The terms "on" and "off" are used in describing British railway signals. When describing an older semaphore, "on" refers to a signal arm in the horizontal position, and "off" means a signal raised upwards or lowered downwards from pivot point (at up to 60°). With regard to newer colour-light signals, "on" is synonymous with the most restrictive aspect, while all other aspects are considered to be "off". A way to remember this is to refer to the state of the red light, or yellow light if the signal is a distant and incapable of displaying a red aspect. If it is lit, the signal is "on", and if the red light is unlit, the signal is "off".
Semaphore signals Image:Signal Home Semaphore R & G.svg|Semaphore stop signal (lower quadrant type) Image:Signal Distant Semaphore Y & G.svg|Semaphore distant signal (lower quadrant type) Image:British home and distant railway semaphore RYG signals.svg|Combined semaphore stop and distant signals (lower quadrant type) The traditional British signal is the
semaphore, comprising a mechanical arm that rises or drops to indicate 'clear' (termed an "upper-quadrant" or "lower-quadrant" signal, respectively). Both types are
fail-safe in the event of breakage of the operating pull-wire but lower-quadrant signals require a heavy counterweight with push-pull rod between counterweight and arm linkage (generally assisted by the "spectacle" that carries the coloured lenses for use at night) to do that, while upper-quadrant signals fall back to "danger" under the weight of the arm. During the 1870s, almost all the British railway companies standardised on the use of semaphore signals, which were then invariably of the lower quadrant type. From the 1920s onwards, upper quadrant semaphores almost totally supplanted lower quadrant signals in Great Britain, except on former
GWR lines and their succession to BR(WR) and latterly Network Rail Western Zone. There are two main types of semaphore; stop and distant. The stop signal consists of a red, square-ended arm, with a vertical white stripe typically 9-12 inches (230–300 mm) from the end, and advises the driver whether the line immediately ahead is clear or not. A stop signal must not be passed in the horizontal "on" (danger) position, except where specially authorised by the signaller's instruction. By night, it shows a red light when "on" and a green light when "off" (clear). The green light is usually produced through the use of a blue spectacle lens, which produces green when lit from behind by the yellowish flame from a paraffin lamp. The other type is the distant signal, which has a yellow arm with a 'V' ("fishtail") notch cut out of the end and a black chevron typically 9-12 inches (230–300 mm) from the end. Its purpose is to advise the driver of the state of the following stop signal(s); it may be passed in the "on" position, but the driver must slow their train to be able to stop at the next stop signal. When "off", a distant signal tells the driver that all the following stop signals of the signal box (and/or until the next distant) are also "off", and when "on" tells the driver that one or more of these signals is likely to be at danger. By night, it shows a yellow light when "on" and a green light when "off". On many branch lines and short block sections, a distant signal was often fixed at 'Caution', standalone or mounted below a Stop semaphore, and so exhibited only a yellow light at night. Where a signal consists of a combination of a stop and distant arms a mechanism is included to prevent the distant arm clearing while the stop arm is at ‘danger’. Current British practice mandates that semaphore signals, both upper and lower quadrant types, are inclined at an angle of 45 degrees from horizontal to display an "off" indication.
Colour light signals In total, colour-light signals in the UK display seven aspects. These are: • Green –
Clear. The train may proceed subject to any speed restrictions applying to the section of line or to the train itself. (See also Flashing Green below.) • Double yellow –
Preliminary caution. The next signal is displaying a single yellow aspect. • Flashing double yellow - indicates that the next signal is showing flashing yellow. • Single yellow –
Caution. The driver must prepare to stop the train at the next signal. • Flashing single yellow - warns that a diverging route is set. The next signal will be a steady single yellow with a junction indicator. • Red –
Danger/Stop. Additionally, on the trial section of line between Peterborough and York: • Flashing Green - the train may proceed at line speed. Where this aspect is in use, the steady green aspect means that the next signal shows double yellow. The green aspect and the four yellow aspects are known as 'proceed aspects', as they allow the train to pass the signal; the red aspect
requires the train to stop. Two-aspect systems use red and green only. Three-aspect systems include yellow. Four-aspect signalling, which also includes double yellow, is mostly used on busy routes to allow shorter headways, and on fast routes to provide longer braking distances.
Flashing yellow aspects A flashing single or double yellow aspect indicates that a train is to take a diverging route ahead with a lower line speed than the main route. A flashing double yellow (only used in 4-aspect signalling) means that the next signal is showing flashing single yellow. A flashing single yellow means that the next signal at the junction is showing (steady) single yellow with an indication for a diverging route, and the signal beyond the junction is at danger (red). This sequence of increasingly restrictive aspects forces the driver to slow the train down in preparation for stopping at the red signal, and this ensures that the train crosses the junction at the appropriate speed. As the train nears the junction, the red signal beyond may 'step up' to a less restrictive aspect depending on the state of the line ahead. The two yellows in a flashing double-yellow flash in unison rather than alternately, but the flashing double-yellow and single-yellows are not synchronised. Flashing yellow signalling contains an additional safety vital relay typically referred to as Flashing Lamp Proving Relay (FECR) – this changes over the supply for the yellow signal transformers at each signal where flashing aspects are provided from a steady 110Va.c. to a "flashing" supply switched on and off at about 1.2 Hz or 70–72 c.p.m., once the junction points have been set, locked and detected correctly for the lower–speed divergence. This supply has to be specially provided, either from the power–box or control centre, or by a specially designed signal control module in more modern LED installations. The increased complexity in providing flashing aspects prior to the introduction of
solid state interlocking resulted in more stringent criteria for the use of flashing aspects in earlier installations.
Failures If a signal is to malfunction and not show any aspect, the driver is required to treat the blank signal as if it was red and contact the signaller. A failure of the changeover relay to switch on the flashing indication to the double-yellow aspect would not be a problem as it is considered that a steady double-yellow followed by a flashing single-yellow aspect sequence is acceptable. However, safety circuitry is connected to the single-yellow flashing supply to ensure that a failure of the single-yellow to change over to the flashing supply would abort the "approach release from yellow" sequence and re-impose the normal "approach control from red" sequence as failure of the single yellow to flash following a flashing double-yellow is considered potentially very dangerous.
Lens placement and alignment The design considerations determining the familiar arrangement of
roadway 'traffic signals', with red at the top, do not apply to the railway. In particular, there is no risk that a signal will be masked by a tall vehicle in front of the driver. Furthermore, to position the red aspect at the lowest position may reduce risk of obscuring of that lens by heavy snow or ice. There are standard arrangements of the lights, however unusual variations, such as horizontal mounting is allowed when demanded by local conditions or geography, such as in tunnels, areas of limited clearance, or the presence of bridges over the railway. On pole- and gantry-mounted railway signals the most restrictive aspect is usually the lowest of the principal aspects. These have a single lamp in front of which is placed either a red, yellow, or green filter to show the respective aspect. The filter assembly is moved by an electro-magnet. For a double-yellow aspect a second lamp is fitted, illuminated only when required. A few traditional searchlight signals (i.e. with moving filter glasses inside) remain in use in the
Clacton area. These fell out of favour by the 1960s, being replaced by the multi-lens vertically arranged signals, with searchlight style signals only being allowed in circumstances where the signal lens would allow better signal sighting due to a physical obstructions to sight lines. By 1991, the use of searchlight signals in any future installation was prohibited. When junction indicators are fitted, they are typically placed above the principal aspects of a signal. Signal positioning guidance aims for a signal to be understood by a driver at a distance between from the signal, with no obstructions within and at a height of above the left-hand rail. Signals are positioned from the inside edge of the left-hand rail. Right-hand signals are used in situations where local conditions make a left-hand placement unsuitable. Ground mounted signals are rarely so critical for alignment (an advantage of ground mounting) and are often used in tunnels, where the relative luminosity of the aspects is much higher.
Unusual colour light aspects . • Flashing green – flashing green aspects are employed on the
East Coast Main Line north of
Peterborough. They were installed for 140 mph (225 km/h) running in connection with the testing of the new
InterCity 225 electric trains, with a steady green limiting test trains to the normal speed limit of 125 mph (200 km/h). They no longer have official meaning, but remain in place and there are a couple of locations where the presence or absence of flashing provides useful information to drivers. • Splitting distants – at some locations approaching a junction two heads are placed side by side. When this signal or the junction signal is at danger, one head is dark and the other shows red or single yellow. When the junction signal is not at danger, both heads show an aspect: the one for the route set ahead of the junction (left or right) shows the correct aspect while the other shows single yellow (or double yellow at an "outer splitting distant"). • Green over yellow, or green over green – the
Liverpool Loop Line and
London Underground use separate red/green "stop" and yellow/green "repeater" signals. If a repeater signal is at the same location as a stop signal, it is placed underneath it and lit only when the stop signal is green. Thus the order of the heads is (from top to bottom) green, red, green, yellow, and aspects are red, green over yellow, and green over green. • Yellow over green – this was used in the experimental "speed signalling" at Mirfield to provide an additional caution. It meant that the next signal was showing double yellow. It was discontinued in 1970.
Approach release At certain locations such as the final signal on approach to a terminus station or at a diverging route requiring a large speed reduction, approach release (also known as approach control) may be used. The driver will be "checked down" with a normal signalling sequence (green, double yellow, yellow for a four-aspect area) and the red signal clears when it is proven that the approaching train must have slowed to an appropriate speed for the conditions ahead. Typically for low speed junctions (e.g. crossover on a line), the train will be brought down to nearly standing at the signal before it clears. Approach control is achieved by maintaining the signal at danger until the approach track circuit has been occupied for a specified period of time. After the track circuit has been occupied for the specified period of time, the signal is allowed to "step-up" to the highest available aspect and display the junction indicator where applicable. The length of time required varies on the design of the installation. Where a junction indicator is used an additional safety precaution ensures that failure of the indicator does not cause an irregular or mutilated display to appear. This can be observed in practice – at Bescot Stadium northbound the signal, when cleared for the divergence for Walsall-bound trains, shows the junction-indicator with a red aspect for 2–3 seconds before the main aspect clears – this is whilst the interlocking proves sufficient elements of the junction-indicator are lit before clearing the main aspect. With route relay interlocking the proving circuitry for the junction indicator is housed locally. With a solid state or computerised signalling this proof has to pass to the main interlocking, hence the additional delay in proving that the junction indicator is lit prior to clearing the main signal.
Delayed Yellow Operation In the Absolute Block Signalling System, the signalling regulations provide for trains to be signalled into a section of line where the designated "overlap" past the signal is not clear – the signaller keeps the signal concerned at danger until the train has come to a stand at it, and then the driver must be warned verbally by the signaller that the line is not clear the whole distance to the next signal, then once the signaller is satisfied the driver has understood the warning, they will typically pull off the signal very slowly – the driver understands from this that they are being accepted into the occupied length of line under "Warning" Regulation 4. In colour light power box operated areas, the "home" signal where "warning" arrangements are in force has a time release similar to approach control from red but the control is more stringent – the signal only clears when the speed of the train is detected to be less than 10 mph and only clearance to single yellow is allowed – this is called delayed yellow operation, and is often found at the approach to large stations where two trains may use one platform. == Subsidiary signals ==