Inside caliper Inside calipers are used to measure the internal size of an object. • The upper caliper in the image (on the right) requires manual adjustment prior to fitting. Fine setting of this caliper type is performed by tapping the caliper legs lightly on a handy surface until they will
almost pass over the object. A light push against the resistance of the central pivot screw then spreads the legs to the correct dimension and provides the required, consistent
feel that ensures a repeatable measurement. • The lower caliper in the image has an adjusting screw that permits it to be carefully adjusted without removal of the tool from the workpiece.
Outside caliper Outside calipers are used to measure the external size of an object. The same observations and technique apply to this type of caliper, as for the inside caliper. With some understanding of their limitations and usage, these instruments can provide a high degree of accuracy and repeatability. They are especially useful when measuring over very large distances; consider if the calipers are used to measure a large-diameter pipe. A vernier caliper does not have the depth capacity to straddle this large diameter and at the same time reach the outermost points of the pipe's diameter. They are made from high-carbon steel.
Divider caliper In the metalworking field, a divider caliper, popularly called a compass, is used to
mark out locations. The points are sharpened so that they act as scribers; one leg can then be placed in the dimple created by a
center or prick punch and the other leg pivoted so that it scribes a line on the workpiece's surface, thus forming an arc or circle. Their namesake use is in dividing a workpiece of arbitrary width into equal-width sections: by "walking" the tool from one end to the other by pivoting it from one point to the next until reaching the other end, then adjusting the gap between the points until the "walk" ends directly on the end point, equal divisions can be easily marked out without any measuring. A divider caliper is also used to measure a distance between two points on a map. The two caliper ends are brought to the two points whose distance is being measured. The caliper's opening is then either measured on a separate ruler and then converted to the actual distance, or measured directly on a
scale drawn on the map. On a
nautical chart the distance is often measured on the
latitude scale appearing on the sides of the map: one
minute of arc along any
great circle, e.g. any longitude meridian, is approximately one
nautical mile or 1852
meters. Dividers are also used in the medical profession. An ECG (also EKG) caliper transfers distance on an
electrocardiogram; in conjunction with the appropriate scale, the heart rate can be determined. A pocket caliper version was invented by cardiologist Robert A. Mackin.
Oddleg caliper Oddleg calipers,
hermaphrodite calipers, or
oddleg jennys, as pictured on the left, are generally used to scribe a line at a set distance from the edge of a workpiece. The bent leg is used to run along the workpiece edge while the scriber makes its mark at a predetermined distance, this ensures a line parallel to the edge. In the diagram at left, the uppermost caliper has a slight shoulder in the bent leg allowing it to sit on the edge more securely. The lower caliper lacks this feature but has a renewable scriber that can be adjusted for wear, as well as being replaced when excessively worn.
Vernier caliper The labelled parts are The calipers in the diagram show a primary reading on the metric scale of about 2.475 cm (2.4 cm read from the main scale plus about 0.075 cm from the vernier scale). Calipers often have a "zero point error": meaning that the calipers do not read 0.000 cm when the jaws are closed. The zero point error must always be subtracted from the primary reading. Let us assume these calipers have a zero-point error of 0.013 cm. This would give us a length reading of 2.462 cm. For any measurement, reporting the error on the measurement is also important. Ignoring the possibility of interpolation by eye, both the primary reading and the zero point reading are bounded by plus/minus
half the length corresponding to the width of the smallest interval on the vernier scale (0.0025 cm). These are "absolute" errors and absolute errors add, so the length reading is then bounded by plus/minus the length corresponding to the
full width of the smallest interval on the vernier scale (0.005 cm). Assuming no systematics affect the measurement (the instrument works perfectly), a complete measurement would then read 2.462 cm ± 0.005 cm. The vernier, dial, and digital calipers directly read the distance measured with high
accuracy and precision. They are functionally identical, with different ways of reading the result. These calipers comprise a calibrated scale with a fixed jaw, and another jaw, with a pointer, that slides along the scale. The distance between the jaws is then read in different ways for the three types. The simplest method is to read the position of the pointer directly on the scale. When the pointer is between two markings, the user can mentally
interpolate to improve the precision of the reading. This would be a simply calibrated caliper, but the addition of a
vernier scale allows more accurate interpolation and is the universal practice; this is the
vernier caliper. Vernier, dial, and digital calipers can measure internal dimensions (using the uppermost jaws in the picture at right), external dimensions using the pictured lower jaws, and in many cases depth by the use of a probe that is attached to the movable head and slides along the centre of the body. This probe is slender and can get into deep grooves that may prove difficult for other measuring tools. The vernier scales may include
metric measurements on the lower part of the scale and
inch measurements on the upper, or vice versa, in countries that use inches. Vernier calipers commonly used in industry provide a precision to 0.01 mm (10
micrometres), or one thousandth of an inch. They are available in sizes that can measure up to 1828 mm (72 in). Image:Schuifmaat afmeten uitwendige maat.jpg|Measuring external distance Image:Schuifmaat afmeten inwendige maat.jpg|Measuring internal distance Image:Schuifmaat afmeten diepte.jpg|Measuring the depth of a step or hole with the depth probe Image:Schuifmaat afmeten uitsparing.jpg|Measuring the width of a step with the top of the calipers Image:Schuifmaat aftekenen breedte.jpg|Marking a set or measured distance from an edge by scraping a line with the sharp sides of the beak Image:Schuifmaat aftekenen kopse kant.jpg|Marking a set or measured distance from an edge by marking with a pencil. The top of the moving part is held against the side of the step. Not all calipers have this option.
Dial caliper Instead of using a vernier mechanism, which requires some practice to use, the
dial caliper reads the final fraction of a millimeter or inch on a simple dial. In this instrument, a small, precise
rack and pinion drives a pointer on a circular
dial, allowing direct reading without the need to read a vernier scale. Typically, the pointer rotates once every inch, tenth of an inch, or 1 millimeter. This measurement must be added to the coarse whole inches or centimeters read from the slide. The dial is usually arranged to be rotatable beneath the pointer, allowing for "differential" measurements (the measuring of the difference in size between two objects, or the setting of the dial using a master object and subsequently being able to read directly the plus-or-minus variance in the size of subsequent objects relative to the master object). The slide of a dial caliper can usually be locked at a setting using a small
lever or screw; this allows simple
go/no-go checks of part sizes.
Digital caliper Rather than a
rack and pinion,
digital calipers use a
linear encoder. A
liquid-crystal display shows the measurement, which often can switch
units between millimeters and
fractional or decimal inches. All provide for zeroing the display at any point along the slide, allowing the same sort of differential measurements as with the dial caliper. Digital calipers may contain a "reading hold" feature, allowing the reading of dimensions after use in awkward locations where the display cannot be seen. Like analog calipers, the slide of many digital calipers can be locked using a lever or screw.
Resolution and accuracy Ordinary 150 mm (6
in) digital calipers made of stainless steel have a rated accuracy of ± 0.02 mm (
0.001 in) and a
resolution of 0.01 mm (0.0005 in). The same technology is used for longer calipers, but accuracy declines to ± 0.03 mm (0.001 in) for 100–200 mm (4–8 in) and ± 0.04 mm (0.0015 in) for 200–300 mm (8–12 in) measurements.
Measurement method Many digital calipers contain a
capacitive linear encoder. Inexpensive models have 56 narrow emitter plates and one long receiver plate etched on the sliding display's
printed circuit board, which intersect with a repeating pattern of T-shaped plates in the longer "stator" board. The top of the "T" plates intersect with the receiver plate, while the vertical bars of each "T" intersect with the emitter plates. The pitch of each "T" in the stator is slightly less than 8 times the pitch of each emitter plate, so their intersecting capacitive area is not perfectly aligned but rather forms an
interference pattern. As the slider moves, these variable capacitances change in a repeating linear fashion. The slider's circuitry counts these repetitions as it slides and achieves finer resolution using linear interpolation of the capacitances. One model sends 8 periodic
pulse-width modulation voltage signals (which appear identical but out of phase by of the period), each connected to 7 emitter plates, and the resulting analog signal is read through a single receiver plate. The 1983 German patent DE3340782C2 (see figure) is said to describe the workings. Other digital calipers contain an
inductive linear encoder, which allows robust performance in the presence of contamination such as coolants. Magnetic linear encoders are used in yet other digital calipers.
Serial data output Digital calipers nowadays offer
serial data output to expedite repeated measurements, avoid
human error, and allow direct
data entry into a digital recorder,
spreadsheet,
statistical process control program, or similar software on a
personal computer. Interfacing devices based on
RS-232,
Universal Serial Bus, or
wireless can be built or purchased. The serial digital output varies among manufacturers, but common options are: • Mitutoyo's Digimatic interface. This is the dominant name brand interface. Format is 52
bits arranged as 13
nibbles. • Sylvac interface. This is the common protocol for inexpensive, non-name brand, calipers. Format is 24-bit 90 kHz synchronous. • Starrett • Brown & Sharpe
Micrometer screw caliper A caliper using a calibrated
screw for measurement (rather than a slide) is called an
external micrometer caliper gauge, a
micrometer caliper, or, more often, simply a
micrometer. Sometimes the term
caliper, referring to any other type in this article, is held in contradistinction to
micrometer. ==Comparison==