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{{Short description|A tool used to measure projectile speed}}
{{For|a timepiece with both timekeeping and stopwatch functions|chronograph}}
{{multiple image|perrow = 1|total_width=220
A '''gun chronograph''' is an instrument used to measure the velocity of a projectile fired by a gun.
| image1 = Chronographa.jpg |thumb
| image2 = Prochrono2.jpg|thumb
| footer = A Down Range chronograph with storage and statistical tools.
}}
A '''ballistic chronograph''' or '''gun chronograph''' is a [[measuring instrument]] used to [[measurement|measure]] the [[velocity]] of a [[projectile]] in [[flight]], typically fired from a [[gun]] or other [[Firearm|firearm]]. The instrument is often useful for tasks such as gauging the utility of a [[Firearm|firearm]] or safety of non-lethal projectiles fired from items such as a [[Paintball marker|paintball gun]] or [[BB gun]].


==History==
==History==
[[Benjamin Robins]] (1707-1751) invented the [[ballistic pendulum]] that measures the [[momentum]] of the [[projectile]] fired by a [[gun]]. Dividing the momentum by the projectile [[mass]] gives the [[velocity]]. Robbins published his results as ''New Principles of Gunnery'' in 1742.<ref>{{harvnb|Ingalls|1886|p=17}}</ref><ref>{{citation |last=Robins |first=Benjamin |title=New Principles of Gunnery |edition=New |year=1805 |publisher=F. Wingrave |url=http://google.com/books?id=3j8FAAAAMAAJ&printsec=frontcover&source=gbs_ge_summary_r&cad=0#v=onepage&q&f=false}}</ref> The ballistic pendulum could make only one measurement per firing because the device catches the projectile.<ref>{{Harvnb|Bashforth|1866|p=3}}, "only one observation on each round".</ref> The gun's accuracy also limited how far down range a measurement could be made.<ref>{{Harvnb|Bashforth|1866|p=3}}, "Beyond 295 feet the gun was not sufficiently accurate".</ref>
[[Benjamin Robins]] (1707–1751) invented the [[ballistic pendulum]] that measures the [[momentum]] of the [[projectile]] fired by a [[gun]]. Dividing the momentum by the projectile [[mass]] gives the [[velocity]]. Robbins published his results as ''New Principles of Gunnery'' in 1742.<ref>{{harvnb|Ingalls|1886|p=17}}</ref><ref>{{citation |last=Robins |first=Benjamin |title=New Principles of Gunnery |edition=New |year=1805 |publisher=F. Wingrave |url=https://books.google.com/books?id=3j8FAAAAMAAJ}}</ref> The ballistic pendulum could make only one measurement per firing because the device catches the projectile.<ref>{{Harvnb|Bashforth|1866|p=3}}, "only one observation on each round".</ref> The gun's accuracy also limited how far down range a measurement could be made.<ref>{{Harvnb|Bashforth|1866|p=3}}, "Beyond 295 feet the gun was not sufficiently accurate".</ref>


[[Alessandro Vittorio Papacino d'Antoni]] published results in 1765 using a wheel chronometer. This used a horizontal spinning wheel with a vertical paper mounted on the rim. The bullet was fired across the diameter of the wheel so that it pierced the paper on both sides, and the angular difference along with the rotation speed of the wheel was used to compute the bullet velocity.<ref>{{Citation |last=d'Antoni |first=Alessandro Vittorio Papacino |title=Esame Della Polvere |year=1765 |location=Torino |publisher=Nella Stamperia Reale}}</ref>
An early chronograph that measures velocity directly was built in 1804 by [[Grobert]], a colonel in the French Army. This used a rapidly rotating axle with two disks mounted on it about 13 feet apart. The bullet was fired parallel to the axle, and the angular displacement of the holes in the two disks, together with the rotational speed of the axle, yielded the bullet velocity.<ref>{{Citation |last=Prony |contribution=Report of a method of measuring the initial Velocity of Projectiles discharged from Fire-arms, both horizontally and with different Elevations, made to the Physical and Mathematical Class of the National Institute |title=A Journal of Natural Philosophy, Chemistry and the Arts |editor-first=William |editor-last=Nicholson |volume=XI |year=1805 |location=London |url=http://books.google.com/books?id=uwkAAAAAMAAJ&pg=RA1-PA42&hl=en&sa=X&f=false}} at page 42<br/> abridged from ''Journal des Mines'' No 92 p. 117, May 1804.</ref>


An early chronograph that measures velocity directly was built in 1804 by [[Grobert]], a colonel in the French Army. This used a rapidly rotating axle with two disks mounted on it about 13 feet apart. The bullet was fired parallel to the axle, and the angular displacement of the holes in the two disks, together with the rotational speed of the axle, yielded the bullet velocity.<ref>{{Citation |last=Prony |contribution=Report of a method of measuring the initial Velocity of Projectiles discharged from Fire-arms, both horizontally and with different Elevations, made to the Physical and Mathematical Class of the National Institute |title=A Journal of Natural Philosophy, Chemistry and the Arts |editor-first=William |editor-last=Nicholson |volume=XI |year=1805 |location=London |url=https://books.google.com/books?id=uwkAAAAAMAAJ&pg=RA1-PA42}} at page 42<br/> abridged from ''Journal des Mines'' No 92 p. 117, May 1804.</ref>
{{Harvtxt|Ingalls|1882|p=18}} describes Bashforth's chronograph that could make many measurements over long distances:

{{Harvtxt|Ingalls|1886|p=18}} describes Bashforth's chronograph that could make many measurements over long distances:
: In 1865 the Rev. [[Francis Bashforth]], M. A., who had then been recently appointed Professor of Applied Mathematics to the advanced class of artillery officers at [[Royal Military Academy, Woolwich|Woolwich]], began a series of experiments for determining the resistance of the air to the motion of both spherical and oblong projectiles, which he continued from time to time until 1880. As the instruments then in use for measuring velocities were incapable of giving the times occupied by a shot in passing over a series of successive equal spaces, he began his labors by inventing and constructing a chronograph to accomplish this object, which was tried late in 1865 in Woolwich Marshes, with ten screens, and with perfect success.
: In 1865 the Rev. [[Francis Bashforth]], M. A., who had then been recently appointed Professor of Applied Mathematics to the advanced class of artillery officers at [[Royal Military Academy, Woolwich|Woolwich]], began a series of experiments for determining the resistance of the air to the motion of both spherical and oblong projectiles, which he continued from time to time until 1880. As the instruments then in use for measuring velocities were incapable of giving the times occupied by a shot in passing over a series of successive equal spaces, he began his labors by inventing and constructing a chronograph to accomplish this object, which was tried late in 1865 in Woolwich Marshes, with ten screens, and with perfect success.


[[File:Girl Gunners- the work of the Auxiliary Territorial Service at An Experimental Station, Shoeburyness, Essex, England, 1943 D12697.jpg|thumb|right|The velocity of [[Ordnance QF 25-pounder]] shells being measured in the United Kingdom, 1943]]
The Bashforth screens were made with several threads and series connected switches. A projectile passing through a screen would break one or more threads, the broken thread caused a switch to momentarily (about 20&nbsp;ms) interrupt a current as the switch arm moved from its weighted position to its unweighted position, and the momentary interruption would be recorded on a paper chart.<ref>{{Harvnb|Bashforth|1866|pp=12–13}}</ref>
The Bashforth screens were made with several threads and series connected switches. A projectile passing through a screen would break one or more threads, the broken thread caused a switch to momentarily (about 20&nbsp;ms) interrupt a current as the switch arm moved from its weighted position to its unweighted position, and the momentary interruption would be recorded on a paper chart.<ref>{{Harvnb|Bashforth|1866|pp=12–13}}</ref>

The first electronic ballistic chronograph was invented by Kiryako ("Jerry") Arvanetakis in the 1950s.{{Citation needed|date=May 2011}} As consulting engineer under contract by NACA (later [[NASA]]), he was asked to find a way to accurately measure the velocity of various projectiles fired at [[hypersonic|hyper-velocities]] into a variety of engineered materials in anticipation of crewed space flight. His first design was an open rectangular frame of square [[aluminum]] tubing with a screen of fine copper wire at both ends. Breaking the first wire started charging a [[capacitor]], breaking the second wire stopped it. Measuring the accumulated voltage and knowing the rate of charge the elapsed time could be accurately calculated.


==Modern chronograph==
==Modern chronograph==
The modern chronograph consists of two sensing areas called ''chronograph screens'', which contain [[photodetector|optical sensors]] that detect the passage of the bullet. The bullet is fired so it passes through both screens, and the time it takes the bullet to travel the distance between the screens is measured electronically.
The modern chronograph consists of two sensing areas framed by rods topped by diffusing screens or artificial lighting above (or below) along with [[photodetector|optical sensors]] that detect the passage of the bullet. The time it takes the bullet to travel the distance between the sensors is measured electronically from which velocity is calculated and displayed.


Advanced ballistic chronographs include a type employing [[Doppler radar]] to measure bullets in free flight at various distances; another is a device mounted at the end of a barrel, which uses magnetic field sensors for the measurement of a bullet's velocity as it exits the muzzle.<ref>{{Cite web|url=https://outdoorworld.reviews/best-shooting-chronograph/|title = 15 Best Shooting Chronographs|date = 22 November 2020}}</ref>
The first electronic ballistic chronograph was invented by Kiryako ("Jerry") Arvanetakis in the 1950s.{{Citation needed|date=May 2011}} As consulting engineer under contract by NACA (later [[NASA]]), he was asked to find a way to accurately measure the velocity of various projectiles fired at [[hypersonic|hyper-velocities]] into a variety of engineered materials in anticipation of manned space flight. His first design was an open rectangular frame of square [[aluminum]] tubing with a screen of fine copper wire at both ends. Breaking the first wire started charging a [[capacitor]], breaking the second wire stopped it. Measuring the accumulated voltage and knowing the rate of charge the elapsed time could be accurately calculated.

[[File:Chronographa.jpg|thumb|Down Range Chronograph. With Storage and Statistical Tools]]
== See also ==
[[File:Prochrono2.jpg|thumb|Down Range Chronograph with storage and statistical tools.]]
* [[Aberdeen chronograph]]


==References==
==References==
{{reflist|30em}}
{{reflist|30em}}


* {{Citation |last=Bashforth |first=Francis |authorlink=Francis Bashforth |title=Description of a Chronograph adapted for measuring the varying velocity of a body in motion through the air and for other purposes |location=London |publisher=Bell and Daldy |year=1866 |url=http://books.google.com/books?id=tBxWAAAAcAAJ&hl=en&f=false}}
* {{Citation |last=Bashforth |first=Francis |authorlink=Francis Bashforth |title=Description of a Chronograph adapted for measuring the varying velocity of a body in motion through the air and for other purposes |location=London |publisher=Bell and Daldy |year=1866 |url=https://books.google.com/books?id=tBxWAAAAcAAJ}}
* {{citation |last=Ingalls |first=James M. |publisher=D. van Nostrand |location=New York |year=1886 |title=Exterior Ballistics in the Plane of Fire }}
* {{citation |last=Ingalls |first=James M. |publisher=D. van Nostrand |location=New York |year=1886 |title=Exterior Ballistics in the Plane of Fire |url=https://archive.org/details/exteriorballist00unkngoog}}


==Further reading==
==Further reading==
* {{Citation |last=Bashforth |first=Francis |authorlink=Francis Bashforth |title=A mathematical treatise on the motion of Projectiles founded chiefly on the results of experiments made with the author's chronograph |location=London |publisher=Asher and Company |year=1873 |url=https://archive.org/details/amathematicaltr00bashgoog }}
* {{Citation |last=Bashforth |first=Francis |authorlink=Francis Bashforth |title=A mathematical treatise on the motion of Projectiles founded chiefly on the results of experiments made with the author's chronograph |location=London |publisher=Asher and Company |year=1873 |url=https://archive.org/details/amathematicaltr00bashgoog |ref=none}}
* {{Citation |last=Bashforth |first=Francis |authorlink=Francis Bashforth |url=http://www.archive.org/details/ballisticexperim00bashrich |title=Ballistic experiments from 1864 to 1880 |publisher=Cambridge University Press |year=1907}}
* {{Citation |last=Bashforth |first=Francis |authorlink=Francis Bashforth |url=https://archive.org/details/ballisticexperim00bashrich |title=Ballistic experiments from 1864 to 1880 |publisher=Cambridge University Press |year=1907 |ref=none}}
* {{Citation |last=Bashforth |first=Francis |authorlink=Francis Bashforth |title=Revised account of the experiments made with the Bashforth Chronograph, to find the resistance of the air to the motion of projectiles, with the application of the results to the calculation of trajectories according to J. Bernoulli's method |publisher=Cambridge University Press |year=1890 |url=https://archive.org/details/revisedaccountof00bashuoft}}
* {{Citation |last=Bashforth |first=Francis |authorlink=Francis Bashforth |title=Revised account of the experiments made with the Bashforth Chronograph, to find the resistance of the air to the motion of projectiles, with the application of the results to the calculation of trajectories according to J. Bernoulli's method |publisher=Cambridge University Press |year=1890 |url=https://archive.org/details/revisedaccountof00bashuoft |ref=none}}
* {{Citation |last=Bashforth |first=Francis |authorlink=Francis Bashforth |url=http://www.archive.org/details/ahistoricalsket00bashgoog |title=A Historical Sketch of the Experimental Determination of the Resistance of the Air to the Motion of Projectiles |publisher=Cambridge University Press |year=1903}}
* {{Citation |last=Bashforth |first=Francis |authorlink=Francis Bashforth |url=https://archive.org/details/ahistoricalsket00bashgoog |title=A Historical Sketch of the Experimental Determination of the Resistance of the Air to the Motion of Projectiles |publisher=Cambridge University Press |year=1903 |ref=none}}

{{Firearms}}


[[Category:Horology]]
[[Category:Horology]]
[[Category:Firearm terminology]]
[[Category:Firearm terminology]]
[[Category:Ballistics]]

Latest revision as of 22:15, 17 November 2023

A Down Range chronograph with storage and statistical tools.

A ballistic chronograph or gun chronograph is a measuring instrument used to measure the velocity of a projectile in flight, typically fired from a gun or other firearm. The instrument is often useful for tasks such as gauging the utility of a firearm or safety of non-lethal projectiles fired from items such as a paintball gun or BB gun.

History[edit]

Benjamin Robins (1707–1751) invented the ballistic pendulum that measures the momentum of the projectile fired by a gun. Dividing the momentum by the projectile mass gives the velocity. Robbins published his results as New Principles of Gunnery in 1742.[1][2] The ballistic pendulum could make only one measurement per firing because the device catches the projectile.[3] The gun's accuracy also limited how far down range a measurement could be made.[4]

Alessandro Vittorio Papacino d'Antoni published results in 1765 using a wheel chronometer. This used a horizontal spinning wheel with a vertical paper mounted on the rim. The bullet was fired across the diameter of the wheel so that it pierced the paper on both sides, and the angular difference along with the rotation speed of the wheel was used to compute the bullet velocity.[5]

An early chronograph that measures velocity directly was built in 1804 by Grobert, a colonel in the French Army. This used a rapidly rotating axle with two disks mounted on it about 13 feet apart. The bullet was fired parallel to the axle, and the angular displacement of the holes in the two disks, together with the rotational speed of the axle, yielded the bullet velocity.[6]

Ingalls (1886, p. 18) describes Bashforth's chronograph that could make many measurements over long distances:

In 1865 the Rev. Francis Bashforth, M. A., who had then been recently appointed Professor of Applied Mathematics to the advanced class of artillery officers at Woolwich, began a series of experiments for determining the resistance of the air to the motion of both spherical and oblong projectiles, which he continued from time to time until 1880. As the instruments then in use for measuring velocities were incapable of giving the times occupied by a shot in passing over a series of successive equal spaces, he began his labors by inventing and constructing a chronograph to accomplish this object, which was tried late in 1865 in Woolwich Marshes, with ten screens, and with perfect success.
The velocity of Ordnance QF 25-pounder shells being measured in the United Kingdom, 1943

The Bashforth screens were made with several threads and series connected switches. A projectile passing through a screen would break one or more threads, the broken thread caused a switch to momentarily (about 20 ms) interrupt a current as the switch arm moved from its weighted position to its unweighted position, and the momentary interruption would be recorded on a paper chart.[7]

The first electronic ballistic chronograph was invented by Kiryako ("Jerry") Arvanetakis in the 1950s.[citation needed] As consulting engineer under contract by NACA (later NASA), he was asked to find a way to accurately measure the velocity of various projectiles fired at hyper-velocities into a variety of engineered materials in anticipation of crewed space flight. His first design was an open rectangular frame of square aluminum tubing with a screen of fine copper wire at both ends. Breaking the first wire started charging a capacitor, breaking the second wire stopped it. Measuring the accumulated voltage and knowing the rate of charge the elapsed time could be accurately calculated.

Modern chronograph[edit]

The modern chronograph consists of two sensing areas framed by rods topped by diffusing screens or artificial lighting above (or below) along with optical sensors that detect the passage of the bullet. The time it takes the bullet to travel the distance between the sensors is measured electronically from which velocity is calculated and displayed.

Advanced ballistic chronographs include a type employing Doppler radar to measure bullets in free flight at various distances; another is a device mounted at the end of a barrel, which uses magnetic field sensors for the measurement of a bullet's velocity as it exits the muzzle.[8]

See also[edit]

References[edit]

  1. ^ Ingalls 1886, p. 17
  2. ^ Robins, Benjamin (1805), New Principles of Gunnery (New ed.), F. Wingrave
  3. ^ Bashforth 1866, p. 3, "only one observation on each round".
  4. ^ Bashforth 1866, p. 3, "Beyond 295 feet the gun was not sufficiently accurate".
  5. ^ d'Antoni, Alessandro Vittorio Papacino (1765), Esame Della Polvere, Torino: Nella Stamperia Reale
  6. ^ Prony (1805), "Report of a method of measuring the initial Velocity of Projectiles discharged from Fire-arms, both horizontally and with different Elevations, made to the Physical and Mathematical Class of the National Institute", in Nicholson, William (ed.), A Journal of Natural Philosophy, Chemistry and the Arts, vol. XI, London at page 42
    abridged from Journal des Mines No 92 p. 117, May 1804.
  7. ^ Bashforth 1866, pp. 12–13
  8. ^ "15 Best Shooting Chronographs". 22 November 2020.

Further reading[edit]

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