Peaucellier-Lipkin_linkage References

The Peaucellier–Lipkin linkage (or Peaucellier–Lipkin cell, or Peaucellier–Lipkin inversor), invented in 1864, was the first true planar straight line mechanism – the first planar linkage capable of transforming rotary motion into perfect straight-line motion, and vice versa. It is named after Charles-Nicolas Peaucellier (1832–1913), a French army officer, and Yom Tov Lipman Lipkin (1846–1876), a Lithuanian Jew and son of the famed Rabbi Israel Salanter.^[1]^[2]

Until this invention, no planar method existed of converting exact straight-line motion to circular motion, without reference guideways. In 1864, all power came from steam engines, which had a piston moving in a straight-line up and down a cylinder. This piston needed to keep a good seal with the cylinder in order to retain the driving medium, and not lose energy efficiency due to leaks. The piston does this by remaining perpendicular to the axis of the cylinder, retaining its straight-line motion. Converting the straight-line motion of the piston into circular motion was of critical importance. Most, if not all, applications of these steam engines, were rotary.

The mathematics of the Peaucellier–Lipkin linkage is directly related to the inversion of a circle.

Earlier Sarrus linkage

There is an earlier straight-line mechanism, whose history is not well known, called the Sarrus linkage. This linkage predates the Peaucellier–Lipkin linkage by 11 years and consists of a series of hinged rectangular plates, two of which remain parallel but can be moved normally to each other. Sarrus' linkage is of a three-dimensional class sometimes known as a space crank, unlike the Peaucellier–Lipkin linkage which is a planar mechanism.

Geometry

Geometric diagram of a Peaucellier linkage

In the geometric diagram of the apparatus, six bars of fixed length can be seen: $OA$ , $OC$ , $AB$ , $BC$ , $CD$ , $DA$ . The length of $OA$ is equal to the length of $OC$ , and the lengths of $AB$ , $BC$ , $CD$ , and $DA$ are all equal forming a rhombus. Also, point $O$ is fixed. Then, if point $B$ is constrained to move along a circle (for example, by attaching it to a bar with a length half way between $O$ and $B$ ; path shown in red) which passes through $O$ , then point $D$ will necessarily have to move along a straight line (shown in blue). In contrast, if point $B$ were constrained to move along a line (not passing through $O$ ), then point $D$ would necessarily have to move along a circle (passing through $O$ ).

Mathematical proof of concept

Collinearity

First, it must be proven that points $O$ , $B$ , $D$ are collinear. This may be easily seen by observing that the linkage is mirror-symmetric about line $OD$ , so point $B$ must fall on that line.

More formally, triangles $△ BAD$ and $△ BCD$ are congruent because side $BD$ is congruent to itself, side $BA$ is congruent to side $BC$ , and side $AD$ is congruent to side $CD$ . Therefore, angles $∠ ABD$ and $∠ CBD$ are equal.

Next, triangles $△ OBA$ and $△ OBC$ are congruent, since sides $OA$ and $OC$ are congruent, side $OB$ is congruent to itself, and sides $BA$ and $BC$ are congruent. Therefore, angles $∠ OBA$ and $∠ OBC$ are equal.

Finally, because they form a complete circle, we have

\angle OBA+\angle ABD+\angle DBC+\angle CBO=360^{\circ }

but, due to the congruences, $∠ OBA = ∠ OBC$ and $∠ DBA = ∠ DBC$ , thus

{\begin{aligned}&2\times \angle OBA+2\times \angle DBA=360^{\circ }\\&\angle OBA+\angle DBA=180^{\circ }\end{aligned}}

therefore points $O$ , $B$ , and $D$ are collinear.

Inverse points

Let point $P$ be the intersection of lines $AC$ and $BD$ . Then, since $ABCD$ is a rhombus, $P$ is the midpoint of both line segments $BD$ and $AC$ . Therefore, length $BP$ = length $PD$ .

Triangle $△ BPA$ is congruent to triangle $△ DPA$ , because side $BP$ is congruent to side $DP$ , side $AP$ is congruent to itself, and side $AB$ is congruent to side $AD$ . Therefore, angle $∠ BPA$ = angle $∠ DPA$ . But since $∠ BPA + ∠ DPA = 180°$ , then $2 \times ∠ BPA = 180°$ , $∠ BPA = 90°$ , and $∠ DPA = 90°$ .

Let:

{\begin{aligned}&x=\ell _{BP}=\ell _{PD}\\&y=\ell _{OB}\\&h=\ell _{AP}\end{aligned}}

Then:

\ell _{OB}\cdot \ell _{OD}=y(y+2x)=y^{2}+2xy

{\ell _{OA}}^{2}=(y+x)^{2}+h^{2}

(due to the Pythagorean theorem)

{\ell _{OA}}^{2}=y^{2}+2xy+x^{2}+h^{2}

(same expression expanded)

{\ell _{AD}}^{2}=x^{2}+h^{2}

(Pythagorean theorem)

{\ell _{OA}}^{2}-{\ell _{AD}}^{2}=y^{2}+2xy=\ell _{OB}\cdot \ell _{OD}

Since $OA$ and $AD$ are both fixed lengths, then the product of $OB$ and $OD$ is a constant:

\ell _{OB}\cdot \ell _{OD}=k^{2}

and since points $O$ , $B$ , $D$ are collinear, then $D$ is the inverse of $B$ with respect to the circle $(O, k)$ with center $O$ and radius $k$ .

Inversive geometry

Thus, by the properties of inversive geometry, since the figure traced by point $D$ is the inverse of the figure traced by point $B$ , if $B$ traces a circle passing through the center of inversion $O$ , then $D$ is constrained to trace a straight line. But if $B$ traces a straight line not passing through $O$ , then $D$ must trace an arc of a circle passing through $O$ . Q.E.D.

A typical driver

Peaucellier–Lipkin linkages (PLLs) may have several inversions. A typical example is shown in the opposite figure, in which a rocker-slider four-bar serves as the input driver. To be precise, the slider acts as the input, which in turn drives the right grounded link of the PLL, thus driving the entire PLL.

Historical notes

Sylvester (Collected Works, Vol. 3, Paper 2) writes that when he showed a model to Kelvin, he “nursed it as if it had been his own child, and when a motion was made to relieve him of it, replied ‘No! I have not had nearly enough of it—it is the most beautiful thing I have ever seen in my life.’”

Cultural references

A monumental-scale sculpture implementing the linkage in illuminated struts is on permanent exhibition in Eindhoven, Netherlands. The artwork measures 22 by 15 by 16 metres (72 ft × 49 ft × 52 ft), weighs 6,600 kilograms (14,600 lb), and can be operated from a control panel accessible to the general public.^[3]

References

^ "Mathematical tutorial of the Peaucellier–Lipkin linkage". Kmoddl.library.cornell.edu. Retrieved 2011-12-06.
^ Taimina, Daina. "How to draw a straight line by Daina Taimina". Kmoddl.library.cornell.edu. Retrieved 2011-12-06.
^ "Just because you are a character, doesn't mean you have character". Ivo Schoofs. Retrieved 2017-08-14.

Bibliography

Ogilvy, C. S. (1990), Excursions in Geometry, Dover, pp. 46–48, ISBN 0-486-26530-7
Bryant, John; Sangwin, Chris (2008). How round is your circle? : where engineering and mathematics meet. Princeton: Princeton University Press. pp. 33–38, 60–63. ISBN 978-0-691-13118-4. — proof and discussion of Peaucellier–Lipkin linkage, mathematical and real-world mechanical models
Coxeter HSM, Greitzer SL (1967). Geometry Revisited. Washington: MAA. pp. 108–111. ISBN 978-0-88385-619-2. (and references cited therein)
Hartenberg, R.S. & J. Denavit (1964) Kinematic synthesis of linkages, pp 181–5, New York: McGraw–Hill, weblink from Cornell University.
Johnson RA (1960). Advanced Euclidean Geometry: An elementary treatise on the geometry of the triangle and the circle (reprint of 1929 edition by Houghton Mifflin ed.). New York: Dover Publications. pp. 46–51. ISBN 978-0-486-46237-0.
Wells D (1991). The Penguin Dictionary of Curious and Interesting Geometry. New York: Penguin Books. p. 120. ISBN 0-14-011813-6.

External links

How to Draw a Straight Line, online video clips of linkages with interactive applets.
How to Draw a Straight Line, historical discussion of linkage design
Interactive Java Applet with proof.
Java animated Peaucellier–Lipkin linkage
Jewish Encyclopedia article on Lippman Lipkin and his father Israel Salanter
Peaucellier Apparatus features an interactive applet
A simulation using the Molecular Workbench software
A related linkage called Hart's Inversor.
Modified Peaucellier robotic arm linkage (Vex Team 1508 video)

[1] "Mathematical tutorial of the Peaucellier–Lipkin linkage". Kmoddl.library.cornell.edu. Retrieved 2011-12-06.

[2] Taimina, Daina. "How to draw a straight line by Daina Taimina". Kmoddl.library.cornell.edu. Retrieved 2011-12-06.

[Schoofs-3] "Just because you are a character, doesn't mean you have character". Ivo Schoofs. Retrieved 2017-08-14.

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