Continuous Tone-Coded Squelch System

In telecommunications, Continuous Tone-Coded Squelch System or CTCSS is a circuit that is used to reduce the annoyance of listening to other users on a shared two-way radio communications channel. It is sometimes referred to as tone squelch or sub-channel since it has the effect of creating multiple virtual channels which are all using the same radio frequency. It does this by superimposing an extra audio tone over the voice transmission on a channel which can be heard by the radio circuitry but not by the human ear. Where more than one group of users is on the same radio frequency (called co-channel users), CTCSS circuitry mutes those users who are using a different CTCSS tone or no CTCSS.

Receivers equipped with a CTCSS circuit usually have a switch that selects normal mode or CTCSS mode. When enabled, the CTCSS radio circuit, instead of unmuting the receive audio for any signal, causes the two-way radio receiver's audio to open only in the presence of the normal RF signal and the correct sub-audible audio tone (sub-audible meaning that the receiver circuitry can detect it, but is not apparent to the users in the audio output). A carrier squelch or noise squelch receiver not configured with CTCSS will receive any signal. A receiver with CTCSS circuitry (and with it enabled) locks out all signals except ones encoded with the correct tone. CTCSS can be regarded as a form of in-band signalling.

Example

As a simple example, suppose a two-way radio frequency is shared by a pizza delivery service and a landscape maintenance service. Conventional radios without CTCSS would hear all transmissions from both groups. The landscapers would have to listen to the pizza shop. The pizza shop would have to hear about landscape customer complaints. If both installed CTCSS, units from each group would only hear radios from their own group. This is supposed to reduce missed messages and the distraction of unnecessary radio chatter.

Note that in the example above there are only two co-channel users. In dense two-way radio environments a large number of groups may be present on a single radio channel.

A disadvantage of using CTCSS in shared frequencies is that since users cannot hear transmissions from other groups, they may assume that the frequency is open when it is not and transmit simultaneously with another user, thus accidentally overriding or interfering with the other group's transmission. For example, in the above situation a landscaper might be communicating with another landscaper. Meanwhile, a pizza delivery driver—not hearing any transmissions—assumes that the frequency is clear and calls his dispatch office. Depending on several factors (locations, power, etc.), the two simultaneous transmissions could easily interfere with each other—resulting in one or both not being clearly understood. The more separate groups that share a single frequency and the more frequently that they transmit, the more likely that this accidental interference will occur. Radios with a "Busy Channel Lockout" feature will prevent transmitting in this case.

Theory of operation

Radios in a professional two-way radio system using CTCSS always transmit their own tone code whenever the transmit button is pressed (the tone is transmitted at a low level simultaneously with the voice). This is called CTCSS encoding. CTCSS continuously superimposes any one of 32, 38 or as many as 50 (depending on which "standard" is used) precise, very low distortion, low-pitched audio tones on the transmitted signal, ranging from 67 to 257 Hz. The tones are usually referred to as sub-audible tones. In an FM two-way radio system, CTCSS encoder levels are usually set for 15% of system deviation. For example, in a 5 kHz deviation system, the CTCSS tone level would normally be set to 750 Hz deviation. Engineered systems may call for different level settings in the 500 Hz to 1 kHz (10–20%) range.

The ability of a receiver to mute the audio until it detects a carrier with the correct CTCSS tone is called decoding. Receivers are equipped with features to allow the CTCSS "lock" to be disabled. In USA licensed systems, Federal Communications Commission rules require CTCSS users on shared channels to disable their receiver's CTCSS to check if co-channel users are talking before transmitting. On a base station console, a microphone may have a split push-to-talk button. Pressing one half of the button, (often marked with a speaker icon or the letters "MON", short for "MONitor") disables the CTCSS decoder and reverts the receiver to hearing any signal on the channel. This is called the monitor function. There is sometimes a mechanical interlock: the user must push down and hold the monitor button or the transmit button is locked and cannot be pressed. This interlock option is referred to as compulsory monitor before transmit (the user is forced to monitor by the equipment design.) On mobile radios, the microphone is usually stored in a hang-up clip or hang-up box. When the user pulls the microphone out of the hang-up clip to make a call, a switch in the clip (box) forces the receiver to revert to conventional carrier squelch mode ("monitor"). Some designs relocate the switch into the body of the microphone itself. In hand-held radios, an LED indicator may glow green, yellow, or orange to indicate another user is talking on the channel. Hand-held radios usually have a switch or push-button to monitor. Some modern radios have a feature called "Busy Channel Lockout", which will not allow the user to transmit as long as the radio is receiving another signal.

A CTCSS decoder is based on a very narrow bandpass filter which passes the desired CTCSS tone. The filter's output is amplified and rectified, creating a DC voltage whenever the desired tone is present. The DC voltage is used to turn on, enable or unmute the receiver's speaker audio stages. When the tone is present, the receiver is unmuted, when it is not present the receiver is silent.

In a communications receiver designed for CTCSS, a high-pass audio filter is supposed to block CTCSS tones (below 300 Hz) so they are not heard in the speaker. Since audio curves vary from one receiver to another, some radios may pass an audible level of the CTCSS tone to the speaker. Lower tone frequencies generally are less audible. If the magenta audio curve shown at right were plotted from a CTCSS-equipped receiver, it would drop nearly straight down below 300 Hz.

Because period is the inverse of frequency, lower tone frequencies can take longer to decode (depends on the decoder design). Receivers in a system using 67.0 Hz can take noticeably longer to decode than ones using 203.5 Hz, and they can take longer than one decoding 250.3 Hz. In some repeater systems, the time lag can be significant. The lower tone may cause one or two syllables to be clipped before the receiver audio is unmuted (is heard). This is because receivers are decoding in a chain. The repeater receiver must first sense the carrier signal on the input, then decode the CTCSS tone. When that occurs, the system transmitter turns on, encoding the CTCSS tone on its carrier signal (the output frequency). All radios in the system start decoding after they sense a carrier signal then recognize the tone on the carrier as valid. Any distortion on the encoded tone will also affect the decoding time.

Engineered systems often use tones in the 127.3 Hz to 162.2 Hz range to balance fast decoding with keeping the tones out of the audible part of the receive audio. Most amateur radio repeater controller manufacturers offer an audio delay option—this delays the repeated speech audio for a selectable number of milliseconds before it is retransmitted. During this fixed delay period (the amount of which is adjusted during installation, then locked down), the CTCSS decoder has enough time to recognize the right tone. This way the problem with lost syllables at the beginning of a transmission can be overcome without having to use higher frequency tones.

In early systems, it was common to avoid the use of adjacent tones. On channels where every available tone is not in use, this is good engineering practice. For example, an ideal would be to avoid using 97.4 Hz and 100.0 Hz on the same channel. The tones are so close that some decoders may periodically false trigger. The user occasionally hears a syllable or two of co-channel users on a different CTCSS tone talking. As electronic components age, or through production variances, some radios in a system may be better than others at rejecting nearby tone frequencies.

Digital-Coded Squelch

Main article: Digital-Coded Squelch

CTCSS is an analog system. A later Digital-Coded Squelch (DCS) system was developed by Motorola under the trademarked name Digital Private Line (DPL). General Electric responded with the same system under the name of Digital Channel Guard (DCG). The generic name is CDCSS (Continuous Digital-Coded Squelch System). The use of digital squelch on a channel that has existing tone squelch users precludes the use of the 131.8 and 136.5 Hz tones as the digital bit rate is 134.4 bits per second and the decoders set to those two tones will sense an intermittent signal (referred to in the two-way radio field as "falsing" the decoder).[1]

List of tones

CTCSS tones are standardized by the EIA/TIA. The full list of the tones can be found in their original standard RS-220A,[2] and the more recent EIA/TIA-603D Standard;[3] the CTCSS tones also may be listed in manufacturers instruction, maintenance or operational manuals. Some systems use non-standard tones.[4] The NATO Military radios use 150.0 Hz, and this can be found in the user manuals for the radios. Some areas do not use certain tones, for example the tone of 100.0 Hz is avoided in the United Kingdom since this is twice the UK mains power line frequency; an inadequately smoothed power supply may cause unwanted squelch opening (this is true in many other areas that use 50 Hz power). Squelch tones typically come from one of three series as listed below along with the two character PL code used by Motorola to identify tones. The most common set of supported squelch tones is a set of 38 tones including all tones with Motorola PL codes, except for the tones WZ, 8Z, 9Z, and 0Z (zero-Z).[5] The lowest series has adjacent tones that are roughly in the harmonic ratio of 20.05 to 1 (≈1.035265), while the other two series have adjacent tones roughly in the ratio of 100.015 to 1 (≈1.035142). An example technical description can be found in a Philips technical information sheet about their CTCSS products.[6]

NS [1] PL Hz
1 XZ 67.0
WZ 69.3 [2]
2 XA 71.9
3 WA 74.4
4 XB 77.0
5 WB 79.7 [3]
6 YZ 82.5
7 YA 85.4
8 YB 88.5
9 ZZ 91.5
10 ZA 94.8
11 ZB 97.4 [4]
12 1Z 100.0
13 1A 103.5
14 1B 107.2
15 2Z 110.9
16 2A 114.8
17 2B 118.8
NS [1] PL Hz
18 3Z 123.0
19 3A 127.3
20 3B 131.8
21 4Z 136.5
22 4A 141.3
23 4B 146.2
NATO 150.0 [5]
24 5Z 151.4
25 5A 156.7
26 5B 162.2
27 6Z 167.9
28 6A 173.8
29 6B 179.9
30 7Z 186.2
31 7A 192.8
199.5
8Z 206.5 [6]
213.8 [7]
221.3 [7]
NS [1] PL Hz
9Z 229.1 [6]
237.1 [7]
245.5 [7]
0Z 254.1 [6]
159.8
165.5
171.3
177.3
183.5
189.9
196.6
32 M1 203.5
33 M2 210.7
34 M3 218.1
35 M4 225.7
36 M5 233.6
37 M6 241.8
38 M7 250.3

Notes

Vendor names

CTCSS is often called PL tone (for Private Line, a trademark of Motorola), or simply tone. General Electric's and Bendix King's implementation of CTCSS is called Channel Guard (or CG). Vintage RCA radios called their implementation Quiet Channel. Icom radios call this feature C.Tone. Kenwood radios call the feature Quiet Talk or QT. E. F. Johnson Corp. used "TG" for "ToneGuard", and later "CG" for "CallGuard". Zetron literature refers to "ToneLock", and Ritron, Inc. labels their implementations "Quiet Call" (QC) and "Digital Quiet Call" (DQC). There are many other company-specific names used by radio vendors to describe compatible options. Any CTCSS system that has compatible tones and levels is interchangeable. Old and new radios with CTCSS and radios across manufacturers are compatible.

In amateur radio, the terms PL tone, PL and simply tone are still used somewhat commonly. Often, there is a distinction between the terms tone and tone squelch, in which the former refers to the use of transmitting a CTCSS tone while using standard carrier squelch on the receiver. Use of transmit-only CTCSS allows stations to communicate with repeaters and other stations using CTCSS while the link is marginal and the CTCSS tones may not be properly decoded. The term tone squelch most often includes tone and the radio will not only transmit a CTCSS tone to the distant station or repeater, but will squelch all incoming signals that do not also include the CTCSS tone. This is helpful in areas where multiple repeaters may be sharing the same output frequency but have different CTCSS tones, or where local interference is too strong for the front-end of your radio.

Reverse CTCSS

Some professional systems use a phase-reversal of the CTCSS tone at the end of a transmission to eliminate the squelch crash or squelch tail. This is common with General Electric Mobile Radio and Motorola systems. When the user releases his push-to-talk button the CTCSS tone does a phase shift for about 200 milliseconds. In older systems, the tone decoders used mechanical reeds to decode CTCSS tones. When audio at a resonant pitch was fed into the reed, it would resonate / vibrate, which would turn on the speaker audio. The end-of-transmission phase reversal (called "reverse burst" by Motorola and "squelch tail elimination" or "STE" by GE [7]) caused the reed to abruptly stop vibrating which would cause the receive audio to mute. Initially, a phase shift of 180 degrees was used, but experience showed that a shift of ±120 to 135 degrees was optimal in halting the mechanical reeds. These systems often have audio muting logic set for CTCSS only. If a transmitter without the phase reversal feature is used, the squelch can remain unmuted for as long as the reed continues to vibrate—up to 1.5 seconds at the end of a transmission as it coasts to a stop (sometimes referred to as the "flywheel effect" or called "freewheeling"). Thus, there is one caveat about all CTCSS being interchangeable—the phase changing system must exist, and the shift angle must match. Note that the hardware used to implement the "reverse burst" / "squelch tail elimination" system is all contained in the transmitter.

Interference and CTCSS

In non-critical uses, CTCSS can also be used to hide the presence of interfering signals such as receiver-produced intermodulation. Receivers with poor specifications—such as scanners or low-cost mobile radios—cannot reject the strong signals present in urban environments. The interference will still be present and may block the receiver, but the decoder will prevent it from being heard. It will still degrade system performance but the user will not have to hear the noises produced by receiving the interference.

CTCSS is very commonly used in amateur radio for this purpose. Wideband and extremely sensitive radios are common in the amateur radio field, which imposes limits on achievable intermodulation and adjacent-channel performance. Often all repeaters in a geographical region share the same CTCSS tone as a method of reducing co-channel interference from adjacent regions and increasing frequency reuse. This is a practice linked back to an old FCC practice of coordinating CTCSS tones for business services. In many rural areas of the USA where no coordination is necessary, a default of 100 Hz has become a de facto standard.

Family Radio Service (FRS), PMR446 and other consumer-grade "bubble pack" radios often include a feature called "Interference Eliminator Codes", "sub-channels", or "privacy codes"—the latter two being especially misleading as, contrary to what sales literature may say, they do not afford privacy or security, but serve only to reduce annoying interference by other users or other noise sources; a receiver with the tone squelch turned off (e.g., frequently done by selecting code "0") will hear everything on the channel. GMRS/FRS radios offering CTCSS codes typically provide a choice of 38 tones,[8] but the tone number and the tone frequencies used may vary from one manufacturer to another (or even within product lines of one manufacturer) and should not be assumed to be consistent (i.e. "Tone 12" in one set of radios may not be "Tone 12" in another). When a radio offers more than 50 codes (121 is becoming common), the higher ones (e.g. 39–121) are usually DCS codes.

It is a bad idea to use any coded squelch system to hide interference issues in systems with life-safety or public-safety uses such as police, fire, search and rescue or ambulance company dispatching. Adding tone or digital squelch to a radio system doesn't solve interference issues, it just covers them up. The presence of interfering signals should be corrected rather than masked. Interfering signals masked by tone squelch will produce apparently random missed messages. The intermittent nature of interfering signals will make the problem difficult to reproduce and troubleshoot. Users will not understand why they cannot hear a call, and will lose confidence in their radio system. In a worst-case scenario in a life safety environment a missed message, or a misunderstood message, may result in fatalities.

Using coded squelch systems can prevent weak signals from being received, for example, when the person transmitting or receiving is in an area obstructed by buildings or terrain or is a long distance away. A well tuned receiver that isn't configured to require CTCSS or DCS tones to open the squelch might still carry the weak message along with static noise, while a coded squelch enabled receiver may not perceive the tones and will ignore the message entirely.

See also

Notes

  1. Mike Morris WA6ILQ (29 January 2013), A Historical and Technical Overview of Tone Squelch Systems, retrieved 2013-03-06
  2. EIA Standard RS-220-A, Continuous Tone-Controlled Squelch Systems (CTCSS). March 1979.
  3. "Land Mobile FM or PM Communications Equipment Measurement and Performance Standards (abstract)" (PDF). Retrieved 2015-05-02.
  4. List of non-standard CTCSS codes
  5. CTCSS Compatibility in FRS Radios
  6. "Information Sheet: Continuous Tone Controlled Squelch System" (PDF). Retrieved 2015-05-02.
  7. Explanation of Reverse Burst & "And Squelch" - Kevin K. Custer W3KKC
  8. Robert H. Eisner (23 July 1999), CTCSS Compatibility in FRS Radios, retrieved 2014-08-06
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