Long Shape Memory Alloy Tendon-based Soft Robotic Actuators and Implementation as a Soft Gripper


Shape memory alloy (SMA) wire-based soft actuators have had their performance limited by the small stroke of the SMA wire embedded within the polymeric matrix. This intrinsically links the bending angle and bending force in a way that made SMA-based soft grippers have relatively poor performance versus other types of soft actuators. In this work, the use of free-sliding SMA wires as tendons for soft actuation is presented that enables large increases in the bending angle and bending force of the actuator by decoupling the length of the matrix and the length of the SMA wires while also allowing for the compact packaging of the driving SMA wires. Bending angles of 400° and tip forces of 0.89 N were achieved by the actuators in this work using a tendon length up to 350 mm. The tendons were integrated as a compact module using bearings that enables the actuator to easily be implemented in various soft gripper configurations. Three fingers were used either in an antagonistic configuration or in a triangular configuration and the gripper was shown to be capable of gripping a wide range of objects weighing up to 1.5 kg and was easily installed on a robotic arm. The maximum pulling force of the gripper was measured to be 30 N.


Soft robots present several advantages over their traditional counterparts in that they are compliant which allows them to interact adaptively and safely with their environment and with humans without requiring complex and costly control systems that can require sensors or large computational power1,2,3. Pneumatic and motor-driven tendon systems have, so far, been the most promising types of soft actuators for implementation in various robotic applications such as soft wearables or soft grippers4,5,6,7,8. A wide range of soft actuators and smart materials have been developed with diverse capabilities and diverse fabrication methods, but SMAs are silent, have a high power density and require only an electric input for actuation, but their performance is often lacking when implemented in a soft robotic system for real-life applications9,10,11,12. Various designs of soft actuator consisting of a Shape memory alloy (SMA) wires paired with a polymeric matrix have been proposed, but their design limitations severely limit their potential for real-life applications13.

SMA wires have a limited linear stroke in the range of 4 to 8% of their length14,15, but it is possible to transform this small deformation into large out-of-plane deformations by embedding them in a polymeric matrix16,17,18. Anisotropic elements can be added to the polymeric matrix to produce coupled bending and twisting deformations19,20, and multiple SMA wires can be used to produce twisting deformations or multiple types of deformations in a single actuator21,22. Complex SMA wire positioning can be obtained by double casting the actuator to produce a hollow-tube shaped actuator with multiple SMA wires positioned as helix to sustain lateral loads while producing a twisting deformation23. High current can be used to produce rapid movements of the actuator that can make robots jump24. These actuators can be used to produce crawling robots25,26, swimming robots27,28,29, blooming flowers30, or complex deployable structures31,32. Grippers where embedded rigid segments are embedded to produce jointed deformations have been developed33, grippers with varying thickness to create hinge-like motions have been developed34, and grippers where fusible alloy elements are used to selectively stiffen the fingers when grasping35. Curved SMA-based actuators have been used to produce larger maximum deformations, but their grasping force as a soft gripper remains insufficient for grasping most objects36. SMA wire-based soft actuators and grippers with embedded SMA elements have had the usable length of the SMA wire limited to the length of the matrix when embedding it within the matrix during the casting process, which produces a significant trade-off between force and deformation.

SMA springs have been used externally to the deforming structure to produce crawling robots using a peristaltic motion37, using origami-based folded structure38, robots capable of a bio-inspired rolling motion39, octopus tentacles40, jumping robots41, to cause the deformation of bistable structures42,43, and grippers using externally located SMA springs with free-sliding tendons to transmit their force44. SMA wires with torsional pre-strain have also been used to deform origami-based structures45,46. SMA plates have been used in a soft finger with significant force, but requires too much power for practical applications47. Twisted and coiled actuators (TCA) made from nylon fishing lines or other polymers can be used to produce large contraction with limited forces48,49, dielectric elastomers can produce rapid and small deformations50, ionic polymer-metal composites can produce diverse deformations through the movement of cations in a ionic membrane under an applied voltage51, and phase changing materials can expand significantly when heated52. All the surveyed smart material-based actuators are limited in some factors such as their force, usable strain, size limitations, implementation requirements or speed.

In this paper, we present the use of SMA wires themselves as free-sliding tendons to drive a polymeric matrix which allows the SMA length and the design of the polymeric matrix to be decoupled while also allowing the compact packaging of the driving SMA wires through mechanical systems. This allows greater control for designing actuators based on the required bending angle and force characteristics. The effect of the length of the tendon on the bending angle is presented and compared with a quasi-static numerical model, and the effect of the tendon length on the tip force is evaluated. This SMA wire tendon concept is then applied to a compact and modular module using pulleys to compactly package the SMA wire which was implemented in a soft gripper that can be mounted to any robotic arm and used to grasp a wide range of objects. The gripper was tested with a wide range of object shapes and weights, tested using a tensile testing machine, and mounted on a robotic arm.


Concept and manufacturing

The proposed actuator consists of a long SMA wire with a diameter of 203 µm (Flexinol LT, Dynalloy) passed through a shorter silicone rubber tube with an inner diameter of 300 µm (McMaster-Carr). The SMA wire is then positioned as a U-shape longitudinally in a rectangular 3D printed acrylonitrile butadiene styrene (ABS) mold with holes for positioning of the SMA wire. The silicone tube should cover the portion of the SMA wire that is within the mold matrix (Fig. 1a). Mixed and degassed polydimethylsiloxane (PDMS, Sylgard-184, Dow-Corning) is then poured into the mold and cured at 55 °C for 8 hours. The mold is then cut and discarded (Fig. 1b).

Figure 1

(a) Mold with the SMA wires positioned within silicone rubber tubes, (b) manufactured actuator, (c) fixing point and length dimensions of the actuator, (d) jig for measuring the tip force of the actuator, (e) cross-section of the actuator, and (f) bending deformation of the actuator.

This concept allows the SMA wire to slide freely within the polymeric matrix through being positioned within a slightly larger and hollow channel in the matrix formed by the silicone tube. In previous research, the SMA wire was placed in the mold during curing of the polymer and is in direct contact with the matrix such that its effective length is limited to that of the matrix. Each end of the SMA wire are then fixed externally using a bolt at the desired length, and a current of 0.95 A is applied where the SMA wire is fixed (Fig. 1c). This current was chosen empirically as the actuator can reach its maximum deformation within 1 s while being capable of continuous actuation without overheating. This concept allows for the length of the SMA wires to be independent from that of the matrix, and thus the stroke length of the SMA wires depends on the recovery strain of the wire and its length rather than the matrix length. To measure the tip force, the actuator is fixed on a jig whose angle can be varied using a guide and where the tendon length can be adjusted, and a load cell is used to measure magnitude of the tip force (Fig. 1d)

Quasi-static model

The model consists of finding the equilibrium point where either the stress required in the SMA wire to further increase the bending angle is equal to the stress required to bend the matrix. The force FSMA of the SMA wire can be calculated based on the stress σSMA within the SMA wire and area ASMA of SMA wire within the cross-section of the actuator as

$${F}_{SMA}={A}_{SMA}{\sigma }_{SMA}$$

The strain εCP of the center plane of the actuator and the strain εAP within the actuator in the plane the SMA wire can be calculated as

$${\varepsilon }_{CP}=\frac{{F}_{SMA}}{{E}_{Act}{A}_{Act}}$$
$${\varepsilon }_{AP}=\frac{{F}_{SMA}{d}^{2}}{{E}_{Act}{I}_{Act}}+\frac{{F}_{SMA}}{{E}_{Act}{A}_{Act}}$$

where d is the eccentricity of the SMA wire with the neutral plane (Fig. 1e), EAct is the Young’s modulus of the actuator, AAct is the area of the cross-section of the actuator, d is the eccentricity of the SMA wire with respect to the center plane, and IAct is the moment of inertia of the rectangular actuator across its length. The bending angle θ of the actuator of the actuator can then be calculated based on the length LAct of the actuator as

$$\theta =\frac{({\varepsilon }_{AP}-{\varepsilon }_{CP}){L}_{Act}}{d}$$

The actual strain εSMA of the SMA wire can then be calculated as

$${\varepsilon }_{SMA}=\frac{{\varepsilon }_{AP}{L}_{Act}}{{L}_{Act}+{L}_{Ten}}$$

Where LTen is the length of the tendon (Fig. 1f). If the length of the SMA wire is equal to that of the matrix, as in the surveyed literature, then LTen is equal to zero and could be used to solve simple bending actuators. The stress σ produced by the SMA wire can then be related to the strain and temperature within the wire using the Brinson thermoconstitutive model for one-dimensional SMA elements as follows15

$$\sigma -{\sigma }_{0}=E(\xi )\varepsilon -E({\xi }_{0}){\varepsilon }_{0}+\Omega (\xi )\xi -\Omega ({\xi }_{0}){\xi }_{0}+\Theta (T-{T}_{0})$$

Where σ0 is initial stresses in the wire assumed to be zero, E is the Young’s modulus of SMA which depends on the martensite fraction of the SMA, ε and ε0 are the current and initial strains in the SMA wire where we assume that ε0 = εL, Ω is the phase transformation contribution equal to −EεL, εL is the maximum recoverable strain, ξ and ξ0 are the current and initial martensite fractions assuming that the martensite is fully detwinned during pre-straining of the SMA wire and also during cooling of the actuator due to the elastic force of the matrix such that ξ0 = 1, Θ is the thermoelastic coefficient assumed to be equal to 0, and T and T0 are the current and initial temperatures. Re-arranging and applying assumptions, the following equation is obtained in terms of the strain of the SMA wire

$$\varepsilon =\frac{\sigma }{\xi {E}_{m}+(1-\xi ){E}_{a}}+{\varepsilon }_{L}\xi $$

Where Ea is the Young’s modulus of SMA in the austenite phase, and Em in the martensite phase. The martensite fraction ξ during strain recovery can be calculated as

$$\,\xi =\frac{{\xi }_{M}}{2}(\cos [\frac{\pi (T-{A}_{s})}{{A}_{f}-{A}_{s}}-\frac{\pi \sigma }{{C}_{A}({A}_{f}-{A}_{s})}]+1)$$

Where ξM is the minimum martensite fraction, which is assumed to be equal to 1 as actuation starts from the fully martensite state, CA is a dimensionless curve-fitting parameter equal to 10.3 based on previous work on previous literature53,54, and As and Af are the austenite start and finish transition temperatures. Equations 6, 7 and 8 are then used to calculate the stress produced in the SMA throughout the strain recovery, and equations 4 and 5 are used to calculate the stress and strains required by the SMA to deform the actuator such that the point where both intersect is the quasi-static equilibrium of the actuator.

This model can be used to predict the bending deformation of the actuator for a given SMA wire tendon length and polymeric matrix combination, which is useful in reducing testing time when developing soft robotic components using this actuator design.


Bending angle experiments

The basic goal of using SMA tendons to actuate a polymeric matrix is to use an SMA wire longer than the length of the matrix to increase its performance. The performance factor that is most directly impacted by using a longer SMA wire is the bending angle of the actuator. It is expected that it is possible to obtain large increases in the bending angle of the actuator by using a longer SMA wire either up to the force limit of the SMA wire or up to the physical limit of the deformation. To demonstrate this, an experiment is conducted where three actuators with matrix dimensions of 100 mm in length and 25 mm in width are manufactured with thicknesses of 3, 5, and 8 mm. The length of the SMA wire embedded in the actuator is approximately one meter such that the maximum tendon length is 400 mm since it functions as two wires in parallel. However, the maximum usable length is 350 mm due to needing to fasten the SMA wire at each end. Each actuator is fastened at its base, and the fixation point of the SMA wire is moved incrementally from 0 to 350 mm or until the physical limit of the deformation of the actuator. A tendon length of 0 mm corresponds to that of an actuator with the embedded SMA wire not in tendon configuration, which is what is used in most previous SMA wire-based soft actuators.

Results show that the actuator with a thickness of 3 mm produces a bending angle of 213° with a tendon length of 100 mm and reaches its physical bending limit at a bending angle 270° and a tendon length of 200 mm (Fig. 2a). This limit is due to the tip of the actuator touching the actuating SMA tendons such that further deformation is not possible (Fig. 2b). The bending angle of the actuator with a matrix thickness of 5 mm increases from 143° with a tendon length of 100 mm and increases linearly with an increase in tendon length until also reaching its physical bending limit at a tendon length of 350 mm. The actuator with a thickness of 8 mm produces a bending angle of 75° with a tendon length of 100 mm and its bending angle increases up to 168° with a tendon length of 350 mm. These results correspond well with the model up to the physical limit of the bending deformation. A large increase in bending angle can be seen versus the actuator with a tendon length of 0 mm for all thicknesses.

Figure 2

(a) Bending angle of actuator with different thicknesses for different tendon lengths, (b) maximum bending angle of the actuator, and (c) deformation of the actuator with a tapered length.

The tests for the actuators with a matrix thickness of 3 and 5 mm showed that the bending angle of the actuator may be limited by the actuator folding onto either itself, the jig or the driving SMA wires. Using the proposed tendon concept, it is possible to choose the desired matrix shape of the actuator such as to produce a desired deformation. A matrix with a tapered thickness from 5 mm at its base to 2.5 mm at its tip was used to produce a larger deformation at the tip such that the bending motion can avoid bending on itself. With a tendon length of 680 mm, the actuator can produce a bending angle of 400° (Fig. 2c), which is the largest bending angle of all SMA-based soft actuator reported in the surveyed literature.

Bending force experiments

Another important performance factor to assess soft bending actuators is the bending force of the actuator. In this work, this force was evaluated by fixing the actuator and measuring its tip force at different bending angles to obtain the force profile of the actuator. The tip force of the actuator was measured for actuators with thicknesses of 3, 5, and 8 mm with tendon lengths of 0, 50, 100 and 200 mm (Fig. 3a–c). The tip force was measured at bending angles in increments of 30° by using a load cell (CB1-600gf, Da Cell). The maximum measured angle of the force of the actuator was 120° due to not having sufficient space to place the load cell at bending angles above this value.

Figure 3

Tip force for different tendon lengths of actuators with a thickness of (a) 3 mm, (b) 5 mm, and (c) 8 mm.

All four actuators produced their maximum tip force at the 0° position and continued to produce a bending force if the measured angle is smaller than the maximum bending angle for the tested actuator thickness and tendon length configuration. All actuators exhibited a nearly linear decrease in tip force throughout the deformation from the value measured at a 0° bending angle up to the maximum measured angle. Thicker actuators also produce a larger tip force throughout most of their deformation. This could be due to the thinner actuators not being able to transmit forces to the tip of the actuator as well as thicker ones due to deformations between the base and the tip of the actuator.

When the active length of the SMA wire is limited to that of the matrix, actuators making use of a thicker matrixes would produce smaller bending deformations which would reduce the usefulness of the actuator despite being capable of larger forces than thinner actuators. The use of long driving SMA wire tendons produces larger deformations and larger forces. It also becomes possible to retain the same bending deformation with a thicker matrix by using a longer tendon and thus scale up even further the force of the actuator.

Behavior using uneven tendon length

The SMA tendons are able to slide freely within the actuator and the length of the tendon at each end can be adjusted such that each end has a different tendon length. The actuator with a matrix thickness of 5 mm was tested with one tendon having a fixed length of 10 mm and the other having its tendon length varied from 50 to 200 mm in 25 mm increment (Fig. 4a). It can be observed visually that the actuator produces a pure bending deformation with no torsion (Fig. 4b–g), which shows that the uneven tendon lengths do not cause one side of the actuator to contract more than the other. The bending deformation increases linearly with an increase in the tendon length and follows an increase similar to that of the actuator with even tendon lengths. These results show that the contraction of the tendon is distributed in each side due to its ability to slide freely within the silicone tube. This behavior may be helpful when grasping irregular or elliptical objects whose surface would require a slight rotation of the actuators.

Figure 4

(a) Bending angle comparison for even tendon lengths and uneven tendon lengths, and bending deformation for actuators with one tendon length of 10 mm and second tendon length of (b) 75 mm, (c) 100 mm, (d) 125 mm, (e) 150 mm, (f) 175 mm, and (g) 200 mm.

Robotic gripper

A robotic gripper making use of long tendons and a thicker polymeric matrix should be able to have improved grasping performance versus previously developed SMA-based grippers due to the improved bending deformations and tip forces that were demonstrated in the previous section. However, the implementation of 400 mm long tendons requires a tendon routing solution to produce a compact gripper that can be implemented for diverse applications. In this work, each finger of the robotic gripper is built as a stand-alone module with a matrix thickness of 8 mm and a tendon length of 300 mm, whose tendon is routed through a series of V-shaped bearings (Fig. 5a,b). These modules can then be assembled modularly to produce a gripper of the desired shape and number of fingers. This modularity allows for ease of repair and customization. The basic configuration tested in this work is that of a three-fingered grasper with two of the fingers in parallel and the other placed antagonistically (Fig. 5c), and a triangular formation of three fingers was also tested (Fig. 5d). The module was tested for 100 cycles with 1 second of heating and 9 seconds of cooling time, and no degradation in the maximum bending angle of the actuator was visible (Fig. 5e,f). The minimum bending angle during cooling increased due to heat accumulation within the matrix, but the actuator returns near its original unactuated bending angle after being allowed to fully cool.

Figure 5

(a) Single actuator module, (b) inside view of the module, (c) gripper with antagonistic configuration, and (d) gripper with triangular configuration, (e) the first 10 cycles and (f) the last 10 cycles of a 100-cycle module actuation test.

The static adaptive grasping capability of the actuator was tested by grasping objects with a wide range of shapes and weights by applying a fixed current of 0.95A to the SMAs for all objects regardless of their shape or weight. When using adaptive soft grippers, the main goal is to be able to grab objects with different shapes, sizes and weights regardless of their exact position such that can be used in less structured environments. The antagonistic gripper was tested in the horizontal position as this position makes it harder to hold onto the object, and tested objects include a wide range of object shapes and sizes with cylindrical, spherical and other shapes with weights ranging from 5 to 1513 g (Fig. 6a–r). The heaviest and largest object held by the gripper is a full 1.5 L bottle of soda which was able to be grasped both in the vertical and horizontal position. The gripper with a triangular finger configuration is intended for use in the vertical position and was tested for a wide range of objects in the vertical position in which case both power grasps, when the inside of the actuators is holding the object, was realized for smaller objects and fingertip grasps, when the tip of the actuators is holding the object, was realized for larger objects (Fig. 6s–aj). The first gripper was particularly well suited for cylindrical-shaped objects while the second gripper was better suited for round objects. However, both configurations proved capable of grasping either object shapes.

Figure 6

Antagonistic gripper in the horizontal position gripping (a) a marker(17 g), (b) a carrot(200 g), (c) a zucchini(250 g), (d) a bottle of soft drink(310 g), (e) a tumbler(263 g), (f) a large bottle of soft drink(1513 g), (g) a ping-pong ball(27 g), (h) a baseball(130 g), (i) an orange(240 g), (j) a broccoli(300 g), (k) an apple(305 g), (l) a sweet pumpkin(311 g), (m) a shuttlecock(5 g), (n) correction tape(45 g),(o) a pair of scissors(85 g), (p) a box cutter(128 g), (q) a shoe(180 g), and (r) a ratcheting crimper pliers(420 g). Triangular gripper in the vertical position gripping (s) toilet paper(86 g), (t) a bottle of medicine(95 g), (u) a roll of string(126 g), (v) a cup of noodles(150 g), (w) oil can(215 g), (x) a weight of 2 kg(2000g), (y) a ping-pong ball(27 g), (z) a baseball(130 g), (aa) an orange(240 g), (ab) a broccoli(300 g), (ac) an apple(305 g), (ad) a sweet pumpkin(311 g), (ae) a shuttlecock(5 g), (af) a stuffed toy(40 g), (ag) a pair of scissors(85 g), (ah) a pack of instant noodles(120 g), (ai) a bag of chips(135 g), and (aj) wet towel wipes(173 g).

When the gripper is grabbing an object using a power grasp, the grasping force of the gripper increases when a larger area of the actuators is in contact with the object. The pulling force of the gripper was evaluated for grippers with SMA wires with SMA wire diameters of 0.203 mm and 0.305 mm using a tensile testing machine (QC-506, Cometech) using three jigs where the first is an elliptical prism with radiuses of 28 and 20 mm, the second is a half cylinder with a radius of 28 mm, and the third is an inverted triangular prism with a width of 56 mm and a height of 28 mm (Fig. 7a–h). The elliptical prism was designed such that a significant portion of the jig is in contact with the inner surface of the actuator to measure the maximum pulling force of the actuator and the half cylinder represents the case where only a small portion of the object is in contact with the inner surface of the actuator. The triangular prism represents the case where only a single point is originally in contact with the actuator. The results show that the gripper is generally capable of a minimum pulling force of approximately 25 N using thicker SMA wires if a single point is in contact with the actuator, but that if the object is performing a fully adaptive power grasp then its pulling force increases up to 30 N. The pulling force produced by the actuator is also sustained over a large displacement where the pulling force is near its maximum even after a displacement of 40 mm, which is much larger than the previously surveyed SMA-based soft grippers. The gripper finally loses its grip on the jig after a displacement of 60 mm for either the elliptical of half circle jigs. In the case of the inverted triangular prism, the gripper transitions from a single point of contact on the inside of the fingers to a fingertip grasp at approximately 40 mm and loses its grasp at a displacement of 72 mm. The behavior of the gripper was the same regardless of the diameter of the SMA wires used, but the pulling force was significantly increased.

Figure 7

(a) pulling force of the gripper for an elliptical prism and a half cylinder, (b) gripping shape for the elliptical prism, (c) gripping shape for the half cylinder, (d) comparison of the two jigs, (e) pulling force for the inverted triangular prism, (f) initial position with the inverted triangular prism, (g) before transitioning to fingertip grasp, and (h) in fingertip grasp. (i) Pulling force with the fingers covered with a TPU coated polyester sleeve, (j) schematic of the gripper, (k) setup with the elliptical prism jig, and (l) setup with the inverted triangular prism jig.

The elliptical prism and the inverted triangular prism tests were repeated with the actuator wrapped in a TPU coated polyester sleeve which allows for a very low friction coefficient between the actuator and the jig (Fig. 7i–l). Results show that the maximum pulling force of the actuator reduces to 7 N and 13 N for the elliptical prism for the different SMA wire diameters. In the case of the inverted triangular prism, the actuator has the same maximum pulling force, but the force generated after the grip changes to the inside of the finger is significantly weakened especially for the thicker SMA wires. These results show that the actuator is capable of a reasonable pulling force for objects of moderate weights, but that friction may be needed to lift heavier objects.

The gripper was then installed as the end-effector of a robotic arm (UR10, Universal Robots) (Fig. 8a,b). A can of soft drink with a weight of 273 g was successfully grasped, moved, and released by the gripper installed on the robotic arm (Fig. 8c–h). This experiment demonstrates that the proposed modular gripper can be easily implemented as part of a robotic arm despite the use of extremely long SMA wire tendons.

Figure 8

(ab) Gripper installed on a robotic arm, and the gripper (c,d) grasping, (eg) moving, and (h) releasing a can of soft drink.


The proposed SMA-based soft actuator uses SMA wires as free-sliding tendons to overcome the limitations of previous SMA-based soft actuator designs. SMA wire-based soft actuators had the SMA wire embedded into the polymeric matrix in contact with the matrix throughout such that the active length of the SMA wire is limited to the length of the matrix. As SMA wires have a limited actuation strain, SMA-based soft actuators were heavily limited by this. Different designs had been proposed to produce large deformations despite this limitation, but generally at the detriment of the force of the actuator. Using long free-sliding SMA wires allows to use very long SMA wires that produce much larger linear deformations and to use the deformation to produce large deformations without using design solutions that reduce the force of the actuator. Previous work has used externally located SMA springs to enable the use of springs, but this required thicker wires in the fabrication of the springs that required more power input for actuation. Furthermore, longer springs resulted in unwieldy system sizes. The use of SMA wires as the tendon itself enables the use of already established techniques for building compact actuator packages externally to the polymeric structure through pulleys12.

The developed gripper was able to grasp heavier objects than previous SMA-based grippers due to producing larger deformations and larger bending forces. This is directly due to the use of SMA wires much longer than the polymeric matrix through their use as a tendon and the possibility to position them at any eccentricity within the matrix since their stroke can be adjusted by increasing their length. The use of bearings to place the leading SMA wire into a compact package also enabled the actuators to be easy to use and assembled in any desired configuration to form a capable gripper that can be mounted on a robotic arm. The module could easily be designed in a more compact manner using more rigid material, smaller bearing and a better tendon arrangement.

Within the surveyed literature, the largest pulling force for an SMA wire-based soft gripper was 1.4 N without a stiffening mechanism and 6 N using fusible alloy as a stiffening structure while the developed soft robotic gripper produced a maximum pulling force of 25 N. It is possible to further increase the bending force of the actuator by increasing the number of SMA wires in parallel within the matrix, by increasing the diameter of the SMA wires, and by further increasing the length of the tendons. This would, however, increase the energy requirements of the gripper and might require the use of active cooling of the tendons to prevent excessive heat accumulation within the matrix and within the module housing the SMA wires. Other heating methods than Joule heating may be necessary to increase the heating speed and energy efficiency of the actuator if extremely long lengths of SMA wire are used for a single actuator. An alternative explored in other previous SMA-related works that could also be used in the developed gripper is to optimize the design of the matrix to improve the performance of the actuator. This solution is not exclusive with and could be used in tandem with long SMA tendons to further improve the performance of this type of soft actuator.

Pneumatic soft grippers are currently the most commonly used type of soft gripper using mechanical forces to grasp objects due to their large deformations and large force. However, their force diminishes rapidly throughout the motion as significant work is required to deform and expand the polymeric matrix. The force produced by the actuator presented in this paper decreases steadily but slower than polymer-based soft pneumatic grippers such that their performance for grasping could rival or exceed previously developed soft pneumatic grippers while being lighter, significantly quieter and not requiring an external pneumatic source. Further design improvements will be required before SMA-based soft grippers can truly compete with other types of grippers, but the present work.


An important design limitation of previously developed SMA-based soft actuators was that the active length of the SMA wire is equal to that of the polymeric matrix which limits the available strain and constrains the performance of the actuator. In this work, the use of SMA wires as free-sliding tendons within the matrix and fixed externally allows to decouple the length of the matrix and that of the SMA wires such that it is possible to use much longer SMA wires than the polymeric matrix. This was used to realize large increases in performance without altering the design of the matrix with the largest achieved bending angle reaching 400° achieved, the largest reported for SMA-based soft bending actuators, and a tip force of 0.89 N. This design could also be usable for other types of wire-like smart materials coupled with a polymeric matrix whose finite strain limits their performance. The second major advantage of this concept is that the SMA wire can be packaged into a module using pulleys as done previously for non-soft mechanical devices while maintaining a compact form factor for the overall soft actuation system12.

This concept was then applied to a modular soft gripper where each module contains an actuator driven by long SMA wire tendons packaged compactly using bearings. The soft gripper was demonstrated to be able to grab a variety of objects shapes and weight in different orientations, and even of producing pulling forces up to 30 N. It was then installed as the end-effector of a robotic arm and demonstrated its capability to grab and move objects in both the power grasp and the fingertip grasp.

The proposed tendon design can significantly improve the performance of SMA-based soft actuators and even begin to make them compete with soft pneumatic actuators while maintaining the low weight, noiselessness, low cost and simple actuation method of SMA-based soft actuator. This design could be adapted to produce capable robots, mechanisms and medical tools. Future work will concentrate on further improvements of the gripper to produce faster actuation and stronger grasping forces for industrial uses.

Data Availability

All data generated or analyzed during this study are included in this published article.


  1. 1.

    Laschi, C. & Cianchetti, M. Soft Robotics: New Perspectives for Robot Bodyware and Control. Frontiers in bioengineering and biotechnology 2, 3, https://doi.org/10.3389/fbioe.2014.00003 (2014).

    Article  PubMed  PubMed Central  Google Scholar 

  2. 2.

    Rus, D. & Tolley, M. T. Design, fabrication and control of soft robots. Nature 521, 467–475, https://doi.org/10.1038/nature14543 (2015).

    ADS  CAS  Article  PubMed  Google Scholar 

  3. 3.

    Cianchetti, M., Laschi, C., Menciassi, A. & Dario, P. Biomedical applications of soft robotics. Nature Reviews Materials 3, 143–153, https://doi.org/10.1038/s41578-018-0022-y (2018).

    ADS  Article  Google Scholar 

  4. 4.

    Yun, S.-S., Kang, B. B., Cho, K.-J. & Exo-Glove, P. M. An Easily Customizable Modularized Pneumatic Assistive Glove. IEEE Robotics and Automation Letters 2, 1725–1732, https://doi.org/10.1109/lra.2017.2678545 (2017).

    Article  Google Scholar 

  5. 5.

    Asbeck, A. T., Dyer, R. J., Larusson, A. F. & Walsh, C. J. Biologically-inspired Soft Exosuit. IEEE international conference on Rehabilitation robotics (ICORR),Seattle, USA, https://doi.org/10.1109/ICORR.2013.6650455 (2013, June 24–26).

  6. 6.

    Shintake, J., Cacucciolo, V., Floreano, D. & Shea, H. Soft Robotic Grippers. Advanced materials, e1707035, https://doi.org/10.1002/adma.201707035 (2018).

    Article  Google Scholar 

  7. 7.

    Thuruthel, T. G., Falotico, E., Renda, F. & Laschi, C. Learning dynamic models for open loop predictive control of soft robotic manipulators. Bioinspiration & biomimetics 12, 066003, https://doi.org/10.1088/1748-3190/aa839f (2017).

    ADS  Article  Google Scholar 

  8. 8.

    Hawkes, E. W., Blumenschein, L. H., Greer, J. D. & Okamura, A. M. A soft robot that navigates its environment through growth. Science Robotics 2, eaan3028, https://doi.org/10.1126/scirobotics.aan3028 (2017).

    Article  Google Scholar 

  9. 9.

    Chen, D. & Pei, Q. Electronic Muscles and Skins: A Review of Soft Sensors and Actuators. Chemical reviews 117, 11239–11268, https://doi.org/10.1021/acs.chemrev.7b00019 (2017).

    CAS  Article  PubMed  Google Scholar 

  10. 10.

    Mohd Jani, J., Leary, M., Subic, A. & Gibson, M. A. A review of shape memory alloy research, applications and opportunities. Materials & Design 56, 1078–1113, https://doi.org/10.1016/j.matdes.2013.11.084 (2014).

    CAS  Article  Google Scholar 

  11. 11.

    Chu, W.-S. et al. Review of biomimetic underwater robots using smart actuators. International Journal of Precision Engineering and Manufacturing 13, 1281–1292, https://doi.org/10.1007/s12541-012-0171-7 (2012).

    Article  Google Scholar 

  12. 12.

    Nespoli, A., Besseghini, S., Pittaccio, S., Villa, E. & Viscuso, S. The high potential of shape memory alloys in developing miniature mechanical devices: A review on shape memory alloy mini-actuators. Sensors and Actuators A: Physical 158, 149–160, https://doi.org/10.1016/j.sna.2009.12.020 (2010).

    CAS  Article  Google Scholar 

  13. 13.

    Rodrigue, H., Wang, W., Han, M.-W., Kim, T. J. Y. & Ahn, S.-H. An Overview of Shape Memory Alloy-Coupled Actuators and Robots. Soft Robotics 4, 3–15, https://doi.org/10.1089/soro.2016.0008 (2017).

    Article  PubMed  Google Scholar 

  14. 14.

    Furst, S. J. & Seelecke, S. Modeling and experimental characterization of the stress, strain, and resistance of shape memory alloy actuator wires with controlled power input. Journal of Intelligent Material Systems and Structures 23, 1233–1247, https://doi.org/10.1177/1045389x12445036 (2012).

    Article  Google Scholar 

  15. 15.

    Brinson, L. One-Dimensional Constitutive Behavior of Shape Memory Alloys: Thermomechanical Derivation with Non-Constant Material Functions and Redefined Martensite Internal Variable. Journal of Intelligent Material Systems and Structures 4, 229–242, https://doi.org/10.1177/1045389X9300400213 (1993).

    Article  Google Scholar 

  16. 16.

    Icardi, U. Large bending actuator made with SMA contractile wires: theory, numerical simulation and experiments. Composites Part B: Engineering 32, 259–267, https://doi.org/10.1016/S1359-8368(00)00062-7 (2001).

    Article  Google Scholar 

  17. 17.

    Wang, G. & Shahinpoor, M. Design, prototyping and computer simulations of a novel large bending actuator made with a shape memory alloy. Smart Materials and Structures 6, 214–221, https://doi.org/10.1088/0964-1726/6/2/011 (1997).

    CAS  Article  Google Scholar 

  18. 18.

    Du, Y. et al. Dynamic characteristics of planar bending actuator embedded with shape memory alloy. Mechatronics 25, 18–26, https://doi.org/10.1016/j.mechatronics.2014.11.001 (2015).

    Article  Google Scholar 

  19. 19.

    Prahlad, H. & Chopra, I. Modeling and Experimental Characterization of SMA Torsional Actuators. Journal of Intelligent Material Systems and Structures 18, 29–38, https://doi.org/10.1177/1045389x06064349 (2006).

    Article  Google Scholar 

  20. 20.

    Song, S.-H. et al. Design and analysis of a smart soft composite structure for various modes of actuation. Composites Part B: Engineering 95, 155–165, https://doi.org/10.1016/j.compositesb.2016.03.087 (2016).

    CAS  Article  Google Scholar 

  21. 21.

    Rodrigue, H., Bhandari, B., Han, M.-W. & Ahn, S.-H. A shape memory alloy-based soft morphing actuator capable of pure twisting motion. Journal of Intelligent Material Systems and Structures 26, 1071–1078, https://doi.org/10.1177/1045389x14536008 (2015).

    CAS  Article  Google Scholar 

  22. 22.

    Rodrigue, H., Wang, W., Bhandari, B., Han, M.-W. & Ahn, S.-H. SMA-based smart soft composite structure capable of multiple modes of actuation. Composites Part B: Engineering 82, 152–158, https://doi.org/10.1016/j.compositesb.2015.08.020 (2015).

    Article  Google Scholar 

  23. 23.

    Rodrigue, H., Wang, W., Bhandari, B. & Ahn, S.-H. Fabrication of wrist-like SMA-based actuator by double smart soft composite casting. Smart Materials and Structures 24, 125003, https://doi.org/10.1088/0964-1726/24/12/125003 (2015).

    CAS  Article  Google Scholar 

  24. 24.

    Jin, H. et al. Tunable smart digital structure (SDS) to modularly assemble soft actuators with layered adhesive bonding. Smart Materials and Structures 27, 015012, https://doi.org/10.1088/1361-665X/aa9a6a (2018).

    Article  Google Scholar 

  25. 25.

    Wang, W. et al. Locomotion of inchworm-inspired robot made of smart soft composite (SSC). Bioinspiration & biomimetics 9, 046006, https://doi.org/10.1088/1748-3182/9/4/046006 (2014).

    ADS  Article  Google Scholar 

  26. 26.

    Jin, H. et al. A starfish robot based on soft and smart modular structure (SMS) actuated by SMA wires. Bioinspiration & biomimetics 11, 056012, https://doi.org/10.1088/1748-3190/11/5/056012 (2016).

    ADS  Article  Google Scholar 

  27. 27.

    Kim, H.-S., Lee, J.-Y., Chu, W.-S. & Ahn, S.-H. Design and Fabrication of Soft Morphing Ray Propulsor: Undulator and Oscillator. Soft Robotics 4, 49–60, https://doi.org/10.1089/soro.2016.0033 (2017).

    CAS  Article  PubMed  Google Scholar 

  28. 28.

    Villanueva, A., Smith, C. & Priya, S. A biomimetic robotic jellyfish (Robojelly) actuated by shape memory alloy composite actuators. Bioinspiration & biomimetics 6, 036004, https://doi.org/10.1088/1748-3182/6/3/036004 (2011).

    ADS  Article  Google Scholar 

  29. 29.

    Song, S. H. et al. Turtle mimetic soft robot with two swimming gaits. Bioinspiration & biomimetics 11, 036010, https://doi.org/10.1088/1748-3190/11/3/036010 (2016).

    ADS  Article  Google Scholar 

  30. 30.

    Han, M.-W. & Ahn, S.-H. Blooming Knit Flowers: Loop-linked Soft Morphing Structures for Soft Robotics. Advanced materials 29, 1606580 (2017).

    Article  Google Scholar 

  31. 31.

    Wang, W., Rodrigue, H. & Ahn, S.-H. Deployable Soft Composite Structures. Scientific reports 6, 20869, https://doi.org/10.1038/srep20869 (2016).

    ADS  CAS  Article  PubMed  PubMed Central  Google Scholar 

  32. 32.

    Wang, W., Kim, N.-G., Rodrigue, H. & Ahn, S.-H. Modular assembly of soft deployable structures and robots. Materials Horizons 4, 367–376, https://doi.org/10.1039/c6mh00550k (2017).

    CAS  Article  Google Scholar 

  33. 33.

    Wang, W., Rodrigue, H., Kim, H.-I., Han, M.-W. & Ahn, S.-H. Soft composite hinge actuator and application to compliant robotic gripper. Composites Part B: Engineering 98, 397–405, https://doi.org/10.1016/j.compositesb.2016.05.030 (2016).

    CAS  Article  Google Scholar 

  34. 34.

    Kim, H.-I., Han, M.-W., Song, S.-H. & Ahn, S.-H. Soft morphing hand driven by SMA tendon wire. Composites Part B: Engineering 105, 138–148, https://doi.org/10.1016/j.compositesb.2016.09.004 (2016).

    Article  Google Scholar 

  35. 35.

    Wang, W. & Ahn, S. H. Shape Memory Alloy-Based Soft Gripper with Variable Stiffness for Compliant and Effective Grasping. Soft Robotics 4, 379–389, https://doi.org/10.1089/soro.2016.0081 (2017).

    Article  PubMed  Google Scholar 

  36. 36.

    Rodrigue, H., Wang, W., Kim, D.-R. & Ahn, S.-H. Curved shape memory alloy-based soft actuators and application to soft gripper. Composite Structures 176, 398–406, https://doi.org/10.1016/j.compstruct.2017.05.056 (2017).

    Article  Google Scholar 

  37. 37.

    Seok, S. et al. Meshworm: A Peristaltic Soft Robot With Antagonistic Nickel Titanium Coil Actuators. IEEE/ASME Transactions on Mechatronics 18, 1485–1497, https://doi.org/10.1109/TMECH.2012.2204070 (2013).

    Article  Google Scholar 

  38. 38.

    Koh, J.-S. & Cho, K.-K. Omega-Shaped Inchworm-Inspired Crawling Robot With Large-Index-and-Pitch (LIP) SMA Spring Actuators. IEEE/ASME Transactions on Mechatronics 18, 419–429, https://doi.org/10.1109/TMECH.2012.2211033 (2013).

    Article  Google Scholar 

  39. 39.

    Lin, H. T., Leisk, G. G. & Trimmer, B. GoQBot: a caterpillar-inspired soft-bodied rolling robot. Bioinspiration & biomimetics 6, 026007, https://doi.org/10.1088/1748-3182/6/2/026007 (2011).

    ADS  Article  Google Scholar 

  40. 40.

    Cianchetti, M., Licofonte, A., Follador, M., Rogai, F. & Laschi, C. Bioinspired Soft Actuation System Using Shape Memory Alloys. Actuators 3, 226–244, https://doi.org/10.3390/act3030226 (2014).

    Article  Google Scholar 

  41. 41.

    Noh, M., Kim, S.-W., An, S., Koh, J.-S. & Cho, K.-J. Flea-Inspired Catapult Mechanism for Miniature Jumping Robots. IEEE Transactions on Robotics 28, 1107–1017, https://doi.org/10.1109/TRO.2012.2198510 (2012).

    Article  Google Scholar 

  42. 42.

    Kim, S.-W. et al. Flytrap-inspired robot using structurally integrated actuation based on bistability and a developable surface. Bioinspiration & biomimetics 9, 036004, https://doi.org/10.1088/1748-3182/9/3/036004 (2014).

    ADS  Article  Google Scholar 

  43. 43.

    Koh, J.-S. et al. Jumping on water: Surface tension–dominated jumping of water striders and robotic insects. Science 349, 517–521, https://doi.org/10.1126/science.aab1637 (2015).

    ADS  CAS  Article  PubMed  Google Scholar 

  44. 44.

    Lee, J.-H., Chung, Y. S. & Rodrigue, H. Application of SMA spring tendons for improved grasping performance. Smart Materials and Structures 28, 035006, https://doi.org/10.1088/1361-665X/aaf5f4 (2019).

    CAS  Article  Google Scholar 

  45. 45.

    Kim, J., Lee, D.-Y., Kim, S.-R. & Cho, K.-J. A self-deployable origami structure with locking mechanism induced by buckling effect. IEEE International Conference on Robotics and Automation (ICRA),Seattle, Washington, https://doi.org/10.1109/ICRA.2015.7139635 (2015, May 26-30).

  46. 46.

    Firouzeh, A. & Paik, J. Robogami: A Fully Integrated Low-Profile Robotic Origami. Journal of Mechanisms and Robotics 7, 021009, https://doi.org/10.1115/1.4029491] (2015).

    Article  Google Scholar 

  47. 47.

    Engeberg, E. D., Dilibal, S., Vatani, M., Choi, J. W. & Lavery, J. Anthropomorphic finger antagonistically actuated by SMA plates. Bioinspiration and Biomimetics 10, 056002, https://doi.org/10.1088/1748-3190/10/5/056002 (2015).

    ADS  CAS  Article  PubMed  Google Scholar 

  48. 48.

    Haines, C. S. et al. Artificial muscles from fishing line and sewing thread. Science 343, 868–872, https://doi.org/10.1126/science.1246906 (2014).

    ADS  CAS  Article  PubMed  Google Scholar 

  49. 49.

    Park, J. et al. Electrically controllable twisted-coiled artificial muscle actuators using surface-modified polyester fibers. Smart Materials and Structures 26, 035048, https://doi.org/10.1088/1361-665X/aa5323 (2017).

    Article  Google Scholar 

  50. 50.

    Nguyen, C. T., Phung, H., Nguyen, T. D., Jung, H. & Choi, H. R. Multiple-degrees-of-freedom dielectric elastomer actuators for soft printable hexapod robot. Sensors and Actuators A: Physical 267, 505–516, https://doi.org/10.1016/j.sna.2017.10.010 (2017).

    CAS  Article  Google Scholar 

  51. 51.

    Palmre, V. et al. An IPMC-enabled bio-inspired bending/twisting fin for underwater applications. Smart Materials and Structures 22, 014003, https://doi.org/10.1088/0964-1726/22/1/014003 (2013).

    CAS  Article  Google Scholar 

  52. 52.

    Miriyev, A., Stack, K. & Lipson, H. Soft material for soft actuators. Nature communications 8, 596, https://doi.org/10.1038/s41467-017-00685-3 (2017).

    ADS  CAS  Article  PubMed  PubMed Central  Google Scholar 

  53. 53.

    Tadesse, Y., Hong, D. & Priya, S. Twelve Degree of Freedom Baby Humanoid Head Using Shape Memory Alloy Actuators. Journal of Mechanisms and Robotics 3, 011008, https://doi.org/10.1115/1.4003005 (2011).

    Article  Google Scholar 

  54. 54.

    Elahinia, M. H. & Ahmadian, M. An enhanced SMA phenomenological model: I. The shortcomings of the existing models. Smart Materials and Structures 14, 1297–1308, https://doi.org/10.1088/0964-1726/14/6/022 (2005).

    CAS  Article  Google Scholar 

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This work was supported by the convergence technology development program for bionic arm through the National Research Foundation of Korea(NRF) funded by the Ministry of Science & ICT (No. 2014M3C1B2048175).

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H.R. conceived the idea and supervised the research. J.H.L. and Y.S.C. designed the study and performed the experiments. Y.S.C. developed the control system. J.H.L. and H.R. analyzed the data, developed the model and wrote the manuscript. J.H.L., Y.S.C. and H.R. reviewed and commented on the manuscript.

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Correspondence to Hugo Rodrigue.

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Lee, JH., Chung, Y.S. & Rodrigue, H. Long Shape Memory Alloy Tendon-based Soft Robotic Actuators and Implementation as a Soft Gripper. Sci Rep 9, 11251 (2019). https://doi.org/10.1038/s41598-019-47794-1

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