Geometric Approach to the Realization of Planar Elastic Behaviors With Mechanisms Having Four Elastic Components

Compliant behavior is widely used in robotic manipulation to provide force regulation to avoid excessive forces when in contact with a physical constraint. If displacements from equilibrium are small, a compliant behavior can be described by the linear relationship between the applied force (wrench) and displacement (twist). The linear mapping is characterized by a symmetric positive semi-definite (PSD) matrix, the stiffness matrix K, or its inverse, the compliance matrix C.

A general compliance can be modeled as an elastically suspended rigid body. The elastic suspension can be attained by using a compliant mechanism having elastic components connected in series or in parallel (as illustrated in Fig. 1). To realize a compliance, both the mechanism configuration (i.e., the location of the elastic joints of a serial mechanism or the location of the springs in a parallel mechanism) and the elastic behavior of each joint/spring must be identified. It is known [1–3] that, for a given compliant behavior, there are infinitely many mechanisms and sets of joint/spring elastic properties that achieve the desired behavior. In application, each joint/spring property can be attained using a conventional (constant) torsional/line spring. Time-varying elastic behaviors can be obtained using variable stiffness actuation (VSA) [4]. Identification of the mechanism geometry required to realize a given compliance (provided that each joint/spring elastic property is selectable) is the primary motivation for this work.

Although the use of VSAs increases the realizable space of compliances for a mechanism, a significant amount of compliances cannot be attained due to the mechanism kinematic mobility [5–7]. To increase the size of the space of realizable elastic behaviors further, redundant mechanisms can be used. A redundant mechanism allows the mechanism configuration to vary without changing the end-effector pose. A redundant mechanism is particularly useful when the length of each link in a mechanism is limited or the work space is constrained by obstacles.

This paper addresses the passive realization of any selected planar elastic behavior with simple redundant elastic manipulators having four elastic components. Serial mechanisms considered (Fig. 1(a)) consist of rigid links connected by revolute joints, each loaded with a spring (joint compliance). The parallel mechanisms considered (Fig. 1(b)) consist of springs, each independently connected to the compliantly suspended body. In the realization, only passive springs, i.e., elastic behaviors that can be achieved without closed-loop control, are considered. Thus, each joint compliance/stiffness must be positive. The physical significance of the realization conditions for simple elastic mechanisms provides a foundation for the design of more complicated elastic mechanisms.

In spatial compliance analysis, screw theory [8–11] and Lie groups [12] have been used.

In previous work in the realization of spatial compliances, synthesis of elastic behaviors with simple mechanisms (i.e., parallel and serial mechanisms without helical joints) was addressed [1,2,13,14]. The realization of an arbitrary spatial stiffness matrix with a parallel mechanism having both simple springs and screw springs was presented in Refs. [14–16]. A decomposition with invariant properties [17,18] for the purpose of realization with simple and screw springs was identified. The duality between the stiffness matrix realized with a parallel mechanism and the compliance matrix realized with a serial mechanism was identified in Ref. [3]. In these approaches, the realization of a compliant behavior was based on an algebraic decomposition of the stiffness/compliance matrix into rank-1 components. These approaches did not consider mechanism geometry in the decomposition.

More recently, realizations of spatial compliant behaviors with some considerations for the mechanism geometry were presented [19–22]. In Ref. [23], a procedure to synthesize an arbitrary planar stiffness with a symmetric four-spring parallel mechanism was developed.

In recent work, the realization of translational compliances with 3R serial mechanisms having specified link lengths has been addressed [24]. In Ref. [5], conditions on mechanism link lengths to achieve all planar translational compliances were identified and synthesis procedures to realize an arbitrary 2 × 2 compliance matrix were developed. The results obtained in Ref. [5] for 3R mechanisms were then extended to general planar serial mechanisms with three (revolute and/or prismatic) joints [6]. In Refs. [25] and [26], synthesis of isotropic compliance in E(2) and E(3) were addressed.

In our most recent work [7], a geometric construction-based approach to the design of three-component simple elastic mechanisms that realize general planar elastic behavior was described. The three-component cases correspond to nonredundant mechanisms. In a three-joint serial mechanism, the locations of the three joints form a triangle. Necessary and sufficient conditions for the realization of a given compliance require that a force acting along one side of the triangle results in a twist having its instantaneous center located at the vertex opposite to that side of the triangle. The same realization condition applies to a three-spring parallel mechanism in which the three wrench axes form a triangle. As such, the space of compliant behaviors realized at a given configuration is very limited even if each joint compliance/stiffness can vary infinitely.

This paper addresses compliance realization with redundant mechanisms having four elastic components. Due to the mechanism's increase in the degree-of-freedom, a much larger space of elastic behaviors can be realized. The space is increased for two reasons. First, as previously stated, redundancy allows the mechanism configuration to vary when the end-effector pose is specified. Second, even when the mechanism configuration is not allowed to vary, the restrictions on elastic behavior are less conservative than the three-component cases.

This paper addresses the passive realization of an arbitrary planar (3 × 3) elastic behavior with a redundant compliant mechanism. The mechanisms considered are four-joint serial mechanisms and four-spring parallel mechanisms for which each joint compliance or spring stiffness is selectable. Requirements on mechanism geometry to realize a given elastic behavior are identified. Geometric construction-based synthesis procedures are developed. These procedures enable one to select the geometry of each elastic component from the infinite, but restricted set of options available.

The paper is outlined as follows: In Sec. 2, the theoretical background for planar compliance realization with a serial or parallel mechanism is presented. Necessary and sufficient conditions on mechanism configurations to realize an elastic behavior are identified. In Sec. 3, the physical implications of the realization conditions are presented for serial and parallel mechanisms. Using these conditions, the bounds on the realizable space of elastic behaviors for a given mechanism are interpreted in terms of the locus of elastic behavior centers. In Sec. 4, geometric construction-based synthesis procedures for the realization of an arbitrary planar elastic behavior (using either a parallel or serial mechanism) are presented. Section 5 provides numerical examples to illustrate the synthesis procedures for both serial and parallel mechanisms. Finally, a brief summary is presented in Sec. 6.

In this section, the technical background for planar compliance realization with a serial or parallel mechanism having four compliant components is presented. Necessary and sufficient conditions to realize an elastic behavior are then derived for both a serial and a parallel mechanism.

where v = r × k, k is the unit vector perpendicular to the plane, r is the 2-vector indicating the location of the revolute joint relative to the coordinate frame used to describe the compliance C, and n is the unit 2-vector indicating the direction of the prismatic joint axis.

It is known that any positive definite compliance matrix C can be decomposed into the form of Eq. (2). Thus, if a mechanism is designed to have a revolute joint located at the instantaneous center of each revolute joint twist t_r and a prismatic joint along each prismatic twist t_p (with corresponding assigned joint compliance c_i for each joint), then the compliance behavior is realized with the mechanism. Thus, a decomposition of C with four rank-1 components yields the design of a four-joint serial mechanism configuration that realizes C. The rank-1 decomposition of C in Eq. (2) is not unique. There are infinitely many mechanisms that realize a given elastic behavior.

Although the twist associated with a revolute joint in a serial mechanism has a unique location in the plane, a twist associated with a prismatic joint has an arbitrary location in the plane.

where n is a unit 2-vector indicating the direction of the spring axis, $d=(r̃×n)·k$ is a scalar indicating the distance of the spring axis from the coordinate frame, $r̃$ is a position vector from the coordinate frame to any point along the spring axis, and k is the unit vector perpendicular to the plane of the mechanism.

If a given positive definite stiffness matrix K is decomposed into the form of Eq. (6), a parallel mechanism can be designed to have the spring wrench w_i and spring stiffness k_i so that the given stiffness is achieved.

where $Ω$ is the matrix defined in Eq. (4).

For a torsional spring, since the spring wrench is a free vector, its location is arbitrary.

For planar cases, a twist and a wrench are reciprocal when the instantaneous center of the twist is on the line of action of the wrench.

Since a translational twist t_p in Eq. (1) is a free vector in the plane, a serial mechanism consisting of only prismatic joints cannot achieve a full-rank compliant behavior. Thus, in order to realize an arbitrary compliance with a serial mechanism, revolute joints must be used. Similarly, to realize an arbitrary stiffness with a parallel mechanism, simple line springs must be used. Realization conditions impose requirements on the revolute joint locations in a serial mechanism, or on the axes of line springs in a parallel mechanism. These conditions are derived next.

This section identifies necessary and sufficient conditions that a four-joint simple elastic mechanism must satisfy to realize a specified elastic behavior.

where α is a scalar.

The geometric arrangement of the joints satisfying Eq. (12) is a necessary condition for the realization of specified compliance C.

The sufficiency of this set of conditions is evaluated next.

Note that the four Eqs. (20) and (21) are satisfied due to the definition of $C̃$ in Eq. (15) and are independent from each other if any three twists t_i are linearly independent. These four equations are also independent of the equations in Eq. (14). Satisfying two equations in Eq. (14) provides a sufficient number of independent equations to ensure that $C̃=C$⁠. It can be seen that if any two equations in Eq. (14) are satisfied, then condition (12) must be satisfied for any permutation of {1, 2, 3, 4}. As such, condition (14) is a necessary and sufficient condition for C to be expressed in the form of Eq. (11).

Thus, condition (26) for any {i, j, r, s} is a necessary condition for C to be expressed in the form of Eq. (11). It can be proved that condition (26) for any two permutations with different values of s is also sufficient for C to be expressed in the form of Eq. (11).

For two permutations of {1, 2, 3, 4} with different values of s, Eq. (28) gives two independent equations. Since $(C̃−C)$ must satisfy the four Eqs. (20) and (21), the 3 × 3 symmetric matrix $(C−C̃)$ satisfies six independent homogeneous equations. Thus, $C−C̃=0$⁠, which means that $C=C̃$ is expressed in the form of Eq. (11). Therefore, condition (26) for any two different permutations is also necessary and sufficient for C to be expressed in the form of Eq. (11).

In summary, we have

Proposition 1. A symmetric matrixCcan be expressed in the form of Eq. (11) if and only if one of the following statements holds:

• (a)
  For any two sets of (i, j, r, s) from the three permutations (1, 2, 3, 4), (1, 3, 2, 4), and (1, 4, 2, 3)

  $wijTCwrs=0$

  (29)
• (b)
  For any two permutations (i, j, r, s) of {1, 2, 3, 4} with different values of s

  $wijTCwir(wijTts)(wirTts)=wijTCwrj(wijTts)(wrjTts) ◻$

  (30)

Note that if condition (29) or (30) holds for two permutations described in Propositions (1a) and (1b), the condition must hold for all permutations of {1, 2, 3, 4}.

The conditions presented in Proposition 1 are necessary and sufficient conditions for a given C to be realized with a mechanism with joint locations determined by t_i if there are no constraints on the coefficients c_i's in Eq. (11). The mechanism, however, must be capable of having either positive or negative joint compliances. If the conditions in Proposition 1 are not satisfied, the compliant behavior cannot be realized with the mechanism at the configuration even if negative (active) compliance is allowed for each joint.

Proposition 2. A compliance matrixCcan be passively realized with a four-joint serial mechanism having joint twistst_i if and only if the following two conditions are both satisfied:

• (a)
  For any two sets of (i, j, r, s) from the three permutations (1, 2, 3, 4), (1, 3, 2, 4), and (1, 4, 2, 3)

  $wijTCwrs=0$

  (31)
• (b)
  For any four permutations (i, j, r, s) of {1, 2, 3, 4} with s = 1, 2, 3, 4

  $(wijTCwir)(wijTts)(wirTts)≥0 ◻$

  (32)

It can be seen that, in order to passively realize a given compliance matrix with a 4-joint serial mechanism at a given configuration, two equality conditions (31) and four inequality conditions (32) must be satisfied.

By duality, the realization of a specified stiffness with a parallel mechanism having four springs can be obtained.

The results presented in Proposition 2 can be modified for the realization of stiffness with a parallel mechanism.

Proposition 3. A stiffness matrixKcan be passively realized with a four-spring parallel mechanism having spring wrenchesw_i if and only if the following two conditions are both satisfied:

• (a)
  For any two sets of (i, j, r, s) from the three permutations (1, 2, 3, 4), (1, 3, 2, 4), and (1, 4, 2, 3)

  $tijTKtrs=0$

  (34)
• (b)
  For any four permutations (i, j, r, s) of {1, 2, 3, 4} with s = 1, 2, 3, 4

  $tijTKtir(tijTws)(tirTws)≥0 ◻$

  (35)

Similar to the serial case, if condition (34) is satisfied for any two permutations described in Proposition (3a), it must be satisfied for all permutations. If condition (34) is not satisfied, the compliant behavior cannot be realized with the mechanism even if negative stiffness (active, but independently controlled behavior) is allowed for each spring. If condition (35) is satisfied for any four permutations with s being each of the springs, then the condition must be satisfied for all permutations of {1, 2, 3, 4}.

To be passively realized, each k_i in Eqs. (36)–(39) must be non-negative (which is equivalent to Proposition 3b).

Although c_i can be obtained with different permutations, Proposition 1b guarantees that the obtained compliance c_i is the same for the given joint twist t_i.

The implications of the realization conditions can be understood in the geometry of the mechanism. First, the physical interpretations of the realization conditions for serial mechanisms and for parallel mechanisms are presented. Then, using these conditions, the bounds on the realizable space of elastic behaviors for a given mechanism are interpreted in terms of the locus of elastic behavior centers.

Below, we show that the inequality conditions (32) for passive realization require that the locus of t_ij be on a segment along line l_rs bounded by joints J_r and J_s. Two cases are considered: either line l_ij intersects l_rs between J_s and J_r or it does not.

First, consider the case in which line l_ij does not intersect l_rs between J_r and J_s. For the four-joint locations illustrated in Fig. 2, consider, without loss of generality, w₁₂ and w₃₄.

Since J₃ and J₄ are on the same side of l₁₂, $t3Tw12$ and $t4Tw12$ have the same sign. Since c₃ and c₄ are positive, $c3(t3Tw12)$ and $c4(t4Tw12)$ have the same sign. Thus, the positive (or negative) combination of t₃ and t₄ in Eq. (44) indicates that t₁₂ must be located on the line segment between J₃ and J₄.

Conversely, if t₁₂ is located on the finite segment between J₃ and J₄, then the coefficients of t₃ and t₄ in Eq. (44) must have the same sign, i.e., $c3(t3Tw12)$ and $c4(t4Tw12)$ have the same sign. Therefore, c₃ and c₄ must also have the same sign. Below, we show that c₃ and c₄ must be non-negative.

Therefore, c₃ and c₄ must be non-negative. The geometric interpretation of the realization conditions for this case is illustrated in Fig. 2.

Since J₂ and J₄ are on the opposite sides of line l₁₃, $t2Tw13$ and $t4Tw13$ have opposite signs. Thus, t₁₃ must be on line l₂₄ outside the finite segment bounded by J₂ and J₄. Conversely, if t₁₃ is located outside the line segment J₂J₄, the coefficients of t₂ and t₃ in Eq. (45), $c2(t2Tw13)$ and $c4(t4Tw13)$⁠, have opposite signs. Since $(t2Tw13)$ and $(t4Tw13)$ have opposite signs, c₁ and c₂ have the same sign. Since C is PSD, c₁ and c₂ must be non-negative. Figure 3 shows the geometric interpretation of the realization conditions for this case.

For a serial mechanism with four joints J_i arranged such that no three are collinear as illustrated in Fig. 2, the necessary and sufficient condition for realization can be expressed geometrically as:

Proposition 4. A complianceCcan be realized with a four-joint serial mechanism at a given configuration if and only if the following two conditions are satisfied:

• (a)

  A force along l₁₂results in a twist located on line segment J₃J₄; and a force along l₃₄results in a twist located on line segment J₁J₂.

• (b)

  A force along l₂₃results in a twist located on line segment J₁J₄; and a force along l₁₄results in a twist located on line segment J₂J₃. ◻

Note that in Proposition 4, condition (a) implies one equality condition $w12TCw34=0$ and four inequality conditions c_i ≥ 0 [if C can be expressed in the form of Eq. (11)]. Thus, if condition (a) [or condition (b)] is satisfied, one only needs to check an equality condition (29) for any different permutation to ensure the realization of the behavior.

By duality, the geometric interpretation of the realization conditions can be obtained for parallel mechanisms and stiffness matrices.

where k_i ≥ 0.

If $α̃$ and $(tijTwr)$ have the same sign, $β̃$ and $(tijTws)$ must have the opposite sign, and vice versa. Therefore, the wrench resulting from twist t_ij must pass through the intersection of the other two wrench axes and must be in the interior of the area bounded by the two axes that does not contain the intersection of wrench axes w_i and w_j as shown in Fig. 4.

In summary, for a parallel mechanism having four springs w_i, we have

Proposition 5. A stiffnessKcan be realized with a four-spring parallel mechanism if and only if the following two conditions are satisfied:

• (a)

  A twist at the intersection ofw₁andw₂, T₁₂, results in a wrench that passes through the intersection ofw₃andw₄, T₃₄, and lies in the area bounded by the axes ofw₃andw₄that does not contain T₁₂; and a twist at T₃₄results in a wrench that passes through the intersection ofw₁andw₂, T₁₂and lies in the area bounded by the axes ofw₁andw₂that does not contain T₃₄.

• (b)

  A twist at the intersection ofw₁andw₃, T₁₃, results in a wrench that passes through the intersection ofw₂andw₄and lies in the area bounded by the axes ofw₂andw₄that does not contain T₁₃; and a twist at the intersection ofw₂andw₄, T₂₄, results in a wrench that passes through the intersection ofw₁andw₃and lies in the area bounded by the axes ofw₁andw₃that does not contain T₂₄. ◻

The results of Proposition (5a) are illustrated in Fig. 5.

Note that, similar to the serial mechanism, in Proposition 5, condition (a) implies one equality condition $t12TKt34=0$ and four inequality conditions k_i ≥ 0 [if K can be expressed in the form of Eq. (46)]. Thus, if condition (a) [or condition (b)] of Proposition 5 is satisfied, one only needs to check an equality condition (34) for any different permutation to ensure the realization of the behavior.

For any planar compliant behavior, the unique point at which the behavior can be described by a diagonal compliance (stiffness) matrix is defined as the center of compliance (stiffness). For the planar case, the centers of stiffness and compliance are coincident. In Ref. [7], it was shown that if a compliance (stiffness) is realized with a three-joint (three-spring) serial (parallel) mechanism, the center must be inside the triangle formed by the three joints (springs) as vertices (sides). Below, these results are extended to mechanisms having four compliant components.

Then, the twist t₁ = Cw₁ must lie on the line of action of w₂, and the twist t₂ = Cw₂ must lie on the line of action of w₁ as shown in Fig. 6. The following statements hold true:

• (a)

  Any wrench w passing through the intersection point of the two wrenches, T₁₂, when multiplied by C, results in a twist t located on line l₁₂ passing through the centers of t₁ and t₂ as shown in Fig. 6.

• (b)

  Any wrench along line l₁₂ passing through the centers of t₁ and t₂, when multiplied by C, results in a twist t₁₂ located at T₁₂ (where wrenches w₁ and w₂ intersect).

• (c)

  The center of compliance must be inside the triangle formed by the centers of twists t₁, t_2, and t₁₂ (the shaded area shown in Fig. 6).

Thus, t must be on the line passing through the centers of twists t₁ and t₂.

Thus, the twist resulting from C multiplying w₁₂ is reciprocal to both w₁ and w₂, which indicates that the twist center is located at the intersection of w₁ and w₂, i.e., at T₁₂.

Since the three wrenches w₁, w_2, and w₁₂ are reciprocal about C, analysis of three-spring parallel mechanisms [7] shows that the center of compliance must be in the interior of the triangle formed by the axes of the three wrenches. It also can be seen that the three twists t₁, t_2, and t₁₂ are reciprocal about the stiffness K = C⁻¹. The space of realizable elastic centers is bounded by the joint locations (the joint twist centers) in serial mechanisms and by the spring axes in parallel mechanisms.

Using the realization conditions for a serial and parallel mechanism, it is evident that if a compliant behavior is realized with a serial mechanism, the location of the center must be within the polygon formed by the convex hull of the four joints as shown in Fig. 7(a). For a parallel mechanism of four springs, the location of the center must be inside the polygon formed by the union of all triangles formed by any three spring wrenches as shown in Fig. 7(b).

In this section, synthesis procedures for the realization of an elastic behavior with a four-joint serial mechanism and with a four-spring parallel mechanism are presented. The procedures are based on the geometric interpretations of the realization conditions obtained in Sec. 3. First, some geometric properties of wrenches and twists associated with an elastic behavior are derived. These properties are used in the synthesis procedures that follow.

Consider a family of parallel unit wrenches $Wp$⁠. In the plane, each w in $Wp$ can be represented by its line of action l. Thus, $W$ is represented by a family of parallel lines $Lp$ in the plane. In $Lp$⁠, there is a unique line l_c that passes through the center of compliance C_c.

It is shown below that the centers of twists in $Tw$ form a straight line l_t passing through the center of compliance C_c.

where d indicates the perpendicular distance from the line of action to the origin of the coordinate frame used to describe the compliance.

Since t_c is the third column of the compliance matrix, Eq. (59) indicates that it is located at the center of compliance C_c (T_c = C_c). Thus, the t associated with w must lie on the straight line l_t passing through the compliance center C_c as illustrated in Fig. 8(a). Since C is positive definite, $wTt=wTCw>0$⁠, the axis of w never intersects the corresponding center of t. Therefore, w and t are always separated by line l_c as shown in Fig. 8(b). When w approaches the line passing through the center of compliance, l_c, then w^Tt_c → 0, and the center if the corresponding t goes to infinity along the line l_t as shown in Fig. 8(c). When w is far away from the compliance center, d → ±∞, then the center of t approaches C_c, the center of the compliance, as shown in Fig. 8(d).

In summary, we have

Proposition 6. Consider a family of parallel wrenches$Wp$and the corresponding set of twists$Tw$defined in Eq. (54).

• (a)

  The locus of$t∈Tw$is a straight line l_t passing through the center of compliance.

• (b)

  For any$w∈Wp$, the corresponding twist$t∈Tw$is separated by line l_c, the line passing through the center of compliance C_c.

• (c)

  When the axis of$w∈Wp$approaches the line l_c passing through compliance center, the location oftgoes to infinity along line l_t.

• (d)

  When the axis of$w∈Wp$is far away from the compliance center, d → ±∞ and the location oftapproaches the center of compliance C_c along l_t. ◻

Then, as shown below, $Wt$ is a family of parallel wrenches.

Thus, the wrench w = Kt has the direction of wrench w₀ = Kt₀ regardless of the values of α and β in Eq. (61). Therefore, all wrenches in $Wt$ are parallel to the wrench w₀, which means that $Wt$ forms a family of parallel wrenches.

Suppose that l_c is the line of action of the wrench in $Wt$ passing through the stiffness center C_k. Similar to Proposition 6, we have:

Proposition 7. Consider a family of twists$Tl$located on a straight line l_t passing through the stiffness center C_k and the set of corresponding wrenches$Wt$defined in Eq. (60).

• (a)

  $Wt$forms a family of parallel wrenches.

• (b)

  For any twist$t∈Tl$, the line of action of the corresponding wrenchwis on the opposite side of line l_c.

• (c)

  When the center of twistt→ C_k along line l_t, the line of action of the correspondingwgoes to infinity.

• (d)

  Whent→ ±∞ along line l_t, the line of action of the correspondingwapproaches line l_c. ◻

The properties of $Wt$ are illustrated in Fig. 9.

In this subsection, the results of Propositions 6 and 7 are used in synthesis procedures to realize an elastic behavior with a four-joint serial mechanism or a four-spring parallel mechanism.

The procedure for a four-joint serial mechanism is presented below. This procedure identifies the locations of four joints in a serial mechanism and the corresponding compliance values that realize a specified compliance matrix C having compliance center C_c. The geometry associated with the sequence of operations in the synthesis procedure is illustrated in Fig. 10.

1. (1)
   Choose a line l₁ arbitrarily relative to C_c and obtain the unit wrench w₁ associated with l₁. Two revolute joints of the serial mechanism will be located on this line. Calculate the twist resulting from that wrench acting on C

   $t1=Cw1$

   (62)

   The center of t₁, T₁, is determined using Eq. (3).
2. (2)
   Choose a line l₂ passing through the point T₁ and obtain the unit wrench w₂ associated with l₂. The other two joints of the mechanism will be on this line. Calculate the twist resulting from w₂

   $t2=Cw2$

   (63)

   The center of t₂, T₂, will be on line l₁ (the axis of w₁), i.e.,

   $w1TCw2=0$

   (64)

   The line passing through points T₁ and T₂ is denoted as l.
3. (3)

   Choose a line l₃ on one side of line l such that the center of the corresponding twist t₃ = Cw₃ is on the opposite side of l.

   Line l₃ can be selected using the properties of Proposition 6 presented in Sec. 4.1.

   • (a)

     First, choose a candidate line l_p that does not intersect line segment T₁T₂. Obtain the unit wrench $w̃p$ associated with l_p and calculate the corresponding twist $tp=Cw̃p$⁠. Then, by the property presented in Sec. 4.1, the center of t_p, T_p, and the compliance center C_c must be on the same side of l_p.

   • (b)

     Translate l_p toward C_c until T_p is on the opposite side of l. This line is selected as l₃ and the center of the corresponding twist t₃ is T₃.

     This can always be accomplished due to the fact that when l_p → C_c, T_p → ∞.

4. (4)

   Choose a line l₄ that passes through point T₃ and does not intersect line segment T₁T₂. The intersections of these four lines (shown in Fig. 10) are the locations of the four joints (J₁, J₂, J₃, J₄) of the mechanism that realizes the specified compliance.

5. (5)

   Calculate the value of joint compliance for each joint using Eqs. (16)–(19).

It can be seen that when the four joint locations are selected by this process, the realization conditions in Proposition 4 are satisfied. Therefore, the compliance C is realized with a serial mechanism having the obtained configuration.

The procedure for a four-spring parallel mechanism is presented below. This procedure identifies the locations of four line springs and their stiffness values in a parallel mechanism that realizes a specified stiffness matrix K having stiffness center C_k. The geometry associated with the sequence of operations in the synthesis procedure is illustrated in Fig. 11.

1. (1)
   Choose an arbitrary location T₁ relative to the stiffness center C_k and obtain the unit twist t₁ at T₁ using the formula for t_r in Eq. (1). Two spring axes will intersect here in the parallel mechanism. The wrench resulting from t₁ is

   $w̃1=Kt1$

   (65)

   The line of action of $w̃1$⁠, l₁, is obtained.
2. (2)
   Choose an arbitrary point T₂ on line l₁, the unit twist t₂ centered at T₂ is calculated using Eq. (1). Point T₂ is the intersection of the other two spring axes. Then, wrench $w̃2$ corresponding to t₂ is obtained

   $w̃2=Kt2$

   (66)

   The line of action of $w̃2$⁠, l₂ is obtained. By the reciprocal condition, line l₂ must pass through T₁, and satisfy

   $t1TKt2=0$

   (67)

   The line passing through points T₁ and T₂ is denoted as l.
3. (3)

   Choose a line l₃ such that the corresponding wrench $w̃3$ results in a twist $t3=Cw̃3$ centered at the opposite side of line l.

   Line l₃ can be selected using the properties of Proposition 7 presented in Sec. 4.1.

   • (a)

     First choose a candidate line l_p that does not intersect line segment T₁T₂. Using the unit wrench along l_p, $w̃p$⁠, the corresponding twist $tp=Cwp$ is calculated. Then, by the property presented in Sec. 4.1, the center of t_p, T_p, and the stiffness center C_k are both located on the same side of l_p.

   • (b)

     Translate l_p toward C_k until T_p is on the opposite side of l. This location T_p is selected as T₃ which will be the intersection of two spring axes in the mechanism.

     This can always be accomplished due to the fact that when l_p → C_k, T_p → ∞. Line l₃ intersects l₁ at T₁₃ and intersects l₂ at T₂₃.

4. (4)

   Choose an arbitrary point T₄ on line l₃ between T₁₃ and T₂₃, the four lines passing through points (T₁, T₃), (T₁, T₄), (T₂, T₄), and (T₂, T₃) as shown in Fig. 11 are identified as the four spring axes (w₁, w₂, w₃, w₄) for the parallel mechanism.

5. (5)

   Calculate the value of stiffness for each joint using Eqs. (36)–(39).

It can be seen that when the four spring axes are selected by this process, the realization conditions in Proposition 5 are satisfied. Therefore, the stiffness K is realized with the parallel mechanism.

The location of the center of stiffness/compliance for this behavior is calculated to be at $((17/14),−(16/14))$⁠. Since the center must be inside the polygon formed by the locations of the four elastic joints in a serial mechanism (or the four spring components in a parallel mechanism), this point is used as a reference in selecting each elastic component.

Following the procedure provided in Sec. 4.2.1, the locations of joints in a serial mechanism and their joint compliances can be obtained.

where the first two components of w₁ indicate the direction and the third component indicates the perpendicular distance of the line to the origin (according to the right-hand rule).

and using Eq. (3), the center of t₁, T₁, is calculated to be located at (1.6842, −1.8947).

The center of t₂, T₂, is calculated using Eq. (3) to be (0.4, −0.6). Note that T₂ lies on line l₁.

The center of t₃, T₃, is located at (0.9562, −2.1751).

Then, the locations of the four joints J₁, J₂, J₃, and J₄ are determined by the intersections of two lines (l₁, l₄), (l₁, l₃), (l₂, l₃), and (l₃, l₄), respectively, as shown in Fig. 12.