Plotting board


A plotting board was a mechanical device used by the U.S. Army Coast Artillery Corps as part of their fire control system to track the observed course of a target, project its future position, and derive the uncorrected data on azimuth and range needed to direct the fire of the guns of a battery to hit that target. Plotting boards of this sort were first employed by the Coast Artillery around 1905, and were the primary means of calculating firing data until WW2. Towards the end of WW2 these boards were largely replaced by radar and electro-mechanical gun data computers, and were relegated to a back-up role.
Although several different types of plotting boards were used by the Coast Artillery over the years, the example described here is the Whistler-Hearn Plotting Board, Model of 1904 which was widely employed by the Coast Artillery between about 1905 and 1925. This description is primarily derived from two manuals of the period, each of which leaves certain aspects of the board's design and use unexplained. A 1940 manual also describes the Whistler-Hearn board.

Overview

The Whistler-Hearn plotting board was a semicircular wooden table about 7.5 feet in diameter with a mechanism on top that could be configured to represent the geography of the harbor area in which it was used, including the locations of the base end stations that observed targets for the gun battery it controlled and the location of the gun of that battery. The guns were located with reference to their directing point, the point for which the firing data were calculated. Making the firing data relative to the position of the gun was called the relocation of these data. Relocation was part of the analog function of the plotting board and was enabled by adjustments to the gun arm center of the board.
The mechanism of radial arms and adjustable slides, arcs, and gears converted observations that had been telephoned in from the base end stations into firing data for the guns.
The plotting board for a given gun battery was located in the plotting room for that battery, a space often attached to an observation post or protected within a reinforced concrete bunker or casemate. It was served by a large crew who were part of the Range Section of the battery personnel.
To locate a target, plotting board operators used two radial arms, and "locked-in" the ends of these arms along on the notched azimuth scale that ran around the circumference of the board at the azimuths of the sightings that were telephoned in to them by the two base end stations. These locked arms and the baseline arm then formed a triangle whose vertices were the two observation stations and the target. This located the target on the board, and its position was then marked by punching a hole in the paper placed over the plotting board. Next, another radial arm, called the gun arm, was swung over the plotted position of the target, and the resulting range and azimuth for firing were read off the gun arm and an azimuth scale on the gun arm center. These data were corrected or adjusted for some other variables, and telephoned to the gun.
The figure at left shows the actual relationship between the distant target, the two base end stations, and the directing point of the battery's guns, as reflected onto the plotting board. The triangle formed by the B1 arm, the B2 arm and the base line arm is the small triangle at the base of the plotting board, and the gun arm is shown swung over the intersection of the other two arms in order to read the range and azimuth to the target. Another helpful diagram is shown on the base end station page—the cutaway diagram of a battery's plotting room, shown next to the two base end stations, and behind the directing point of the battery, between its two guns.

Customizing the plotting board to its site

Before it was used, a Whistler-Hearn board had to be set up and customized to the geography of the area at which it was to be used and for the location of the guns in the battery it was to direct.
First, the primary block was slid onto the bronze base-line arm and secured at the exact center of that arm. Then, the secondary block was slid onto the left or right end of the base-line arm and set at a distance from the primary block that was equal to the length of the base line at that site.
Both the primary and the secondary block had a pintle, or pin, attached to it which represented the surveyed position of the observing instrument in the primary or secondary base end station.
The secondary arm was installed on the pintle of the secondary block. On the pintle of the primary block were installed the primary arm, the auxiliary arm, and the gun arm, as well as the complex gun arm center mechanism that was used to adjust the board for the location of the guns' directing point, to read the azimuth to the target, to adjust the firing data, and to tally the motion of the target between successive plotted positions. Plate XXVI shows a close-up of the gun arm center mechanism.
The arc of the board was notched at one-degree intervals. To identify these notches with actual degrees of azimuth for a particular site, a zinc strip, with numbers of degrees of azimuth inscribed on it, was slipped into a slot on the surface of the board, towards its outer edge. The azimuth indicated by left edge of the base line arm was arbitrarily determined to be whatever azimuth fit the site, and adjusting screws with a vernier scale allowed for up to 0.5 degrees of "tweaking" of the base line arm's orientation.
Next, two index boxes were slid onto the notched circumference edge of the board and the ends of the primary and auxiliary arms were inserted into these boxes. These boxes could be locked in position at whole-degree intervals, and each index box had a geared dial on its surface that could be turned through one hundred parts of a degree, enabling each arm to be adjusted to within.01 degree of azimuth.
Next, the gun arm center mechanism was slid from side to side and/or up and down with relation to the base line arm to account for the location of the battery's directing point to one side or the other of the primary base end station or behind or in front of the base line. These adjustments resulted in relocating the firing data sent to the guns to the actual positions of these guns. A further adjustment might need to be made by the gun crew to account for the distance of an individual gun from the battery's directing point, called its displacement.
After these adjustments, the plotting board represented a true analog of the harbor being defended and was ready for use in fire control.
This customization of the board to its site, however, was also a weakness. It meant that the battery's fire control system was limited to using only the one baseline and only the two base end stations associated with that baseline. If one of the two base end stations was put out of action the battery would have to switch to a less precise method of fire control, such as vertical base observation, the use of a self-contained rangefinder instrument, or aiming its guns directly, using their own telescopic sights.

Using the plotting board

Using the plotting board required a team of five or six soldiers to handle the board itself, five or six more to handle equipment used to correct and adjust the resulting target coordinates and a minimum of four more in the two distant base end stations. Many of the plotting board functions described below were performed repeatedly, during several successive observation/firing intervals that were indicated throughout the harbor defense system by the ringing of time interval bells.
The process began when a target was identified by the harbor command and assigned to a given gun battery. Observers in the two widely separated base end stations for the chosen battery tracked the target, using either azimuth scopes or more sophisticated depression position finders. Azimuth scopes were only capable of locating the target in azimuth, while a DPF could be used for azimuth readings alone or could also measure the range from the base end station to the target.
At the signal from the time interval bell, the reader in each base end station would read the azimuth of the target off of the instrument and call this reading to the arm setter covering that station at the plotting board. Each of the two arm setters at the board moved his assigned arm to the position on the notched azimuth scale that corresponded to the azimuth reading he had just received by phone from his base end station. The arm setter then locked his arm at that position, using the index disk clamp at the end of the arm. Hundredths of a degree were indicated by turning the geared index disk, a wheel with 100 teeth that enabled adjusting the angle of the arm very precisely.
With both arms set, a small block called the targ was slid up to the intersection of the arms and a mark was made on the plotting paper at the target's indicated position.
This process of observing, setting the arms on the plotting board, and marking the target's position at the arms' intersection was repeated at the end of each observing interval for the battery. Since the firing of the gun often occurred when the interval bell rang, the interval was also called a firing interval. The interval was usually set at 20 seconds. After tracking a target for a short time, there would a string of plotted positions indicated on the board. This would then be sufficient for the plotting room to "connect the dots" with a projected course line and estimate the target's speed.
Next, a slide rule-like device called a set forward rule was used to mark off the set forward point for the target. The set forward point was the anticipated position of the target at the end of the dead time plus the time of flight. The speed of the target was calculated from the time it took to cover the distances between the previously plotted points on its track. This type of fire control in the Coast Artillery was based upon the assumptions that the target steered in straight line and did not alter its speed during the 20-second observing interval.
It was the set forward point that the guns were targeted to hit. This was accomplished by bringing the gun arm of the plotting board over this point, and reading the range from the directing point to the target off the range scale on the edge of that arm and the azimuth from the directing point to the target off of azimuth circle of the gun arm center. To see how this and further steps in the fire control process were accomplished, our attention shifts to the mechanisms of the gun arm center, shown in Plate XXVI at the right.
Plate XXVI shows the gun arm, which points here toward the top of the photo. It also shows the window through which the azimuth of the gun arm was read. Many of the other features of the gun arm center were used in correcting the firing data.
Corrections in range were applied by turning the knob attached to a gear wheel at the center of the correction box, which slid the gun arm towards its circumference or back, with the adjustments indicated by index numbers visible through the window to the left of the pinion. Corrections in azimuth were achieved by turning the knurled knob at the right edge of the worm gear located at the bottom of the gun arm, with its pointer being used to read off index numbers and turn the gun arm through its arc.
The dials on the face of the gun arm center were used to calculate the angular travel of the target between successive plotted points on the board, a quantity that could be corrected and then applied to calculating the set forward point.