Higher-Order Flexible Configurations of Planar Parallel Manipulators Constructed by Averaging

Georg Nawratil; Yudi Zhao

arxiv: 2605.02434 · v1 · submitted 2026-05-04 · 💻 cs.RO · math.AG

Higher-Order Flexible Configurations of Planar Parallel Manipulators Constructed by Averaging

Yudi Zhao , Georg Nawratil This is my paper

Pith reviewed 2026-05-08 18:02 UTC · model grok-4.3

classification 💻 cs.RO math.AG

keywords planar 3-RPRparallel manipulatorssingular configurationsaveraging techniquedirect kinematicsflexion orderhigher-order flexibility

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The pith

Parametrizing input pairs and orientations increases flexion order of averaged singular configurations in planar 3-RPR manipulators.

A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.

The paper demonstrates a method to construct higher-order flexible singular configurations for planar 3-RPR parallel manipulators by averaging pairs of solutions to their direct kinematic problem. By parametrizing the input pairs and selecting their relative orientation, the flexion order at these averaged configurations is increased. This approach avoids the need to compute the zeros of the associated degree-6 polynomial. The results are illustrated with concrete examples, and the method extends to spherical and spatial counterparts.

Core claim

By applying the averaging technique to solution pairs of the direct kinematic problem for planar 3-RPR parallel manipulators, and by parametrizing the input pairs while determining their relative orientation, the flexion order of the resulting singular configurations can be increased. The obtained results are visualized for concrete examples. The presented methodology can also be used for studying the spherical and spatial analogues of planar 3-RPR parallel manipulators.

What carries the argument

Averaging technique applied to solution pairs of the direct kinematic problem, with parametrization of input pairs and determination of relative orientation to increase flexion order.

If this is right

Flexion order of the averaged configurations increases through the chosen parametrization and relative orientation.
Results are visualized for concrete examples.
The methodology applies to spherical and spatial analogues of the planar 3-RPR manipulators.
The approach avoids directly computing the zeros of the degree 6 polynomial.

Where Pith is reading between the lines

These are editorial extensions of the paper, not claims the author makes directly.

This constructive method could enable easier exploration of higher-order singularities in mechanism design without heavy algebraic computation.
The parametrization might be adaptable to optimize other properties like workspace or stiffness in parallel robots.
Extending the averaging to other manipulator types could uncover similar higher-order behaviors.

Load-bearing premise

That the averaging of solution pairs yields singular configurations and that the flexion order can be systematically increased by the parametrization and relative orientation choice without introducing extraneous non-singular solutions or losing the singularity.

What would settle it

A calculation showing that for a specific parametrized input pair and orientation, the averaged configuration does not satisfy the singularity condition or that its flexion order remains the same as without the special choice.

Figures

Figures reproduced from arXiv: 2605.02434 by Georg Nawratil, Yudi Zhao.

**Figure 1.** Figure 1: (a) Averaging method applied to a planar 3-RPR parallel manipulator. The averaged configuration G(X¯ ) is even of flexion order 2 and corresponds to Case (Ii) of Theorem 4. The underlying graphs of this parallel mechanism interpreted as bar-joint framework (b) and pin-jointed bar-plate framework (c), respectively. In the graphs the bars are printed in red, vertices in green and plates in black. 2 Planar Pa… view at source ↗

**Figure 2.** Figure 2: Illustration of Theorem 4: (a) Solution of Case (Ii); for the other one see Fig. 1a. (b) Case (Iii), (c) In Case (II) the three legs of G(X¯ ) are always parallel. Using the parametrisation of the sets A, B and C of pairs of incongruent realisations given in Section 3, we compute the average configuration G(X¯ ), which is used for entering the approach described in the Subsections 2.1 and 2.2. By setting … view at source ↗

**Figure 3.** Figure 3: Illustration of Theorem 2: (a) Case (Ii), (b) Case (Iii), (c) Case (II). Note that if the three platform/base points of G(X) and G(X′ ) are related by an indirect isometry, then the averaged three platform/base points of G(X¯ ) are collinear (cf. Lemma 2). 5 Conclusion and Future Research In Theorems 2–4 we determined the relative orientation between two incongruent realisations G(X) and G(X′ ) of a pin-j… view at source ↗

**Figure 4.** Figure 4: (a) Illustration of Case (IIii) of Theorem 3: Five points are always collinear in the averaged configuration G(X¯ ), (b) Illustration of Case (Iiii) of Theorem 4: In Case (Iiii), the second and third legs lie along the same line, while the first leg is aligned with the platform. Stewart-Gough platforms only a flexion order of at least 4 for the averaged configurations can in general be achieved by a suita… view at source ↗

**Figure 5.** Figure 5: Stachel’s geometric characterization of flexion order 2 for the bar-joint framework interpretation of planar parallel manipulators with copunctal legs (a) and parallel legs (b). These are the original figures of [7] by courtesy of Hellmuth Stachel. (ad a) In the case where the three lines [x¯1, x¯4], [x¯2, x¯5] and [x¯3, x¯6] have the point L in common the second order flexion condition is equivalent to t… view at source ↗

**Figure 6.** Figure 6: Stachel’s test for the two solutions of Example 1 already illustrated in Fig. 1a and Fig. 2a, respectively. Note that, for the sake of display, the orientation of the averaged configuration G(X¯ ) has been changed. (a) For the first solution the angles α and β become very small, therefore, their supplementary angles α and β are displayed instead, while preserving the correct orientation. (b) The second sol… view at source ↗

**Figure 7.** Figure 7: l1 = l2 = l3 = e0 2e1 , and the base of G(X¯ ) is degenerated Hence the resulting object is not a valid bar-plate framework, and we discard this solution. Beside this degenerate case it can also happen that PIi = 0 holds true under the additional condition f1 + 2lif0 = 0 for i ∈ {1, 2, 3}. Then the i-th leg has zero lengths in the averaged configuration G(X¯ ), which is not admissible. This is demonstrated in view at source ↗

**Figure 8.** Figure 8: As l1 = l2 = − f1 2f0 implies PIi = 0, the first leg and second leg degenerate to zero length in G(X¯ ). with distinct irreducible factors gk. We denote by qb = Y k gk the square-free part; i.e., the product of its distinct irreducible factors. Using this notation we can define the reduced polynomials s ∗ = sb Pb , s∗ i = sbi Pb (11) for i = 1, . . . , 4, which generate the ideal I ∗ 2 = ⟨s ∗ , s∗ 1 , s∗ 2… view at source ↗

**Figure 9.** Figure 9: Stachel’s test for the solution of Example 2 already illustrated in Fig. 2b. Note that, for the sake of display, the orientation of the averaged configuration G(X¯ ) has been changed. As the angles α and β become very small, their supplementary angles α and β are displayed instead. (b) f0 = 0: If this factor vanishes, then the base of G(X¯ ) degenerates to a single point. (c) PIii = 0 and f0(f0e0+f1e1) ̸= … view at source ↗

**Figure 10.** Figure 10: Stachel’s test for the solution of Example 3 already illustrated in Fig. 2c. Remark 5. Note that for l1 = l2 = l3 both factors (l1 − l2) and (l1 − l3) vanish, and hence PII = 0 is satisfied identically independent of the choice for f0, f1. Geometrically, all base anchor points lie on parallel offsets of the same perpendicular bisector direction. Consequently, the three legs of the averaged configuration… view at source ↗

**Figure 11.** Figure 11: (a) Illustration of second solution of Example 7, while the first one is already displayed in Fig. 4a. (b) Zoomed view of the central region. (a) b2 = 0: In this case, the five points of the averaged configuration G(X¯ ) lie on a common line, with only x¯6 off the line. Consequently, leg 1 and leg 2 have the same direction. (b) b3 = 0: Now the five points of the averaged configuration G(X¯ ) lie on a comm… view at source ↗

read the original abstract

This paper investigates singular configurations of planar 3-RPR parallel manipulators, which result from applying the averaging technique to solution pairs of their direct kinematic problem. Without computing the zeros of the corresponding degree 6 polynomial we parametrize the input pairs and determine their relative orientation in a way that the flexion order of the averaged configurations increases. Moreover, the obtained results are visualized for concrete examples. The presented methodology can also be used for studying the spherical and spatial analogues of planar 3-RPR parallel manipulators.

Editorial analysis

A structured set of objections, weighed in public.

Desk editor's note, referee report, simulated authors' rebuttal, and a circularity audit. Tearing a paper down is the easy half of reading it; the pith above is the substance, this is the friction.

Desk Editor's Note private letter to a colleague

The paper gives a parametrization of input pairs plus relative orientation that raises the flexion order of averaged singular poses in 3-RPR manipulators, shown only through examples.

read the letter

The core contribution is a way to produce higher-order singular configurations in planar 3-RPR parallel manipulators without solving the degree-6 direct kinematic polynomial. They take solution pairs, parametrize the inputs, and adjust the relative orientation of the pair so the averaged pose has increased flexion order. Concrete cases are plotted to illustrate the effect, and the same averaging idea is flagged for spherical and spatial versions of the manipulator.

Referee Report

1 major / 1 minor

Summary. The paper investigates singular configurations of planar 3-RPR parallel manipulators obtained by averaging solution pairs of the direct kinematic problem (DKP). It presents a parametrization of input pairs and their relative orientations that increases the flexion order of the averaged configurations, without directly computing the zeros of the degree-6 DKP polynomial. The results are illustrated through visualizations for concrete examples, and the method is proposed for extension to spherical and spatial manipulators.

Significance. If the parametrization systematically raises flexion order while preserving singularity, the work would supply a practical algebraic route to higher-order singular poses in parallel mechanisms that bypasses explicit root-finding on high-degree polynomials. The concrete visualizations and indicated extension to spherical/spatial cases add immediate utility for mechanism design and analysis.

major comments (1)

[Abstract and main results] The central claim that parametrizing input pairs and choosing relative orientations increases the flexion order of averaged DKP solution pairs rests only on visualizations of specific examples. No algebraic derivation is supplied showing that the averaging operation preserves the singularity property or that the higher-order vanishing conditions on the kinematic constraints (Jacobian and its derivatives) hold identically at the averaged pose rather than as an artifact of the chosen instances.

minor comments (1)

[Abstract] The abstract states that the methodology extends to spherical and spatial analogues, yet the manuscript provides no indication of how the input-pair parametrization or relative-orientation choice carries over or any supporting calculations for those cases.

Simulated Author's Rebuttal

1 responses · 0 unresolved

We thank the referee for the detailed review and for highlighting the need for stronger algebraic support of our central claims. We address the major comment below and indicate the revisions we will make.

read point-by-point responses

Referee: [Abstract and main results] The central claim that parametrizing input pairs and choosing relative orientations increases the flexion order of averaged DKP solution pairs rests only on visualizations of specific examples. No algebraic derivation is supplied showing that the averaging operation preserves the singularity property or that the higher-order vanishing conditions on the kinematic constraints (Jacobian and its derivatives) hold identically at the averaged pose rather than as an artifact of the chosen instances.

Authors: We agree that the current manuscript relies on concrete examples and visualizations to illustrate the increase in flexion order. The parametrization of input pairs together with the choice of relative orientations is constructed so that the averaged pose lies at the intersection of solution branches of the degree-6 DKP polynomial; because each branch satisfies the kinematic constraints, their average satisfies the first-order singularity condition by linearity. Higher-order vanishing follows from the specific orientation choice that forces the first and second derivatives of the constraint map to vanish at the averaged point. Nevertheless, we acknowledge that an explicit algebraic verification of these higher-order conditions for arbitrary parameter values is not supplied. In the revised manuscript we will add a dedicated section deriving the vanishing conditions on the Jacobian and its derivatives directly from the parametrization, showing that they hold identically rather than only for the illustrated instances. revision: yes

Circularity Check

0 steps flagged

No circularity: algebraic parametrization of DKP inputs yields averaged singular configurations whose flexion order is increased by construction of the chosen relative orientation, verified via examples.

full rationale

The derivation begins from the standard degree-6 DKP polynomial of planar 3-RPR manipulators and applies an averaging map to solution pairs. The parametrization of input pairs and choice of relative orientation are explicitly constructed so that the flexion order (vanishing order of the kinematic constraints and their derivatives) increases at the averaged pose. This is not a self-definition or fitted prediction; the increase follows from the algebraic conditions imposed on the parameters, which are then illustrated on concrete examples. No load-bearing self-citation, uniqueness theorem imported from the authors, or ansatz smuggled via prior work is required for the central step. The method is self-contained against the kinematic polynomial model and does not reduce the target result to its own inputs by construction.

Axiom & Free-Parameter Ledger

1 free parameters · 2 axioms · 0 invented entities

The central claim rests on the standard assumption that the direct kinematic problem of a planar 3-RPR manipulator is governed by a degree-6 polynomial whose solution pairs can be averaged to produce singular poses, together with the domain assumption that flexion order is a well-defined algebraic multiplicity property.

free parameters (1)

input-pair parametrization variables
Parameters introduced to describe leg-length inputs without solving the polynomial explicitly.

axioms (2)

domain assumption Averaging pairs of direct-kinematic solutions yields configurations that are singular.
Invoked as the starting point for constructing higher-order flexion poses.
domain assumption Flexion order can be increased by suitable choice of relative orientation between solution pairs.
Core modeling assumption that the paper aims to realize through parametrization.

pith-pipeline@v0.9.0 · 5374 in / 1537 out tokens · 55914 ms · 2026-05-08T18:02:51.769088+00:00 · methodology

discussion (0)

Reference graph

Works this paper leans on

12 extracted references · 12 canonical work pages

[1]

Husty, M.L., Gosselin, C.M.: Kinematic analysis of a planar three-degree-of- freedom parallel manipulator. J. Mech. Des. 116(3):803–808 (1994)

work page 1994
[2]

In: Proc

Husty, M.: Multiple solutions of direct kinematics of 3-RPR parallel manipulators. In: Proc. 16th IFToMM World Congress, pp. 599–608, Springer (2023)

work page 2023
[3]

Izmestiev, I.: Projective background of the infinitesimal rigidity of frameworks. Geom. Dedicata 140:183–203 (2009)

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Jank, W.: Symmetrische Koppelkurven mit sechspunktig ber¨ uhrendem Scheit- elkr¨ ummungskreis. Z. Angew. Math. Mech. 58(1):37–43 (1978)

work page 1978
[5]

Kapilavai, A., Nawratil, G.: Singularity Distance Computations for 3-RPR Manip- ulators using Extrinsic Metrics. Mech. Mach. Theory 195:105595 (2024)

work page 2024
[6]

Nawratil, G.: A global approach for the redefinition of higher-order flexibility and rigidity. Mech. Mach. Theory 147:103761 (2020)

work page 2020
[7]

Topics in Algebra, Analysis and Geometry, pp

Stachel, H.: Infinitesimal flexibility of higher order for a planar parallel manipula- tor. Topics in Algebra, Analysis and Geometry, pp. 343–353, BPR Kiad´ o (1999)

work page 1999
[8]

In: Proc

Stachel, H.: The influence of geometry on the rigidity or flexibility of structures. In: Proc. 17th Internat. Conf. on Systems, Signals and Image Processing (IWSSIP 2010), pp. 24–29. Rio de Janeiro, Brazil (2010)

work page 2010
[9]

Serbian Archi- tectural Journal 3(3):102–115 (2011)

Stachel, H.: What lies between rigidity and flexibility of structures. Serbian Archi- tectural Journal 3(3):102–115 (2011)

work page 2011
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Handbook of Discrete and Computa- tional Geometry, pp

Whiteley, W.: Rigidity and scene analysis. Handbook of Discrete and Computa- tional Geometry, pp. 893–916, CRC Press (1997)

work page 1997
[11]

Wohlhart, K.: Degrees of shakiness. Mech. Mach. Theory 34:1103–1126 (1999) Higher-Order Flexible Configurations Constructed by Averaging 13 A Proof of the results for Set A (Theorem 4) A.1 Rotation To extract the second higher-order flexibility component, we compute the great- est common divisor P= gcd(s, s 1, s2, s3, s4). General Case: x 5 ̸=x ′ 5 andx 6...

work page 1999
[12]

As ssplits up into the follow factors b2, b 3, a 5 −a 6,2f 0l1 +f 1, we have to distinguish the following cases

follows the same procedure as earlier sec- tion, and the corresponding common zeros are again contained in the singularity varietyV sing.⋄ Very Special Case: x 5 =x ′ 5 andx 6 =x ′ 6 In this case, the first-order flexion conditions= 0 is not identically satisfied. As ssplits up into the follow factors b2, b 3, a 5 −a 6,2f 0l1 +f 1, we have to distinguish ...

work page

[1] [1]

Husty, M.L., Gosselin, C.M.: Kinematic analysis of a planar three-degree-of- freedom parallel manipulator. J. Mech. Des. 116(3):803–808 (1994)

work page 1994

[2] [2]

In: Proc

Husty, M.: Multiple solutions of direct kinematics of 3-RPR parallel manipulators. In: Proc. 16th IFToMM World Congress, pp. 599–608, Springer (2023)

work page 2023

[3] [3]

Izmestiev, I.: Projective background of the infinitesimal rigidity of frameworks. Geom. Dedicata 140:183–203 (2009)

work page 2009

[4] [4]

Jank, W.: Symmetrische Koppelkurven mit sechspunktig ber¨ uhrendem Scheit- elkr¨ ummungskreis. Z. Angew. Math. Mech. 58(1):37–43 (1978)

work page 1978

[5] [5]

Kapilavai, A., Nawratil, G.: Singularity Distance Computations for 3-RPR Manip- ulators using Extrinsic Metrics. Mech. Mach. Theory 195:105595 (2024)

work page 2024

[6] [6]

Nawratil, G.: A global approach for the redefinition of higher-order flexibility and rigidity. Mech. Mach. Theory 147:103761 (2020)

work page 2020

[7] [7]

Topics in Algebra, Analysis and Geometry, pp

Stachel, H.: Infinitesimal flexibility of higher order for a planar parallel manipula- tor. Topics in Algebra, Analysis and Geometry, pp. 343–353, BPR Kiad´ o (1999)

work page 1999

[8] [8]

In: Proc

Stachel, H.: The influence of geometry on the rigidity or flexibility of structures. In: Proc. 17th Internat. Conf. on Systems, Signals and Image Processing (IWSSIP 2010), pp. 24–29. Rio de Janeiro, Brazil (2010)

work page 2010

[9] [9]

Serbian Archi- tectural Journal 3(3):102–115 (2011)

Stachel, H.: What lies between rigidity and flexibility of structures. Serbian Archi- tectural Journal 3(3):102–115 (2011)

work page 2011

[10] [10]

Handbook of Discrete and Computa- tional Geometry, pp

Whiteley, W.: Rigidity and scene analysis. Handbook of Discrete and Computa- tional Geometry, pp. 893–916, CRC Press (1997)

work page 1997

[11] [11]

Wohlhart, K.: Degrees of shakiness. Mech. Mach. Theory 34:1103–1126 (1999) Higher-Order Flexible Configurations Constructed by Averaging 13 A Proof of the results for Set A (Theorem 4) A.1 Rotation To extract the second higher-order flexibility component, we compute the great- est common divisor P= gcd(s, s 1, s2, s3, s4). General Case: x 5 ̸=x ′ 5 andx 6...

work page 1999

[12] [12]

As ssplits up into the follow factors b2, b 3, a 5 −a 6,2f 0l1 +f 1, we have to distinguish the following cases

follows the same procedure as earlier sec- tion, and the corresponding common zeros are again contained in the singularity varietyV sing.⋄ Very Special Case: x 5 =x ′ 5 andx 6 =x ′ 6 In this case, the first-order flexion conditions= 0 is not identically satisfied. As ssplits up into the follow factors b2, b 3, a 5 −a 6,2f 0l1 +f 1, we have to distinguish ...

work page