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The slide rule is a mechanical precursor of the pocket calculator. It was invented in 1625 by William Oughtred and was very commonly used until the 1970s when it was
made obsolete for most purposes by electronic calculators.
Cursor on a slide rule
Once widely used for rapid, approximate scientific and engineering calculations, a slide rule is a portable, mechanical,
analog computer consisting of three interlocking calibrated strips.
The central strip can be moved lengthways relative to the other two. A sliding cursor
with one or more vertical alignment lines can record an intermediate result on any of the scales. Some slide rules have scales on
both sides of the rule and slide strip, others on the slide strip only.
One slide rule remaining in daily use around the world is the E-6B. This is a circular slide rule
first created in the 1930s for pilots to help with dead reckoning. It is still available in all flight shops, and remains widely used. While GPS has greatly reduced the use of dead reckoning for
aerial navigation, the E-6B remains widely used as a backup device and the majority of flight schools demand its mastery to some
degree.
Theory of operation
Standard linear rules
The scales are logarithmic. That is, a number x is
printed on each rule at a distance c·log(x) from the 'index', which is marked with the number 1. A logarithm
transforms an operation of multiplication or division to one of addition or subtraction. Since addition and subtraction are
easily carried out using a number line, the slide rule effectively implements
a number line with a sliding scale. By the use of the logarithmic transform
multiplication and division can be carried out.
To multiply x by y, one aligns the index on the sliding scale with the number x on the fixed scale.
To do this, the sliding scale must be moved over a distance of c·log(x). The number y on the sliding
scale has now moved from its old position, c·log(y), to c·log(y)+c·log(x) =
c·log(xy), and is therefore aligned with the number xy on the fixed scale.
For example, the illustration below shows the multiplication of 2 by 3.5. The index (1) on the upper scale is aligned with the
2 on the lower scale. The number 3.5 on the upper scale is aligned with the product, 7, on the lower scale.
Division reverses this process. The illustration below shows the division of 22
by 2.75. The index (1) on the upper scale is aligned with the 2.75 on the lower scale. The 22 on the lower scale (the mark just
to the left of the 22.5 mark) is aligned with the quotient, 8, on the upper scale.
Slide rules calibrated on one side were called "simplex." Slide rules calibrated on both sides were called "duplex."
Typically two significant figures of precision were possible, with three being obtained by expert users who could estimate the
fraction between gradations. Some high-end slide rules had magnifying cursors that effectively doubled the accuracy, permitting a
10-inch slide rule to serve as well as a 20-inch.
Slide rules often have other mathematical functions encoded on other auxiliary scales. The most popular were trigonometric, usually sine and tangent, logarithm of logarithm (base 10) (for taking the log of a value on a multiplier scale),
natural logarithm and exponential scales. Some rules included a pythagorean
scale, to figure sides of triangles, and a scale to figure circles.
Specialised slide rules were invented for various forms of engineering, business and banking. These often had common
calculations directly expressed as special scales, for example loan calculations, optimal purchase quantities, or particular
engineering equations.
A number of tricks were used to get more convenience. Trigonometric scales were sometimes dual-labelled, in black and red,
with complementary angles, the so-called "Darmstadt" style. Duplex slide rules often duplicated basic scales on the back. Scales
were often "split" to get higher accuracy.
Circular slide rules
Circular slide rules came in two basic types, one with two cursors, and another with a moveable disk and a cursor. The basic
advantage of a circular slide rule is that the longest dimension was reduced by a factor of about 3 (i.e. by π). For example, a 10cm circular would have a maximum accuracy equal to a 30 cm ordinary slide rule.
Circular slide rules were mechanically more rugged, smoother-moving and more precise than linear slide rules, because they
depended on a single central bearing. The central pivot did not usually fall apart. The pivot also prevented scratching of the
face and cursors. Only the most expensive linear slide rules had these features.
The highest accuracy scales were placed on the outer rings. Rather than "split" scales, high-end circular rules used helical
(snail-shell-shaped) scales for difficult things like log-of-log scales. One eight-inch premium circular rule had a 50 inch
helical log-log scale! Circular slide rules also eliminate "off-scale" calculations, because the scales were designed to "wrap
around."
In 1952, Swiss watch company
Breitling introduced a pilot's wristwatch with an integrated circular slide rule specialized for flight calculations
— the Breitling Navitimer. The Navitimer circular rule, referred to by Breitling as a "navigation computer", featured
airspeed, rate/time of climb/descent, flight time, distance, and fuel consumption functions, as well as kilometer–nautical mile and
gallon–liter fuel amount conversion
functions.
Technically, a real disadvantage of circular slide rules is that less-important scales are closer to the center, and have
lower accuracies. Historically, the main disadvantage of circular slide rules was just that they were not standard. Most students
learned slide rule use on the linear slide rules, and never found reasons to switch.
Materials
The best older slide rules were made of bamboo, which is dimensionally stable, strong and naturally self-lubricating. They
used scales of celluloid or plastic. Some were made of mahogany. Later slide rules were made of plastic, or aluminum painted with
plastic.
All premium slide rules had numbers and scales engraved, and then filled with paint or other resin. Painted or imprinted slide
rules are inferior because the markings wear off.
Early cursors were metal frames holding glass. Later cursors were acrylics or polycarbonates sliding on teflon bearings.
Magnifying cursors can both help engineers with bad eyes, and double the accuracy of a slide rule.
Premium slide rules included clever catches so the rule would not fall apart by accident, and bumpers so that tossing the rule
on the table would not scratch the scales or cursor.
The recommended cleaning method for engraved markings is light scrubbing with steel-wool. For painted slide rules, and the faint
of heart, use diluted commercial window-cleaning fluid and a soft cloth.
History
Slide rules came into wide use in the 1850s, as engineering became a recognized professional activity. In World War II, bombardiers and navigators who required quick calculations often used specialized slide rules.
One office of the U.S. Navy actually designed a generic slide rule "chassis" with an
aluminum body and plastic cursor into which celluloid cards (printed on both sides) could be placed for special calculations. The
process was invented to calculate range, fuel-use and altitude for aircraft, and
then adapted to many other purposes.
Throughout the 1950s and 1960s the slide rule
was the symbol of the engineer's profession in the same way that the stethoscope symbolized the medical profession. Some engineering students and engineers actually carried
five-inch pocket slide rules in belt holsters, in addition to using a ten- or twenty-inch rule for precision work at home or at
the office. All this came to an end in the 1970s, when the advent of miniaturised
calculators made slide rules obsolete. The last nail in the coffin was the
launch of scientific pocket calculators, i.e. having trigonometric and logarithmic functions, of which the HP-35 was the first, in 1972.
Most slide rules are now collectors' items. A very popular model is the Keuffel & Esser Deci-Lon, a premium
scientific and engineering slide rule available both in a ten-inch "regular" (Deci-Lon 10) and a five-inch "pocket"
(Deci-Lon 5) variant. Another prized model is the eight-inch Scientific Instruments circular rule. At the turn of the
millennium, the collectors' market still doesn't seem to be drying up, and as recently as 2002, new slide rules were being
located in the back-shelves of university book-stores, even though production ended in 1973.
See also
External links
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