This is an experiment in format for me: I would like to have something like
twitter for thoughts that are interesting but don't necessarily make a whole
post. The problem is that I'm loathe to use Twitter and I somehow find most of
the federated solutions to be worse, although I'm feeling sort of good about
Pixelfed. But of course it's not amenable to text.
I would just make these blog posts, but blog posts get emailed out to a decent
number of subscribers now. I know that I, personally, react with swift anger to
any newsletter that dare darken my inbox more than once a week. I don't want to
burden you with another subject line to scroll past unless it's really worth
it, you know? So here's my compromise: I will post short items on the blog, but
not email them out. When I write the next proper post, I'll include any short
items from the meantime in the email with that post. Seem like a fair
compromise? I hope so. Beats my other plan, at least, which was to start a
syndicated newspaper column.
Also, having now written Computers Are Bad for nearly two years, I went back
and read some of my old posts. I feel like my tone has gotten more formal
over time, something I didn't intend.
I would hate for anyone to accuse me of being "professional." In an effort to
change this trend, the tone of these will be decidedly informal and my typing
might be even worse than usual.
The good part
So tonight I was lying on my couch watching Arrested Development yet again
while not entirely sober, and I experienced something of a horror film
scenario: I noticed that the "message" light on my desk phone was flashing.
I remembered I'd missed several calls today, so I retrieved my voice mail.
That is, I pulled out my smartphone and scrolled through my inbox to find the
notification emails with a PCM file attached. Even I don't actually make a
phone call for that.
The voicemail, from a seemingly random phone number in California, was 1 minute
and 8 seconds long. I realized that this was a trend: over the last few days I
had received multiple 1 minute, 8 second voice messages but the first one I had
listened to seemed to be silent. I had since been ignoring them, assuming it
was a telephone spammer that hung up a little bit too late (an amusing defect
of answering machines and voicemail is that it has always been surprisingly hard
for a machine to determine whether a person answered or voicemail, although
there are a few heuristics). Just for the heck of it, though, realizing that I
had eight such messages, I listened to one again.
The contents: a sort of digital noise. It sounded like perhaps very far away
music, or more analytically it seemed like mostly white noise with a little
bit of detail that a very low-bitrate speech codec had struggled to handle.
It was quiet, and I could never quite make anything out, although it always
seemed like I was just on the edge of distinguishing a human voice.
Here's the best part: after finding about fifteen seconds of this to be
extremely creepy, I went back to my email. The sound kept on playing. I
checked the notifications. Still going. It wouldn't stop. I went to the task
switcher and dismissed the audio player. Still going. Increasingly agitated,
and on the latest version of Android which is somehow yet harder to use, I held
power and remembered it doesn't do that any more. I held power and volume down,
vaguely remembering they had made it something like that. No, screenshot.
Holding power and volume up finally got me to the six-item power menu, which
somehow includes an easy-access "911" button even though you have to remember
some physical button escape sequence to get it. Rebooting the phone finally
stopped the noise.
Thoroughly spooked, I considered how I came to this point.
Because I am a dweeb and because IP voice termination is very cheap if you look
in the right places, I hold multiple toll-free phone numbers, several of which
go through directly to the extension of my desk phone. This had been the case
for some time, a couple of years at least, and while I don't put it to a lot of
productive use I like to think I'm kind of running my own little cottage
PrimeTel. Of course basically the only calls these numbers ever get are spam
calls, including a surprising number of car warranty expiration reminders
considering the toll-free number.
But now I remember that there is another type of nuisance call that afflicts
some toll free numbers. You see, toll free numbers exhibit a behavior called
"reverse charging" or "reverse tolling" where the callee pays for the call
instead of the caller. Whether you get your TFN on a fixed contract basis or
pay a per-minute rate, your telephone company generally pays just a little bit
of money each minute to the upstream telephone providers to compensate them for
carrying the call that their customer wasn't going to pay for.
This means that, if you have a somewhat loose ethical model of the phone
system, you can make a bit of profit by making toll-free calls. If you either
are a telco or get a telco to give you a cut of the toll they receive, every
toll-free call you make now nets you a per-minute rate. There is obviously a
great temptation to exploit this. Find a slightly crooked telco, make thousands
of calls to toll-free numbers, get some of them to stay on the phone for a
while, and you are now participating in capitalism.
The problem, of course, is that most telcos (even those that offer a kickback
for toll-free calls, which is not entirely unusual) will find out about the
thousands of calls you are making. They'll promptly, usually VERY promptly due
to automated precautions, give you the boot. Still, there are ways, especially
overseas or by fraud, to make a profit this way.
And so there is a fun type of nuisance call specific to the recipients of
toll-free calls: random phone calls that are designed to keep you on the phone
as long as possible. This is usually done by playing some sort of audio that is
just odd enough that you will probably stay on the phone to listen for a bit
even after you realize it's just some kind of abuse. Something that sounds
almost, but not quite, like someone talking is a classic example.
Presumably one of the many operations making these calls is happy to talk to
voicemail for a bit (voicemail systems typically "supe," meaning that the call
is charged as if it connected). why one minute and eight seconds I'm not sure,
that's not the limit on my voicemail system. Perhaps if you include the
greeting recording it's 2 minutes after the call connects or something.
I've known about this for some time, it's a relatively common form of toll
fraud. I likely first heard of it via an episode of "Reply All" back when that
was a going concern. Until now, I'd never actually experienced it. I don't know
why that's just changed, presumably some operation's crawler just now noticed
one of my TFNs on some website. Or they might have even wardialed it the old
fashioned way and now know that it answers.
Oh, and the thing where it kept on playing after I tried to stop it, as if it
were the distorted voice of some supernatural entity? No idea, as I said, I use
Android. God only knows what part of the weird app I use and the operating
system support for media players went wrong. Given the complexity and generally
poor reliability of the overall computing ecosystem, I can easily dismiss
basically any spooky behavior emanating from a smartphone. I'm not going to
worry about evil portents until it keeps going after a .45 to the chipset...
Maybe a silver one, just in the interest of caution.
One of the great joys of the '00s was the tendency of marketers to apply the
acronym "HD" to anything they possibly could. The funniest examples of this
phenomenon are those where HD doesn't even stand for "High Definition," but
instead for something a bit contrived like "Hybrid Digital." This is the case
with HD Radio.
For those readers outside of these United States and Canada (actually Mexico
as well), HD Radio might be a bit unfamiliar. In Europe, for example, a
standard called DAB for Digital Audio Broadcasting is dominant and, relative
to HD radio, highly successful. Another relatively widely used digital
broadcast standard is Digital Radio Mondiale, confusingly abbreviated DRM,
which is more widely used in the short and medium wave bands than in VHF
where we find most commercial broadcasting today... but that's not a
limitation, DRM can be used in the AM and FM broadcast bands.
HD radio differs from these standards in two important ways: first, it is
intended to completely coexist with analog broadcasting due to the lack of
North American appetite to eliminate analog. Second, no one uses it.
HD Radio broadcasts have been on the air in the US since the mid '00s. HD
broadcasts are reasonably common now, with 9 HD radio carriers carrying 16
stations here in Albuquerque. Less common are HD radio receivers. Many, but not
all, modern car stereos have HD Radio support. HD receivers outside of the car
center console are vanishingly rare. Stereo receivers virtually never have HD
decoding, and due to the small size of the market standalone receivers run
surprisingly expensive. I am fairly comfortable calling HD Radio a failed
technology in terms of its low adoption, but since it falls into the broader
market of broadcast radio standards are low. We can expect HD Radio stations to
remain available well into the future and continue to offer some odd
programming.
Santa Fe's 104.1 KTEG ("The Edge"), for example, a run of the mill iHeartMedia
alt rock station, features as its HD2 "subcarrier" a station called Dance
Nation '90s. The clearly automated programming includes Haddaway's "What Is
Love" seemingly every 30 minutes and no advertising whatsoever, because it
clearly doesn't have enough listeners for any advertisers to be willing to pay
for it. And yet it keeps on broadcasting, presumably an effort by iHeartMedia
to meet programming diversity requirements while still holding multiple top-40
licenses in the Albuquerque-Santa Fe market region [1].
So what is all this HD radio stuff? What is a subcarrier? And just what makes
HD radio "Hybrid Digital?" HD Radio has gotten some press lately because of the
curious failure mode of some Mazda head units, and that's more attention than
it's gotten for years, so let's look a bit at the details.
First, HD Radio is primarily, in the US, used in a format called In-Band
On-Channel, or IBOC. The basic idea is that a conventional analog radio station
continues to broadcast while an HD Radio station is superimposed on the same
frequency. The HD Radio signal is found "outside" of the analog signal, as two
prominent sideband signals outside of the bandwidth of analog FM stereo.
While the IBOC arrangement strongly resembles a single signal with both analog
and digital components, in practice it's very common for the HD signal to be
broadcast by a separate transmitter and antenna placed near the analog
transmitter (in order to minimize destructive interference issues). This isn't
quite considered the "correct" implementation but is often cheaper since it
avoids the need to make significant changes to the existing FM broadcast
equipment... which is often surprisingly old.
It's completely possible for a radio station to transmit only an HD signal,
but because of the rarity of HD receivers this has not become popular. The FCC
does not normally permit it, and has declined to extend the few experimental
licenses that were issued for digital-only operation. As a result, we see HD
Radio basically purely in the form of IBOC. More commonly, HD Radio supports
both a full hybrid mode with conventional FM audio clarity and also an
"extended" mode in which the digital sidebands intrude on the conventional FM
bandwidth. This results in mono-only, reduced-quality FM audio, but allows
for a greater digital data rate.
HD Radio was developed and continues to be maintained by a company called
iBiquity, which was acquired by DTS, which was acquired by Xperia. iBiquity
maintains a patent pool and performs (minimal) continuing development on the
standard. iBiquity makes their revenue from a substantial up-front license fee
for radio stations to use HD Radio, and from royalties on revenue from
subcarriers. To encourage adoption, no royalties are charged on each radio
station's primary audio feed. Further encouraging adoption (although not
particularly successfully), no royalty or license fees are required to
manufacture HD Radio receivers.
The adoption of HD Radio in North America stems from an evaluation process
conducted by the FCC in which several commercial options were considered. The
other major competitor was FMeXtra, a generally similar design that was not
selected by the FCC and so languished. Because US band planning for broadcast
radio is significantly different from the European approach, DAB was not a
serious contender (it has significant limitations due to the very narrow
RF bandwidth available in Europe, a non-issue in the US where each FM radio
station was effectively allocated 200kHz).
Layer 1
The actual HD Radio protocol is known more properly as NRSC-5, for its
standards number issued by the National Radio Systems Council. The actual
NRSC-5 protocol differs somewhat depending on whether the station is AM or FM
(the widely different bandwidth characteristics of the two bands require
different digital encoding approaches). In the more common case of FM, NRSC-5
consists of a set of separate OFDM data carriers, each conveying part of
several logical channels which we will discuss later. A total of 18 OFDM
subcarriers are typically present, plus several "reference" subcarriers which
are used by receivers to detect and cancel certain types of interference.
If you are not familiar with OFDM or Orthogonal Frequency Division
Multiplexing, it is an increasingly common encoding technique that essentially
uses multiple parallel digital signals (as we see with the 18 subcarriers in
the case of HD Radio) to allow each individual signal to operate at a lower
symbol rate. This has a number of advantages, but perhaps the most important is
that it is typically used to enable the addition of a "guard interval" between
each symbol. This intentional quiet period avoids subsequent symbols "blurring
together" in the form of inter-symbol interference, a common problem with
broadcast radio systems where multipath effects result in the same signal
arriving multiple times at slight time offsets.
A variety of methods are used to encode the logical channels onto the OFDM
subcarriers, things like scrambling and convolutional coding that improve the
ability of receivers to recover the signal due to mathematics that I am far
from an expert on. The end result is that an NRSC-5 standard IBOC signal in
the FM band can convey somewhere from 50kbps to 150kbps depending on the
operator's desired tradeoffs of bitrate to power and range.
The logical channels are the interface from layer 1 of NRSC-5 to layer 2. The
number and type of logical channels depends on the band (FM or AM), the
waveform (hybrid analog and digital, analog with reduced bandwidth and digital,
or digital only), and finally the service mode, which is basically a
configuration option that allows operators to select how digital capacity is
allocated.
In the case of FM, five logical channels are supported... but not all at once.
A typical full hybrid station broadcasts only primary channel P1 and a the PIDS
channel, a low-bitrate channel for station identification. P1 operates at
approximately 98kbps. For stations using an "extended" waveform with mono FM,
the operator can select from configurations that provide 2-3 logical channels
with a total bitrate of 110kbps to 148kbps. Finally, all-digital stations can
operate in any extended service mode or at lower bitrates with different
primary channels present. Perhaps most importantly, all-digital stations can
include various combinations of secondary logical channels which can carry
yet more data.
The curious system of primary channels is one that was designed basically to
ease hardware implementation and is not very intuitive... we must remember that
when NRSC-5 was designed, embedded computing was significantly more limited.
Demodulation and decoding would have to be implemented in ASICs, and so many
aspects of the protocol were designed to ease that process. At this point it is
only important to understand that HD Radio's layer 1 can carry some combination
of 4 primary channels along with the PIDS channel, which is very low bitrate
but considered part of the primary channel feature set.
Layer 1, in summary, takes some combination of primary channels, the
low-bitrate PIDS channel, and possibly several secondary channels (only in the
case of all-digital stations) and encodes them across a set of OFDM subcarriers
arranged just outside of the FM audio bandwidth. The design of the OFDM encoding
and other features of layer 1 aid receivers in detecting and decoding this data.
Layer 2
Layer 2 operates on protocol data units or PDUs, effectively the packet of
NRSC-5. Specifically, it receives PDUs from services and then distributes them
to the layer 1 logical channels.
The services supported by NRSC are the Main Program Service or MPS which can
carry both audio (MPSA) and data (MPSD), the similar Supplemental Program
Service which also conveys audio and data, the Advanced Application Service
(AAS), and the Station Information Service (SIS).
MPS and SPS are where most of HD Radio happens. Each carries a program audio
stream along with program data that is related to the audio stream---things
like metadata of the currently playing track. These streams can go onto any
logical channel at layer 1, depending on the bitrate required and available.
An MPS stream is mandatory for an HD radio station, while an SPS is optional.
AAS is an optional feature that can be used for a variety of different
purposes, mostly various types of datacasting, which we'll examine later. And
finally, the SIS is the simplest of these services, as it has a dedicated
channel at layer 1 (the PIDS previously mentioned). As a result, layer 2 just
takes SIS PDUs and puts them directly on the layer 1 channel dedicated to them.
The most interesting part of layer 2 is the way that it muxes content together.
Rather than sending PDUs for each stream, NRSC-5 will combine multiple streams
within PDUs. This means that a PDU may contain only MPS or SPS audio, or it
might contain some combination of MPS or SPS with other types of data. While
this seems complicated, it has some convenient simplifying properties: PDUs can
be emitted for each program stream at a fixed rate based on the audio codec
rate. Any unused space in each PDU can then be used to send other types of
data, such as for AAS, on an as-available basis. The situation is somewhat
simplified for the receiver since it knows exactly when to expect PDUs
containing program audio, and that program audio is always the start of a PDU.
The MPS and one or more SPS streams, if present, are not combined together but
instead remain separate PDUs and are allocated to the logical channels in one
of several fixed schemes depending on the number of SPS present and the
broadcast configuration used by the station. In the most common configuration,
that of one logical channel on a full hybrid radio station, the MPS and up to
two SPS are multiplexed onto the single logical channel. In more complex
scenarios such as all-digital stations, the MPS and three SPS may be
multiplexed across three logical channels. Conceptually, up to seven distinct
SPS identified by a header field can be supported, although I'm not aware of
anyone actually implementing this.
It is worth discussing here some of the practical considerations around the MPS
and SPS. NRSC-5 requires that an MPS always be present, and the MPS must convey
a "program 0" which cannot be stopped and started. This is the main audio
channel on an HD radio station. The SPS, though, are used to convey
"subcarrier" [2] stations. This is the capability behind the "HD2" second audio
channel present on some HD radio stations, and it's possible, although not at
all common, to have an HD3 or even HD4.
Interestingly, the PDU "header" is not placed at the beginning of the PDU.
Instead, its 24-bit sequence (chosen off a list based on what data types are
present in the PDU) are interleaved throughout the body of the PDU. This is
intended to improve robustness by allowing the receiver to correctly determine
the PDU type even when only part of the PDU is received. PDUs always contain
mixed data in a fixed order (program data, opportunistic data, fixed data),
with a "data delimiter" sequence after the program audio and a fixed data
length value placed at the end. This assists receivers in interpreting any
partial PDUs, since they can "backtrack" from the length suffix to identify the
full fixed data section and then search further back for the "data delimiter"
to identify the full opportunistic data section.
And that's layer 2: audio, opportunistic data, and fixed data are collected for
the MPS and any SPS and/or AAS, gathered into PDUs, and then sent to layer 1 for
transmission. SID is forwarded directly to layer 1 unmodified.
Applications
NRSC-5's application layer runs on top of layer 2. Applications consist most
obviously of the MPS and SPS streams, which are used mainly to convey audio...
you know, the thing that a radio station does. This can be called the Audio
Transport application and it runs the same way whether producing MPS (remember,
this is the main audio feed) or SPS (secondary audio feeds or subcarriers).
Audio transport starts with an audio encoder, which is a proprietary design
called HDC or High-Definition Coding. HDC is a DCT-based lossy compression
algorithm which is similar to AAC but adjusted to have some useful properties
for radio. Among them, HDC receives audio data (as PCM) at a fixed rate and
then emits encoded blocks at a fixed rate---but variable size. This variable
size but fixed rate is convenient to receivers but also makes "opportunistic
data," as discussed earlier, possible, because many PDUs will have spare room
at the end.
Another useful feature of HDC is its multi-stream output. HDC can be configured
to produce two different bit streams, a "core" bit stream which is lower bitrate
but sufficient to reproduce the audio at reduced quality, and an "enhanced" data
stream that allows the reproduction of higher fidelity audio. The core bit
stream can be placed on a different layer 1 channel than the enhanced data stream,
allowing receivers to decode only one channel and still produce useful audio when
the second channel is not available due to poor reception quality. This is not
typically used by hybrid stations, instead it's a feature intended for extended
and digital-only stations.
The variable size of the audio data and variable size of PDUs creates some
complexity for receivers, so the audio transport includes some extra data about
sample rate and size to assist receivers in selecting an appropriate amount of
buffering to ensure that the program audio does not underrun despite bursts of
large audio samples and fixed data. This results in a fixed latency from
encoding to decoding, which is fairly short but still a bit behind analog
radio. This latency is sometimes apparent on receivers that attempt to
automatically select between analog and digital signals, even though stations
should delay their analog audio to match the NRSC-5 encoder.
Finally, the audio transport section of each PDU (that is, the MPS or SPS part
at the beginning) contains regular CRC checksums that are used by the receiver
to ensure that any bad audio data is discarded rather than decoded.
MPS and SPS audio is supplemented by Program Service Data (PSD), which can be
either associated with the MPS (MPSD) or an SPS (SPSD). The PSD protocol
generates PDUs which are provided to the audio transport to be incorporated
into audio PDUs at the very beginning of the MPS or SPS data. The PSD is rather
low bitrate as it receives only a small number of bytes in each PDU. This is
quite sufficient, as the PSD only serves to move small, textual metadata about
the audio. Most commonly this is the title, artist, and album, although a few
other fields are included as well such as structured metadata for
advertisements, including a field for price of the advertised deal. This
feature is rarely, if ever, used.
The PSD data is transmitted continuously in a loop, so that a receiver that has
just tuned to a station can quickly decode the PSD and display information
about whatever is being broadcast. The looping PSD data changes whenever
required, typically based on an outside system (such as a radio automation
system) sending new PSD data to the NRSC-5 encoder over a network connection.
PSD data is limited to 1024 bytes total and, as a minimum, the NRSC-5
specification requires that the title and artist fields be populated. Oddly, it
makes a half-exception for cases where no information on the audio program is
available: the artist field can be left empty, but the title field must be
populated with some fixed string. Some radio stations have added an NRSC-5
broadcast but not upgraded their radio automation to provide PSD data to the
encoder; in this case it's common to transmit the station call sign or name as
the track title, much as is the case with FM Radio Data Service.
Interestingly, the PSD data is viewed as a set of ID3 tags and, even though
very few ID3 fields are supported, it is expected that those fields be in
the correct ID3 format including version prefixes.
Perhaps the most sophisticated feature of NRSC-5 is the Advanced Application
Service transport or AAS. AAS is a flexible system intended to send just about
any data alongside the audio programs. Along with PDUs, the audio transport
generates a metadata stream indicating the length of the PDUs which is used.
The AAS can use that value to determine how many bytes are free, and then fill
them with opportunistic data of whatever type it likes. As a result, the AAS
basically takes advantage of any "slack" in the radio broadcast's capacity, as
well as reserving a portion for fixed data if desired by the station operator.
AAS data is encoded into AAS packets, an organizational unit independent of
PDUs (and included within PDUs generated by the audio transport) and loosely
based on computer networking conventions. Interestingly, AAS packets may be
fragmented or combined to fit into available space in PDUs. To account for this
variable structure, AAS specifies a transport layer below AAS packets which is
based on HDLC (ISO high-level data link control) or PPP (point-to-point
protocol, which is closely related to HDLC and very similar). So, in a way, AAS
consists of a loosely computer-network-like protocol over a protocol roughly
based on PPP over audio transport PDUs over OFDM.
Each AAS packet header specifies a sequence number for reconstruction of large
payloads and a port number, which indicates to the receiver how it should
handle the packet (or perhaps instead ignore the packet). A few ranges of
port numbers are defined, but the vast majority are left to user applications.
Port numbers are two bytes, and so there's a large number of applications
possible. Very few are defined by specification, limited basically to port
numbers for supplemental PSD. This might be a bit confusing since PSD has its
own reserved spot at the beginning of the audio transport. The PSD protocol
itself is limited to only small amounts of text, and so when desired AAS can
be used to send larger PSD-type payloads. The most common application of this
"extra PSD" is album art, which can be sent as a JPG or PNG file in the AAS
stream. In fact, multiple ports are reserved for each of MPSD (main PDS) and
SPSD, allowing different types of extra data to be sent via AAS.
Ultimately, the AAS specification is rather thin... because AAS is a highly
flexible feature that can be used in a number of ways. For example, AAS forms
the basis of the Artist Experience service which allows for delivery of more
complete metadata on musical tracks including album art. AAS can be used as
the basis of almost any datacasting application, and is applied to everything
from live traffic data to distribution of educational material to rural areas.
Finally, in our tour of applications, we should consider the station information
service or SIS. SIS is a very basic feature of NRSC-5 that allows a station to
broadcast its identification (call sign and name) along with some basic services
like a textual message related to the station and emergency alert system
messages. SIS has come up somewhat repeatedly here because it receives special
treatment; SIS is a very simple transport at a low bitrate and has its own
dedicated logical channel for easy decoding. As a result, SIS PDUs are typically
the first thing a receiver attempts to decode, and are very short and simple
in structure.
To sum up the structure of HD radio, it is perhaps useful to look at it as a
flow process: SID data is generated by the encoder and sent to layer 2 which
passes it directly to layer 1, where it is transmitted on its own logical
channel. PSD data is provided to the audio transport which embeds it at the
beginning of audio PDUs. The audio transport informs the AAS encoder of the
amount of available free space in a PDU, and the AAS encoder provides an
appropriate amount of data to the audio transport to be added at the end of the
PDU. This PDU is then passed to layer 2 which encapsulates it in a complete
NRSC-5 PDU and arranges it into logical channels which are passed to layer 1.
Layer 1 encodes the data into multiple OFDM carriers using a somewhat complex
scheme that produces a digital signal that is easy for receivers to recover.
Non-Audio Applications of NRSC-5
While the NRSC-5 specification is clearly built mostly around transporting the
main and secondary program audio, the flexibility of its data components like
PSD and AAS allows its use for purposes other than audio. As a very simple
example, SIS packets include a value called the "absolute local frame number"
or ALFN that is effectively a timestamp, useful for receivers to establish the
currency of emergency alert messages and for various data applications.
Because the current time can be easily calculated from the ALFN, it can be used
to set the clocks on HD radio receivers such as car head units. To support
this, standard SIS fields include information on local time zone, daylight
savings time, and even upcoming leap seconds.
SIS packets include a one-bit flag that indicates whether or not the ALFN is
being generated based on a GPS-locked time source, or based on the NRSC-5
encoder's internal clock only. To avoid automatically adjusting radio clocks to
an incorrect time (something that had plagued the earlier CEA protocol for
automatic setting of VCR clocks via PBS member stations), NRSC-5 dictates that
receivers must not set their display time based on a radio station's ALFN
unless the flag indicating GPS lock is set. Unfortunately, it seems that it's
rather uncommon for radio stations to equip their encoder with a GPS time
source, and so in the Albuquerque market at least HD Radio-based automatic time
setting does not work.
Other supplemental applications were included in the basic SIS as well, notably
emergency alert messages. HD Radio stations can transmit emergency alert
messages in text format with start and end times. In practice this seems to be
appreciably less successful than the more flexible capability of SiriusXM,
and ironically despite its cost to the consumer SiriusXM might have better
market penetration than HD Radio.
NRSC-5's data capabilities can be used to deliver an enhanced metadata
experience around the audio programming. The most significant implementation of
this concept is the "artist experience" service, a non-NRSC-5 standard
promulgated by the HD Radio alliance that uses the AAS to distribute more
extensive metadata including album art in image format. This is an appreciably
more complex process and so is basically expected to be implemented in software
on a general-purpose embedded operating system, rather than the hardware-driven
decoding of audio programming and basic metadata. Of course this greater
complexity lead more or less directly to the recent incident with Mazda HD
radio receivers in Seattle, triggered by a station inadvertently transmitting
invalid Artist Experience data in a way that seems to have caused the Mazda
infotainment system to crash during parsing. Fortunately infotainment-type HD
radio receivers typically store HD Radio metadata in nonvolatile memory to
improve startup time when tuning to a station, so these Mazda receivers
apparently repeatedly crashed every time they were powered on to such a degree
that it was not possible to change stations (and avoid parsing the cached
invalid file). Neat.
Since Artist Experience just sends JPG or PNG files of album art, we know that
AAS can be used to transmit files in general (and looking at the AAS protocol
you can probably easily come up with a scheme to do so). This opens the door to
"datacasting," or the use of broadcast technology to distribute computer data.
I have written on this topic
before.
To cover the elements specific to our topic, New Mexico's KANW and some other
public radio stations are experimenting with transmitting educational materials
from local school districts as part of the AAS data stream on their HD2
subcarrier. Inexpensive dedicated receivers collect these files over time and
store them on an SD card. These receiver devices also act as WiFi APs and offer
the stored contents via an embedded web server. This allows the substantial
population of individuals with phones, tablets, or laptops but no home internet
or cellular service to retrieve their distance education materials at home,
without having to drive into town for cellular service (the existing practice
in many parts of the Navajo Nation, for example) [3].
There is potential to use HD Radio to broadcast traffic information services,
weather information, and other types of data useful to car navigation systems.
While there's a long history of datacasting this kind of information via radio,
it was never especially successful and the need has mostly been obsoleted by
ubiquitous LTE connectivity. In any case, the enduring market for this type of
service (over-the-road truckers for example) has a very high level of SiriusXM
penetration and so already receives this type of data.
Fall of the House of Hybrid Digital
In fact, the satellite angle is too big to ignore in an overall discussion of
HD Radio. Satellite radio was introduced to the US at much the same time as HD
Radio, although XM proper was on the market slightly earlier. Satellite has the
significant downside of a monthly subscription fee. However, time seems to have
shown that the meaningful market for enhanced broadcast radio consists mostly
of people who are perfectly willing to pay a $20/mo subscription for a
meaningful better service. Moreover, it consists heavily of people involved in
the transportation industry (Americans listen to the radio basically only in
vehicles, so it makes sense that the most dedicated radio listeners are those
who spend many hours in motion). Since many of these people regularly travel
across state lines, a nationwide service is considerably more useful than one
where they have to hunt for a new good station to listen to as they pass
through each urban area.
All in all, HD radio is not really competitive for today's serious radio
listeners because it fails to address their biggest complaint, that radio is
too local. Moreover, SiriusXM's ongoing subscription revenue seems to provide a
much stronger incentive to quality than iHeartMedia's declining advertising
relationships [4]. The result is that, for the most part, the quality of
SiriusXM programming is noticeably better than most commercial radio stations,
giving it a further edge over HD Radio.
Perhaps HD Radio is simply a case of poor product-market fit, SiriusXM having
solved essentially the same problems but much better. Perhaps the decline of
broadcast media never really gave it a chance. The technology is quite
interesting, but adoption is essentially limited to car stereos, and not even
that many of them. I suppose that's the problem with broadcast radio in
general, though.
[1] The details here are complex and deserve their own post, but as a general
idea the FCC attempts to maintain a diversity of radio programming in each
market by refusing licenses to stations proposing a format that is already used
by other stations. Unfortunately there are relatively few radio formats that
are profitable to operate, so the broadcasting conglomerates tend to end up
playing games with operating stations in minor formats, at little profit, in
order to argue to the FCC that enough programming diversity is available to
justify another top 40 or "urban" station.
[2] The term "subcarrier" is used this way basically for historical reasons and
doesn't really make any technical sense. It's better to think of "HD2" as being
a subchannel or secondary channel, but because of the long history of radio
stations using actual subcarrier methods to convey an alternate audio stream
the subcarrier term is stuck.
[3] It seems inevitable that, as has frequently happened in the history of
datacasting, improving internet access technology will eventually obsolete this
concept. I would strongly caution you against thinking this has already
happened, though: even ignoring the issue of the long and somewhat undefined
wait, Starlink is considerably more expensive than the typical rates for rural
internet service in New Mexico. It is to some extent a false dichotomy to say
that Starlink is cost uncompetitive with DSL considering that it can service a
much greater area. However, I think a lot of "city folk" are used to the
over-$100-per-month pricing typical of urban gigabit service and so view
Starlink as inexpensive. They do not realize that, for all the downsides of
rural DSL, it is very cheap. This reflects the tight budget of its consumers.
For those who have access, CenturyLink DSL in New Mexico ranch country is
typically $45/mo no-contract with no install fee and many customers use a
$10/mo subsidized rate for low income households. Starlink's $99/mo and $500
initial is simply unaffordable in this market, especially since those outside
of the CenturyLink service area have, on average, an even lower disposable
income than those clustered near towns and highways.
[4] It is hard for me not to feel like iHeartMedia brought this upon
themselves. They gained essentially complete control of the radio industry
(with only even sadder Cumulus as a major competitor) and then squeezed it for
revenue until US commercial radio programming had become, essentially, a joke.
Modern commercial radio stations run on exceptionally tight budgets that have
mostly eliminated any type of advantage they might have had due to their
locality. This is most painfully apparent when you hear an iHeartMedia station
give a rare traffic update (they seem to view this today as a mostly pro forma
activity and do it as little as possible) in which the announcer pronounces
"Montaño" and, more puzzlingly, "Coors" wrong in the span of a single sentence.
I have heard a rumor that all of the iHeartMedia traffic announcements are done
centrally from perhaps Salt Lake City but I do not know if this is true.
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.