names. When a node starts up, it queries a few of these
names and receives a list of A records that represent known-good,
known-accessible Bitcoin nodes. The method by which these lists are curated is
up to the operators of the DNS seeds, and it seems that some are automated
while some are hand-curated. The details don't really matter that much, as long
as it's a list that contains a few contactable peers so that peer discovery can
continue from there using the actual Bitcoin protocol.
Other projects use similar methods. One of the more interesting and
sophisticated distributed protocols right now is
Hypercore, which is the basis of the Beaker
Browser, in my opinion the most promising
distributed web project around... at least in that it presents a vision of a
distributed web that is so far not conjoined at the hip with Ethereum-driven
hypercapitalism. Let's take a look at how Hypercore and its underlying P2P
communications protocol Hyperswarm address the problem.
Well, it's basically the exact same way as Bitcoin with one less step of
indirection. When new Hypercore nodes start up, they connect to
bootstrap1.hyperdht.org through bootstrap3.hyperdht.org, each of which
represents one well-established Hypercore node that can be used to get a
toehold into the broader DHT.
This pattern is quite general. The majority of modern P2P systems bootstrap by
using DNS to look up either a centrally maintained node, or a centrally
maintained list of nodes. Depending on the project these introducer DNS entries
may be fully centralized and run by the project, or may be "lightly
decentralized" in that there is a list of several operated by independent
people (as in the case of Bitcoin). While this is slightly less centralized it
is only slightly so, and does not constitute any kind of real distributed
system.
Part of the motivation for Bitcoin to have multiple independently operated DNS
seeds is that they are somewhat integrity sensitive. Normally the Bitcoin
network cannot enter a "split-brain" state (e.g. two independent and equally
valid blockchains) because there are a large number of nodes which are strongly
interconnected, preventing any substantial number of Bitcoin nodes being
unaware of blocks that other nodes are aware of. In actuality Bitcoin enters a
"split-brain" state on a regular basis (it's guaranteed to happen by the
stochastic proof of work mechanism), but as long as nodes are aware of all
"valid" blockchain heads they have an agreed upon convention to select a single
head as valid. This method can sometimes take multiple rounds to converge,
which is why Bitcoin transactions (and broadly speaking other blockchain
entries) are not considered valid until multiple "confirmations"---this simply
provides an artificial delay to minimize the probability of a transaction
being taken as valid when the Bitcoin blockchain selection algorithm has not
yet converged across the network.
But this is only true of nodes which are already participating. When a new
Bitcoin node starts for the first time, it has no way to discover any other
nodes besides the DNS seeds. In theory, if the DNS seeds were malicious, they
could provide a list of nodes which were complicit in an attack by
intentionally not forwarding any information about some blocks or
advertisements of nodes which are aware of those blocks. In other words, in
practice the cost of a sybil attack is actually reduced to the number of nodes
directly advertised by the DNS seeds, but only for new users and only if the
DNS seeds are complicit. In practice the former is a massive limitation. The
Bitcoin project allows only trusted individuals, but also multiple such
individuals, to operate DNS seeds in order to mitigate the latter. In practice
the risk is quite low, mostly due to the limited impact of the attack rather
than its difficulty level (very few people are confirming Bitcoin transactions
using a node which was just recently started for the first time).
Multicast
One of the painful points here is that multicast and IGMP make this problem
relatively easy on local networks, and indeed mDNS/Avahi/Bonjour/etc solve
this problem on a daily basis, in a reasonably elegant and reliable way,
to enable things like automatic discovery of printers. Unfortunately we cannot
use these techniques across the internet because, among other reasons, IGMP
does not manageably scale to internet levels.
P2P systems can use them across local networks, though, and there are P2P
systems (and even non-P2P systems) which use multicast methods to opportunistically
discover peers on the same local network. When this works, it can potentially
eliminate the need for any centralized introducer. It's, well, not that likely
to work... that would require at least one, preferably more than one, fully
established peer on the same local network. Still, it's worth a shot, and
Hypercore for example does implement opportunistic peer discovery via mDNS
zeroconf.
Multicast presents an interesting possibility: much like the PGP key parties of
yore, a P2P system can be bootstrapped without dependence on any central
service if its users join the same local network at some point. For
sufficiently widely-used P2P systems, going to a coffee shop with a stable,
working node once in order to collect initial peer information will likely be
sufficient to remain a member of the system into the future (as long as there
are enough long-running peers with stable addresses that you can still find
some and use them to discover new peers weeks and months into the future).
Of course by that point we could just as well say that an alternative method to
bootstrapping is to call your friends on the phone and ask them for lists of
good IP addresses. Still, I like my idea for its cypherpunk aesthetics, and when
I inevitably leave my career to open a dive bar I'll be sure to integrate it.
Hope for the future
We have seen that all P2P systems that operate over the internet have,
somewhere deep down inside, a little bit of centralized original sin. It's not
a consequence of the architecture of the internet so much as it's a consequence
of the fifty years of halting change that has brought the internet to its
contemporary shape... changes that were focused around the client-server use
cases that drive commercial computing for various reasons, and so had the
network shaped in their image to the extent of exclusion of true P2P
approaches.
Being who I am it is extremely tempting to blame the whole affair on
capitalism, but of course that's not quite fair. There are other reasons as
well, namely that the security, abuse, stability, scalability, etc. properties
of truly distributed systems are universally more complex than centralized
ones. Supporting fully distributed internet use cases is more difficult, so
it's received lower priority. The plurality of relatively new P2P/distributed
systems around today shows that there is some motivation to change this state
of affairs, but that's mostly been by working around internet limitations
rather than fixing them.
Fixing those limitations is difficult and expensive, and despite the number of
P2P systems the paucity of people who actually use them in a P2P fashion would
seem to suggest that the level of effort and cost is not justifiable to the
internet industry. The story of P2P networking ends where so many stories about
computing end: we got here mostly by accident, but it's hard to change now so
we're going to stick with it.
I've got a list of good IP addresses for you though if you need it.
[1] WU's digital automatic routing network was developed in partnership with
RCA and made significant use of microwave links as it expanded. Many have
discussed the way that the US landscape is littered in AT&T microwave relay
stations, fewer know that many of the '60s-'80s era microwave relays not built
by AT&T actually belonged to Western Union for what we would now call data
networking. The WU network was nowhere near as extensive as AT&T's but was
particularly interesting due to the wide variety of use-cases it served, which
ranged from competitive long distance phone circuits to a a very modern looking
digital computer interconnect service.
[2] We should not get the impression that any of these problems are in any way
specific to Windows. Many of the earliest computer worms targeted UNIX systems
which were, at the time, more common. UNIX systems were in some ways more
vulnerable due to their relatively larger inventory of network services
available, basically all of which were designed with no thought towards
security. Malware developers tended to follow the market.
It's the first of the new year, which means we ought to do something momentous
to mark the occasion, like a short piece about telephones. Why so much on
telephones lately? I think I'm just a little burned out on software at the
moment and I need a vacation before I'm excited to write about failed Microsoft
ventures again, but the time will surely come. Actually I just thought of a
good one I haven't mentioned before, so maybe that'll be next time.
Anyway, let's talk a little bit about phones, but not quite about long distance
carriers this time. Something you may or may not have noticed about the
carriers we've discussed, perhaps depending on how interesting you find data
communications, is that we have covered only the physical layer. So far, there
has been no consideration of how switches communicated in order to set up and
tear down connections across multiple switches (i.e. long distance calls).
Don't worry, we will definitely get to this topic eventually and there's plenty
to be said about it. For the moment, though, I want to take a look at just one
little corner of the topic, and that's multifrequency tone systems.
Most of us are at least peripherally familiar with the term "dual-tone
multifrequency" or "DTMF." AT&T intended to promote Touch-Tone as the consumer
friendly name for this technology, but for various reasons (mainly AT&T's
trademark) most independent manufacturers and service providers have stuck to
the term DTMF. DTMF is the most easily recognizable signaling method in the
telephone system: it is used to communicate digital data over phone lines, but
generally only for "meta" purposes such as connection setup (i.e. dialed
digits). An interesting thing about DTMF that makes it rather recognizable is
that it is in-band, meaning that the signals are sent over the same audio
link as the phone call itself... and if your telephone does not mute during
DTMF (some do but most do not), you can just hear those tones.
Or, really, I should say: if your phone just makes the beep boop noises for fun
pretend purposes, like cellphones, which often emit DTMF tones during dialing
even though the cellular network uses entirely on-hook dialing and DTMF is not
actually used as part of call setup. But that's a topic for another day.
DTMF is not the first multi-frequency signaling scheme. It is directly based on
an earlier system called, confusingly, multifrequency or MF. While DTMF and MF
have very similar names, they are not compatible, and were designed for
separate purposes.
MF signaling was designed for call setup between switches, mostly for
long-distance calling. Whenever a call requires a tandem switch, so say you
call another city, your telephone switch needs to connect you to a trunk on a
tandem switch but also inform the tandem switch of where you intend to call.
Historically this was achieved by operators just talking to each other over the
trunk before connecting it to your local loop, but in the era of direct dialing
an automated method was needed. Several different techniques were developed,
but MF was the most common for long-distance calling in the early direct dial
era.
An interesting thing about MF, though, is that it was put into place in a time
period in which some cities had direct long distance dialing but others did
not. As a result, someone might be talking to an operator in order to set up a
call to a city with direct dial. This problem actually wasn't a new one, the
very earliest direct dialing implementations routinely ran into this issue, and
so it became common for operators switchboards to include a telephone dial
mounted at each operator position. The telephone dial allowed the operator to
dial for a customer, and was especially important when connecting someone into
a direct dial service area.
MF took the same approach, and so one could say that there were two distinct
modes for MF: in machine-to-machine operation, a telephone switch automatically
sent a series of MF tones after opening a trunk, mainly to forward the dialed
number to the next switch in the series. At the same time, many operators had
MF keypads at their positions that allowed them to "dial" to a remote switch
by hand. The circuitry that implemented these keypads turned more or less
directly into the DTMF keypads we see on phones today.
Like DTMF, MF worked by sending a pair of two frequencies [1]. The frequencies
were selected from the pool of 700, 900, 1100, 1300, 1500, and 1700Hz. That's
six frequencies, and it is required that two frequencies always be used, so the
number of possible symbol is 6c2 or 15. Of course we have the ten digits, 0-9,
but what about the other five? The additional five possibilities were used for
control symbols. For reasons that are obscure to me, the names selected for
the control symbols were Key Pulse or KP and Start or ST. Confusingly, KP
and ST each had multiple versions and were labeled differently by different
equipment. The closest thing to a universal rule would be to say that MF could
express the symbols 0-9, KP1-KP2, and ST1-ST3.
Part of the reason that the labeling of the symbols was inconsistent is that
their usage was somewhat inconsistent from switch to switch. Generally
speaking, an operator would connect to a trunk and then press KP1, the number
to be called, and then ST1. KP1 indicated to the far-side switch that it should
set up for an incoming connection (e.g. by assigning a sending unit or other
actions depending on the type of switch), while ST1 indicated that dialing was
complete. Most of the time telephone switches used other means (digit-matching
based on "dial plans") to determine when dialing was complete, but since tandem
switches handled international calls MF was designed to gracefully handle
arbitrary length phone numbers (due to both variance between countries and the
bizarre choice of some countries to use variable-length phone numbers).
The additional KP and ST symbols had different applications but were most often
used to send "additional information" to the far side switch, in which case the
use of one of the control symbols differentiated the extra digits (e.g. an
account number) from the phone number.
MF keypads were conventionally three columns, two columns of digits (vertically
arranged) and one of control symbols on the right.
This is a good time to interject a quick note: the history of MF signaling turns
out to be surprisingly obscure. I had been generally aware of it for years, I'm
not sure why, but when I went to read the details I was surprised by... how few
details there are. Different sources online conflict about basic facts (for
example, Wikipedia lists 6 frequencies which is consistent with the keypad I
have seen and the set of symbols, but a 1960 BSTJ overview article says there
were only five...). So far as I can tell, MF was never formally described in
BSTJ or any other technical journal, and I can't find any BSPs describing the
components. I suspect that MF was an unusually loose standard for the telephone
system, and that the MF implementation on different switches sometimes varied
significantly. This is not entirely surprising since the use of MF spanned from
manual exchanges to modern digital exchanges (it is said to still be in use in
some areas today, although I am not aware of any examples), covering around 80
years of telephone history.
I didn't really intend to go into so much detail on MF here, but it's useful to
understand my main topic: DTMF. MF signaling went into use by the late 1940s
(date unclear for the reasons I just discussed), and by 1960 was considered a
main contender for AT&T's goal of introducing digital signaling not just
between switches but also from the subscriber to the switch [2]. A few years
later, AT&T introduced Touch-Tone or DTMF dialing. Unsurprisingly, DTMF is
really just MF with some problems solved.
MF posed a few challenges for use with subscriber equipment. The biggest was
the simple placement of the frequencies. The consistent 200 Hz separation
meant that certain tones were subject to harmonics and other intermodulation
products from other tones, requiring high signal quality for reliable decoding.
That wasn't much of a problem on toll circuits which were already maintained to
a high standard, but local loops were routinely expected to work despite very
poor quality, and there was a huge variety of different equipment in use on
local loops, some of which was very old and easily picked up spurious noise.
Worse, the MF frequencies were placed in a range that was fairly prominent in
human speech. This resulted in a high risk that a person talking would be
recognized by an MF decoder as a symbol, which could create all kind of
headache. This wasn't really a problem for MF because MF keypads were designed
to disconnect the subscriber when digits were pressed. DTMF, though, was
intended to be simpler to implement and convenient to use while in a call,
which made it challenging to figure out how to disconnect or "mute" both
parties during DTMF signaling.
To address these issues, a whole new frequency plan was devised for DTMF. The
numbers and combinations all seem a bit odd, but were chosen to avoid any kind
of potential intermodulation artifacts that would be within the sensitivity
range of the decoder. DTMF consisted of eight frequencies, which were
organized differently, into a four by four grid. A grid layout was used, in
which there is one set of "low" frequencies and one set of "high" frequencies
and "low" was never mixed with "low" and vice versa, because it allowed much
tighter planning of the harmonics that would result from mixing the
frequencies.
So, we can describe DTMF this way: there are four rows and four columns. The
four rows are assigned 697, 770, 852, and 941 Hz, while the four columns are
1209, 1336, 1477, and 1633 Hz. Each digit consists of one row frequency and
one column frequency, and they're laid out the same way as the keypad.
Wait a minute... four rows, four columns?
DTMF obviously needed to include the digits 0-9. Some effort was put into
selecting the other available symbols, and for various reasons * and # were
chosen as complements to the digits (likely owing to their common use in
typewritten accounting and other business documents at the time). That makes
up 12 symbols, the first three columns. The fourth column, intended mostly for
machine-to-machine applications [3], was labeled A, B, C, and D.
Ever since, DTMF has featured the mysterious symbols A-D, and they have seen
virtually no use. It is fairly clear to me that they were only included
originally because DTMF was based directly on MF and so tried to preserve the
larger set of control symbols and in general a similar symbol count. The
engineers likely envisioned DTMF taking over as a direct replacement for MF
signaling in switch-to-switch signaling, which did happen occasionally but
was not widespread as newer signaling methods were starting to dominate by
the time DTMF was the norm. Instead, they're essentially vestigial.
One group of people which would be generally aware of the existence of A-D are
amateur radio operators, as the DTMF encoders in radios almost always provide a
full 4x4 keypad and it is somewhat common for A-D to be used for controlling
telephone patches---once the telephone patch is connected, 0-9, *, and # will
be relayed directly to the phone network, A-D provide an opportunity for four
symbols that are reserved for the patch itself to respond to.
Another group of people to which this would be familiar is those in the
military from roughly the '70s to the '90s, during the period of widespread
use of AUTOVON. While AUTOVON was mostly the same as the normal telephone
network but reserved for military use, it introduced one major feature that
the public telephone system lacked: a precedence, or priority system.
Normally dialed AUTOVON calls were placed at "routine" priority, but
"priority," "immediate," "flash," and "flash override" were successively higher
precedence levels reserved for successively more important levels of military
command and control. While it is not exactly true, it is almost true, and
certainly very fun to say, that AUTOVON telephones feature a button that only
the President of the United States is allowed to press. The Flash Override or
FO button was mostly reserved for use by the national command authority in
order to invoke a nuclear attack, and as you would imagine would result in
AUTOVON switches abruptly terminating any other call as necessary to make
trunks available.
AUTOVON needed some way for telephones to indicate to the switch what the
priority of the call was, and so it was obvious to relabel the A, B, C, and D
DTMF buttons as FO, F, I, and P respectively. AUTOVON phones thus feature a
full 4x4 keypad, with the rightmost column typically in red and used to prefix
dialed calls with a precedence level. Every once in a while I have thought
about buying one of these phones to use with my home PABX but they tend to be
remarkably expensive... I think maybe restorers of military equipment are
holding up prices.
And that's what I wanted to tell you: the military has four extra telephone
buttons that they don't tell us about. Kinda makes you take the X-files a
little more seriously, huh?
In all seriousness, though, they both do and don't today. Newer military
telephone systems such as DSN and the various secure VoIP systems usually
preserve a precedence feature but offer it using less interesting methods.
Sometimes it's by prefixing dialing with a numeric code, sometimes via feature
line keys, but not by secret DTMF symbols.
[1] This was technically referred to as a "spurt" of MF, a term which I am
refusing to use because of my delicate sensibilities.
[2] One could argue that pulse dialing was "digital," but because it relied on
the telephone interrupting the loop current it was not really "in-band" in the
modern sense and so could not readily be relayed across trunks. Much of the
desire for a digital subscriber signaling system was for automated phone
systems, which could never receive pulses since they were "confined" to the
local loop. Nonetheless DTMF was also useful for the telephone system itself
and enabled much more flexible network architectures, especially related to
remote switches and line concentrators, since DTMF dialing could be decoded
by equipment "upstream" from wherever the phone line terminated without any
extra signaling equipment needed to "forward" the pulses.
[3] This might be a little odd from the modern perspective but by the '60s
machine-to-machine telephony using very simple encodings was becoming very
popular... at least in the eyes of the telephone company, although not always
the public. AT&T was very supportive of the concept of telephones which read
punched cards and emitted the card contents as DTMF. In practice this ended up
being mostly used as a whimsical speed-dial, but it was widely advertised for
uses like semi-automated delivery of mail orders (keypunch them in the field,
say going door to door, and then call an electromechanical order taking system
and feed them all through your phone) and did see those types of use for some
time.