Post Instrument



The Post Plotting Instrument, or simply Post Instrument, was the standard optical sighting system used by the British Royal Observer Corps (ROC) to determine the location of aircraft before and during World War II. There were two versions, a pre-war model using a pantograph and a wartime version of somewhat more sophistication. Both models worked by estimating the altitude of the aircraft, pointing an indicator at it, and then looking down at a pointer positioned over a small circular map with the Ordnance Survey National Grid on it. Later models added the Micklethwait Height Corrector which allowed the posts to measure altitude with some accuracy. The ROC operators would then report this information to their observer centers, who would in turn report this into the Dowding system reporting chain.

Background
Prior to the introduction of radar, optical tracking systems of widely varying complexity were commonly used to spot and report aircraft positions. The Post Instrument was intended to be at the simple end of the scale, an inexpensive and easy to use instrument to make rough but rapid measurements of the locations of formations of aircraft.

They were installed at hundreds of observation posts across the UK, typically in small groups about 3 to 5 miles apart, that allowed the operators to cross check each other's altitude measurements. Each post was normally manned by two or three operators, one operating the Post Instrument, another using the telephone to report the locations to a plotting center, and the third, if present, operating as a lookout and helper.

Pre-war model
The original Post Instrument was supported by a metal rod extending vertically from the center of a circular table. A small section of map showing the surrounding area was attached to the tabletop.

The instrument itself consisted of an open rectangle made of metal bars with hinges at each corner, allowing it to rotate to form various parallelograms. Similar hinges were located at the midpoints of the long bars of the rectangle, which formed the horizontal axis. These midpoint pivots connected to the vertical bar on the table, producing a pantograph that could be rotated vertically to point upward at the aircraft, sighting along the upper bar.

A final piece was a separate vertical bar connected to the two horizontals and pivoted in the same way so that it remained pointing vertically as the horizontal bars were rotated vertically. This bar was able to be moved along the horizontal bars, fore and aft, which was used to adjust the estimated altitude.

To use the system, the operator would first estimate the altitude of the target aircraft and then move the smaller pointer to set that altitude as measured against a scale on the upper horizontal arm. They would then rotate the apparatus around the vertical shaft so the target aircraft lay along the line of the upper bar, and then rotate the bar vertically until it pointed at the aircraft. The vertical pointer now pointed to a grid location on the map, which could be read off to the reporting center.

Wartime model
The original model worked, but was somewhat difficult and time consuming to use. Just prior to the war a new version was introduced that was easier to use. Officially known as the Observer Instrument, Mark 2, it was built by R.B. Pullin & Co., starting in 1934.

The vertical rod of the original version was replaced by a horizontal framework, roughly T-shaped, that was suspended above the table on three wheels running on a metal track around the rim of the map. This provided a much more robust framework for holding the sighting system, and could be smoothly rotated. A pointer behind the front wheel made it easy to read off the bearing, when required. Travelling along the framework horizontally fore and aft was a sliding mechanism that held the sights. This formed the altitude adjustment that would be set prior to sighting. The map pointer was connected to the bottom of the slider.

The sights, in the form of an open-framework tube containing a crosshairs, was mounted to the horizontal slider on a vertical square tube. Sightings could be taken either through the crosshairs or along open sights on the top of the tube. A geared rack running down the back of the tube held the sights at a selected angle, and the angle was adjusted by rotating a geared knob on the right side of the sights. As the sights were rotated upwards, they forced the horizontal slider to the rear, moving the pointer over the map.

Micklethwait Height Corrector


Wartime models were modified in 1940 with the Micklethwait Height Corrector, named for its inventor, Eric Walter Eustace Micklethwait. Micklethwait was an observer at the Gower Street Post on the roof of a building at University of London, near Euston Square tube station. Formerly a patent clerk, he devised the Corrector and quickly patented it.

The Corrector consisted of a second map pointer on a second horizontal slider, along with a short vertical bar marked with altitude corrections. A second arm suspended from the main sight tube was read against the vertical bar. Two or more posts had to work in concert to use the system, using two measured angles and simple trigonometry to solve the altitude.

The simplest measurement took place when an aircraft flew directly over one of the posts. Other posts that could see the same aircraft would continue to track the target as normal, set to whatever altitude they had initially estimated. When the first post called that the aircraft was directly overhead, the other posts would crank the Corrector until its pointer lay over a marking for the other post printed on the map.

For instance, if the original estimate was 10000 feet and the aircraft was actually at 11000 feet, the operator at a second post would set his instrument to 10,000 and continue to measure as normal until they heard the first post call "aircraft overhead". At this point they would stop measuring the aircraft and instead crank the Corrector until its pointer lay over the marking on the map indicating the location of the first post. By comparing the position of the bar suspended from the sighting tube to the Corrector's vertical scale, they would see it indicate +1000. All the posts in the area would then update their altitude settings to 11,000 feet.

When the target did not pass directly over a post the calculation was somewhat more complex. In this case two posts would measure the location of the aircraft at the same time, and then one would call its grid reference to the other. The second would then place a ruler on the map lying along the line from their location on the map to the grid location called in. This would not normally be the same direction as the instrument itself. They would then move the Corrector until it lay directly above the nearest point on the ruler, and the correction could then be read off as normal.

An alternate procedure involved the use of an operator at the observer center. Gathering indicated grid locations from several sites set to the same arbitrary altitude, they would triangulate the grid location of the target and pass this information back to the posts. The operators at the posts would then crank the Corrector until its pointer lay over the calculated grid location, at which point the correction could be read. This would be reported back to the center, who would then report the average correction to all the posts.

Sound measures
The Post Instrument was introduced in an era when sound locating was still common, and some techniques for measuring the angle by sound were developed. This basically consisted of moving the horizontal slider until the indicator pointer was over the "sound line", a circle on the map representing a 5 mile distance around the post. The operator would then rotate the sights horizontally and vertically to try to point the sights in the direction they estimated the sound to be coming from. Instead of using the map, the operator instead called the horizontal and vertical angles to their operations room. The horizontal angle could be read off a scale around the outer edge of the map, but the vertical angle was instead measured by dropping the last three zeros of the altitude measurement, so if the sights were over the 14,000 foot marker, they would call in "angle 14".

In the operations room, a plotter trained in sound measurements would take the angle measurements from multiple stations and determine the location by plotting the angles on a map and looking for the intersections. They would then calculate the distance from one or more of the posts and calculate the altitude using the formula $altitude = angle x calculated distance ÷ 5$. For instance, if they found that the aircraft was 4 miles from a particular post that indicated the angle was 14, then the altitude would be 14 x 4 / 5 = 56/5 = about 11,000 feet. Plotters were equipped with pre-calculated tables to make these calculations quickly.

Reporting system


The Observer Corp was to a large degree an expansion of a system originally set up in World War I to coordinate the reports from observers in the London area, part of the London Air Defence Area (LADA). In this system, originally set up by Edward Ashmore, observers telephoned reports of aircraft to a plotting center in the Horse Guards building in London. Information from the map would then be forwarded to the fighter aircraft and anti-aircraft guns in the LADA area.

In the post-WWI era the system was taken over by the Air Defence of Great Britain organization, formally part of the Royal Air Force but containing British Army and Royal Engineer units as well. It was re-organized and expanded, covering not only the London area but adding similar reporting organizations in The Midlands. They also introduced new techniques to deal with faster aircraft.

In the new systems, plotters would take the reports from the observers and place a colored marker on a large map inside the indicated grid location. The marker held information about the number and altitude of the aircraft. The marker colors changed every five minutes, based on a sector clock, and when the marker was moved to a new location, a smaller marker was left behind in its former location. This produced a trail of colored markers on the map that allowed observers to easily see the track of the aircraft, as well as estimate how quickly it was moving.

The Dowding system was built on top of the existing reporting system. It added a central filter room that acted as a plotting station for all of the Chain Home radar stations. Reports from the filter room were then forwarded to Group plotting rooms where they were combined with information from the Observer Corps. The same basic system using colored markers indicating the time, altitude and number of aircraft was used throughout the system.

Starting in 1942, additional charts were installed at the Group plotting centers that allowed information from neighbouring Groups to be recorded. This was useful for handing over tracks that were moving across Group boundaries.