In
kinematics
Kinematics is a subfield of physics, developed in classical mechanics, that describes the Motion (physics), motion of points, Physical object, bodies (objects), and systems of bodies (groups of objects) without considering the forces that cause ...
, Burmester theory comprises
geometric techniques for synthesis of
linkages. It was introduced in the late 19th century by
Ludwig Burmester
Ludwig Ernst Hans Burmester (5 May 1840 – 20 April 1927) was a German kinematician and geometer.
His doctoral thesis (from German: ''About the elements of a theory of isophotes'') concerned lines on a surface defined by light direction. Aft ...
(1840–1927). His approach was to compute the geometric constraints of the linkage directly from the inventor's desired movement for a floating link. From this point of view a
four-bar linkage
In the study of mechanisms, a four-bar linkage, also called a four-bar, is the simplest closed- chain movable linkage. It consists of four bodies, called ''bars'' or ''links'', connected in a loop by four joints. Generally, the joints are configu ...
is a floating link that has two points constrained to lie on two circles.
Burmester began with a set of locations, often called ''poses'', for the floating link, which are viewed as snapshots of the constrained movement of this floating link in the device that is to be designed. The design of a
crank for the linkage now becomes finding a point in the moving floating link that when viewed in each of these specified positions has a
trajectory
A trajectory or flight path is the path that an object with mass in motion follows through space as a function of time. In classical mechanics, a trajectory is defined by Hamiltonian mechanics via canonical coordinates; hence, a complete traj ...
that lies on a circle. The dimension of the crank is the distance from the point in the floating link, called the circling point, to the center of the circle it travels on, called the center point. Two cranks designed in this way form the desired four-bar linkage.
This formulation of the mathematical synthesis of a four-bar linkage and the solution to the resulting equations is known as Burmester Theory.
[Hunt, K. H. ''Kinematic Geometry of Mechanisms''. Oxford Engineering Science Series, 1979.] The approach has been generalized to the synthesis of spherical and spatial mechanisms.
[J. M. McCarthy and G. S. Soh. ''Geometric Design of Linkages''. 2nd Edition, Springer, 2010](_blank)
Finite position synthesis
Geometric formulation
Burmester theory seeks points in a moving body that have trajectories that lie on a circle called circling points. The designer approximates the desired movement with a finite number of task positions; and Burmester showed that circling points exist for as many as five task positions. Finding these circling points requires solving five quadratic equations in five unknowns, which he did using techniques in descriptive geometry. Burmester's graphical constructions still appear in machine theory textbooks to this day.
Two positions: As an example consider a task defined by two positions of the coupler link, as shown in the figure. Choose two points A and B in the body, so its two positions define the segments A
1B
1 and A
2B
2. It is easy to see that A is a circling point with a center that is on the perpendicular bisector of the segment A
1A
2. Similarly, B is a circling point with a center that is any point on the perpendicular bisector of B
1B
2. A four-bar linkage can be constructed from any point on the two perpendicular bisectors as the fixed pivots and A and B as the moving pivots. The point P is clearly special, because it is a hinge that allows pure rotational movement of A
1B
1 to A
2B
2. It is called the relative displacement pole or also
instant centre of rotation
The instant center of rotation (also, instantaneous velocity center, instantaneous center, or instant center) is the point fixed to a body undergoing planar movement that has zero velocity at a particular instant of time. At this instant, the vel ...
.
Three positions: If the designer specifies three task positions, then points A and B in the moving body are circling points each with a unique center point. The center point for A is the center of the circle that passes through A
1, A
2 and A
3 in the three positions. Similarly, the center point for B is the center of the circle that passes through B
1, B
2 and B
3. Thus for three task positions, a four-bar linkage is obtained for every pair of points A and B chosen as moving pivots.
Four positions: Graphical solution to the synthesis problem becomes more interesting in the case of four task positions, because not every point in the body is a circling point. Four task positions yield six relative displacement poles, and Burmester selected four to form the opposite pole quadrilateral, which he then used to graphically generate the circling point curve (''Kreispunktcurven''). Burmester also showed that the circling point curve was a circular
cubic curve
In mathematics, a cubic plane curve is a plane algebraic curve defined by a cubic equation
:
applied to homogeneous coordinates for the projective plane; or the inhomogeneous version for the affine space determined by setting in such an eq ...
in the moving body.
Five positions: To reach five task positions, Burmester intersects the circling point curve generated by the opposite pole quadrilateral for a set of four of the five task positions, with the circling point curve generated by the opposite pole quadrilateral for different set of four task positions. Five poses imply ten relative displacement poles, which yields four different opposite pole quadrilaterals each having its own circling point curve. Burmester shows that these curves will intersect in as many as four points, called the ''Burmester points'', each of which will trace five points on a circle around a center point. Because two circling points define a four-bar linkage, these four points can yield as many as six four-bar linkages that guide the coupler link through the five specified task positions.
Algebraic formulation
Burmester's approach to the synthesis of a four-bar linkage can be formulated mathematically by introducing coordinate transformations
''i''">'T''''i''nbsp;=
''i'', d''i''">'A''''i'', d''i'' ''i'' = 1, ..., 5, where
'A''is a 2×2 rotation matrix and d is a 2×1 translation vector, that define task positions of a moving frame ''M'' specified by the designer.
The goal of the synthesis procedure is to compute the coordinates w = (''w''
''x'', ''w''
''y'') of a moving pivot attached to the moving frame ''M'' and the coordinates of a fixed pivot G = (''u'', ''v'') in the fixed frame ''F'' that have the property that w travels on a circle of radius ''R'' about G. The trajectory of w is defined by the five task positions, such that
:
Thus, the coordinates w and G must satisfy the five equations,
:
Eliminate the unknown radius ''R'' by subtracting the first equation from the rest to obtain the four quadratic equations in four unknowns,
:
These synthesis equations can be solved numerically to obtain the coordinates w = (''w''
''x'', ''w''
''y'') and G = (''u'', ''v'') that locate the fixed and moving pivots of a crank that can be used as part of a four-bar linkage. Burmester proved that there are at most four of these cranks, which can be combined to yield at most six four-bar linkages that guide the coupler through the five specified task positions.
It is useful to notice that the synthesis equations can be manipulated into the form,
:
which is the algebraic equivalent of the condition that the fixed pivot G lies on the perpendicular bisectors of each of the four segments W
''i'' − W
1, ''i'' = 2, ..., 5.
Input-output synthesis
One of the more common applications of a
four-bar linkage
In the study of mechanisms, a four-bar linkage, also called a four-bar, is the simplest closed- chain movable linkage. It consists of four bodies, called ''bars'' or ''links'', connected in a loop by four joints. Generally, the joints are configu ...
appears as a rod that connects two
levers
A lever is a simple machine consisting of a beam or rigid rod pivoted at a fixed hinge, or ''fulcrum''. A lever is a rigid body capable of rotating on a point on itself. On the basis of the locations of fulcrum, load and effort, the lever is di ...
, so that rotation of the first lever drives the rotation of the second lever. The levers are
hinged
A hinge is a mechanical bearing that connects two solid objects, typically allowing only a limited angle of rotation between them. Two objects connected by an ideal hinge rotate relative to each other about a fixed axis of rotation: all other ...
to a ground frame and are called the ''input'' and ''output'' ''
cranks'', and the
connecting rod
A connecting rod, also called a 'con rod', is the part of a piston engine which connects the piston to the crankshaft. Together with the crank, the connecting rod converts the reciprocating motion of the piston into the rotation of the cranksh ...
is the called the ''coupler'' link. Burmester's approach to the design of a four-bar linkage can be used to locate the coupler so that five specified angles of the input crank result in five specified angles of the output crank.
Let ''θ''
''i'', ''i'' = 1, ..., 5 be the angular positions of the input crank, and let ''ψ''
''i'', ''i'' = 1, ..., 5 be the corresponding angles of the output crank. For convenience locate the fixed pivot of the input crank at the origin of the fixed frame, O = (0, 0), and let the fixed pivot of the output crank be located at C = (''c''
''x'', ''c''
''y''), which is chosen by the designer. The unknowns in this synthesis problem are the coordinates g = (''g''
''x'', ''g''
''y'') of the coupler attachment to the input crank and the coordinates w = (''w''
''x'', ''w''
''y'') of the attachment to the output crank, measured in their respective reference frames.
While the coordinates of w and g are not known their trajectories in the fixed frame are given by,
:
where
(•)denotes the rotation by the given angle.
The coordinates of w and g must satisfy the five constraint equations,
:
Eliminate the unknown coupler length ''R'' by subtracting the first equation from the rest to obtain the four quadratic equations in four unknowns,
:
These synthesis equations can be solved numerically to obtain the coordinates w = (''w''
''x'', ''w''
''y'') and g = (''g''
''x'', ''g''
''y'') that locate the coupler of the four-bar linkage.
This formulation of the input-output synthesis of a four-bar linkage is an inversion of finite-position synthesis, where the movement of the output crank relative to the input crank is specified by the designer. From this viewpoint the ground link OC is a crank that satisfies the specified finite positions of the movement of the output crank relative to the input crank, and Burmester's results show that its existence guarantees the presence of at least one coupler link. Furthermore, Burmester's results show that there may be as many as three of these coupler links that provide the desired input-output relationship.
References
Further reading
*
Ian R. Porteous (2001) ''Geometric Differentiation'', § 3.5 Burmester Points, page 58,
Cambridge University Press
Cambridge University Press is the university press of the University of Cambridge. Granted letters patent by Henry VIII of England, King Henry VIII in 1534, it is the oldest university press
A university press is an academic publishing hou ...
.
M. Ceccarelli and T. Koetsier, Burmester and Allievi: ''A Theory and Its Application for Mechanism Design at the End of the 19th Century'', ASME 2006
External links
R. E. Kaufman provides links to videos of KINSYN which is the original interactive graphics software implementing Burmester's four position synthesis.The University of Minnesota Lincages software implements Burmester's four position synthesis.The Synthetica 3.0 software applies Burmester's approach to the synthesis of spatial linkages.Linkage synthesis on mechanicaldesign101.com provides a Mathematica notebook for Burmester's five position synthesis.
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Linkages (mechanical)