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SOFT ACTUATORS
SOFT ROBOTICS DESIGN AND MANUFACTURING
7 MAY 2024

ALI SADEGHI
DEPARTMENT OF BIOMECHANICAL ENGINEERING
UNIVERSITY OF TWENTE
ACTUATOR

…. is a part of a device or machine that
helps it to achieve physical movements by
converting energy, often electrical, air, or
hydraulic, into mechanical force.*

In simple terms, it is a “mover".

2
* www.progressiveautomations.com/pages/actuators
SOFT ACTUATOR

material, structure, mechanism, etc.

…. is a part of a device or machine that
helps it to achieve physical movements by
converting energy, often electrical, air, or
hydraulic, into mechanical force, in a
compliant manner.

In simple terms, it is a “compliant mover".

3
SOFT BY Material Geometry

A combination of both

4
SOFT BY MATERIAL

5
DIELECTRIC ELECTRO ACTIVE POLYMERS (DEA)

Conductive layer

HV

Dielectric
Kovacs, G., et al. "Stacked dielectric elastomer actuator
for tensile force transmission." Sensors and actuators
A: Physical 155.2 (2009): 299-307.
Applying a voltage generates an electrostatic pressure
and causes the com pression ofdielectric layer.

6
Field-activated EAP
Can operate in room conditions for a long time
Rapid response (msec levels)
Can hold strain under dc activation
Induces relatively large actuation forces
Requires high field strength.
Bar-Cohen, Yoseph, and Iain A. Anderson. "Electroactive
polymer (EAP) actuators—background review." Mechanics of
Soft Materials 1.1 (2019): 1-14.

https://www.youtube.com/watch?v=7Qxvyw5tUko

7
SOFT FLUIDIC ACTUATORS

8
9
SOFT FLUIDIC ACTUATORS

Convert the volume change in a desired
movement such as:

Elongation
Contraction
Bending B A
Twisting,
Etc.

10
Prismatic Joint Rotary Joint Link

11
Link

12
 Link

Rotary Joint

Link
Rotary Joint

13
14
QUESTION: What would be the alternative joint-linkage model of an
inflatable ball?

15
QUESTION: What would be the alternative joint-linkage model of an
inflatable ball?

16
QUESTION: What would be the alternative joint-linkage model of an elastic
balloon?

17
QUESTION: What would be the alternative joint-linkage model of an elastic
balloon?

18
QUESTION: What would be the alternative joint-linkage model of an elastic
balloon reinforced by radial inextensible fibers?

19
P P P P

20
DESIGN ACTUATOR BEHAVIOR: EXTENSION

21
DESIGN ACTUATOR BEHAVIOR: BENDING

22
DESIGN ACTUATOR BEHAVIOR: BENDING IN 3D

23
Suzumori, Koichi, Takafumi Matsumaru, and Shoichi Iikura. "Elastically deformable fluid
actuator." U.S. Patent No. 4,976,191. 11 Dec. 1990.
DESIGN ACTUATOR BEHAVIOR: BENDING

24
Polygerinos, Panagiotis, et al. "Soft robotic glove for combined assistance and at-home
rehabilitation." Robotics and Autonomous Systems 73 (2015): 135-143.
DESIGN ACTUATOR BEHAVIOR: BY GEOMETRICAL
PARAMETERS

P

Asymmetric Structure

25
Martinez, Ramses V., et al. "Robotic tentacles with three-dimensional mobility
based on flexible elastomers." Advanced materials 25.2 (2013): 205-212.
 DESIGN ACTUATOR BEHAVIOR: BY GEOMETRICAL
PARAMETERS
Pneunet

Larger deformation by the
interconnected smaller chambers

26
Shepherd, Robert F., et al. "Multigait soft robot." Proceedings of the national
academy of sciences 108.51 (2011): 20400-20403.
QUESTION: What would be the alternative model of each design?

Larger deformation by the
interconnected smaller chambers
27
INNER WALLS RESULT LIMITED INFLATION AND LARGER BENDING

Pneunet

28
QUESTION

Any solution for design a contractive fluidic actuator?

29
DESIGN ACTUATOR BEHAVIOR: CONTRACTION

30
DESIGN ACTUATOR BEHAVIOR: CONTRACTION

Byrne, Oisín, et al. "Additive manufacture of composite
soft pneumatic actuators." Soft robotics 5.6 (2018)

Pneum atic artificialm uscles PAM

31
DESIGN ACTUATOR BEHAVIOR: CONTRACTION

𝛼2

l2

𝛼1

l1

M cKibben Actuator

32

https://www.youtube.com/watch?v=oBkdKeTJ5NY
DESIGN ACTUATOR BEHAVIOR: TWISTING

https://www.youtube.com/watch?v=RsJ3hrFGrSk

33
Byrne, Oisín, et al. "Additive manufacture of composite soft pneumatic
actuators." Soft robotics 5.6 (2018): 726-736.
FABRICS

Knitted fabric

Multi directional Stretchability

34
FABRICS

Woven Fabric

Inextensible; particularly in the
direction of wrap and weft

35
EXTENSIBILITY BY PLEATED GEOMETRY

Yap, Hong Kai, et al. "Design and characterization of low-cost fabric-based flat
pneumatic actuators for soft assistive glove application." 2017 International 36
Conference on Rehabilitation Robotics (ICORR). IEEE, 2017.
BENDING BY ASYMMETRIC EXTENSIBILITY
Mono directional extensible Fabric

inextensible Fabric

Elastic Wrap

37
 requires higher pressure for Easier extension; requires lower
extension pressure for extension
Acceptable stiffness even in the Less stiff in the mid-range
mid-range extension/bending extension/bending
Stiff at the end of bending course Stiff at the end of bending course

38
TEXTILE BASED SOFT ACTUATORS

39
Thalman, Carly M., et al. "A novel soft elbow exosuit to supplement bicep lifting
capacity." IROS IEEE, 2018.
ACTUATION BY INEXTENSIBILITY OF TEXTILE

40
Thalman, Carly M., et al. "Design of a soft ankle-foot orthosis exosuit for foot
drop assistance." ICRA IEEE, 2019.
SOFT ACTUATION BY NEGATIVE PRESSURE

41
QUESTION

Any solution for generating motion (such as contraction) by vacuum?

42
DESIGN ACTUATOR BEHAVIOR: CONTRACTION

VACUUM

43
Positive pressure/expansion elongation Negative pressure/collapse & contraction

Resist extension Resist buckling

44
DESIGN ACTUATOR BEHAVIOR: CONTRACTION

VACUUM

45
 46
Yang, Dian, et al. "Buckling pneumatic linear actuators inspired by
muscle." Advanced Materials Technologies 1.3 (2016): 1600055.
 47
Li, Shuguang, et al. "Fluid-driven origami-inspired artificial muscles." Proceedings of the
National academy of Sciences 114.50 (2017): 13132-13137.
FOAM ACTUATORS

48
Robertson, Matthew A., and Jamie Paik. "New soft robots really suck: Vacuum-
powered systems empower diverse capabilities." Science Robotics 2.9 (2017).
FOAM ACTUATORS

Rigid body

Inextensible Fabric
Soft Foam

Vacuum gate

49

Babu, SP Murali, et al.., et al. R-AL 2020
FOAMY SOFT SENSORY ACTUATORS

50

Murali Babu, Saravana Prashanth, et al. Advanced Intelligent Systems 2021
FOAMY SOFT SENSORY ACTUATORS

Babu, S. P. M., et al, IEEE Robotics and Babu, S. P. M., et al, Advanced Intelligent
Automation Letters, 2020 Systems 2021

51
PNEUNET CAN WORK WITH BOTH POSITIVE & NEGATIVE PRESSURES

52
QUESTIONS?

53
 SOFT ACTUATORS
SOFT ROBOTICS DESIGN AND MANUFACTURING
7 MAY 2024

ALI SADEGHI
DEPARTMENT OF BIOMECHANICAL ENGINEERING
UNIVERSITY OF TWENTE
ACTUATOR

…. is a part of a device or machine that
helps it to achieve physical movements by
converting energy, often electrical, air, or
hydraulic, into mechanical force.*

In simple terms, it is a “mover".

2
* www.progressiveautomations.com/pages/actuators
SOFT ACTUATOR

material, structure, mechanism, etc.

…. is a part of a device or machine that
helps it to achieve physical movements by
converting energy, often electrical, air, or
hydraulic, into mechanical force, in a
compliant manner.

In simple terms, it is a “compliant mover".

3
SOFT BY Material Geometry

A combination of both

4
SOFT BY MATERIAL

5
DIELECTRIC ELECTRO ACTIVE POLYMERS (DEA)

Conductive layer

HV

Dielectric
Kovacs, G., et al. "Stacked dielectric elastomer actuator
for tensile force transmission." Sensors and actuators
Applying a voltage generates an electrostatic pressure A: Physical 155.2 (2009): 299-307.

and causes the compression of dielectric layer.

6
Field-activated EAP
Can operate in room conditions for a long time
Rapid response (msec levels)
Can hold strain under dc activation
Induces relatively large actuation forces
Requires high field strength.
Bar-Cohen, Yoseph, and Iain A. Anderson. "Electroactive
polymer (EAP) actuators—background review." Mechanics of
Soft Materials 1.1 (2019): 1-14.

https://www.youtube.com/watch?v=7Qxvyw5tUko

7
SOFT FLUIDIC ACTUATORS

8
9
SOFT FLUIDIC ACTUATORS

Convert the volume change in a desired
movement such as:

Elongation
Contraction
Bending B A
Twisting,
Etc.

10
Prismatic Joint Rotary Joint Link

11
Link

12
 Link

Rotary Joint

Link
Rotary Joint

13
14
QUESTION: What would be the alternative joint-linkage model of an
inflatable ball?

15
QUESTION: What would be the alternative joint-linkage model of an
inflatable ball?

16
QUESTION: What would be the alternative joint-linkage model of an elastic
balloon?

17
QUESTION: What would be the alternative joint-linkage model of an elastic
balloon?

18
QUESTION: What would be the alternative joint-linkage model of an elastic
balloon reinforced by radial inextensible fibers?

19
P P P P

20
DESIGN ACTUATOR BEHAVIOR: EXTENSION

21
DESIGN ACTUATOR BEHAVIOR: BENDING

22
DESIGN ACTUATOR BEHAVIOR: BENDING IN 3D

23
Suzumori, Koichi, Takafumi Matsumaru, and Shoichi Iikura. "Elastically deformable fluid
actuator." U.S. Patent No. 4,976,191. 11 Dec. 1990.
DESIGN ACTUATOR BEHAVIOR: BENDING

24
Polygerinos, Panagiotis, et al. "Soft robotic glove for combined assistance and at-home
rehabilitation." Robotics and Autonomous Systems 73 (2015): 135-143.
DESIGN ACTUATOR BEHAVIOR: BY GEOMETRICAL
PARAMETERS

P

Asymmetric Structure

25
Martinez, Ramses V., et al. "Robotic tentacles with three‐dimensional mobility
based on flexible elastomers." Advanced materials 25.2 (2013): 205-212.
 DESIGN ACTUATOR BEHAVIOR: BY GEOMETRICAL
PARAMETERS
Pneunet

Larger deformation by the
interconnected smaller chambers

26
Shepherd, Robert F., et al. "Multigait soft robot." Proceedings of the national
academy of sciences 108.51 (2011): 20400-20403.
QUESTION: What would be the alternative model of each design?

Larger deformation by the
interconnected smaller chambers
27
INNER WALLS RESULT LIMITED INFLATION AND LARGER BENDING

Pneunet

28
QUESTION

Any solution for design a contractive fluidic actuator?

29
DESIGN ACTUATOR BEHAVIOR: CONTRACTION

30
DESIGN ACTUATOR BEHAVIOR: CONTRACTION

Byrne, Oisín, et al. "Additive manufacture of composite
soft pneumatic actuators." Soft robotics 5.6 (2018)

Pneumatic artificial muscles PAM

31
DESIGN ACTUATOR BEHAVIOR: CONTRACTION

𝛼2

l2

𝛼1

l1

McKibben Actuator

32

https://www.youtube.com/watch?v=oBkdKeTJ5NY
DESIGN ACTUATOR BEHAVIOR: TWISTING

https://www.youtube.com/watch?v=RsJ3hrFGrSk

33
Byrne, Oisín, et al. "Additive manufacture of composite soft pneumatic
actuators." Soft robotics 5.6 (2018): 726-736.
FABRICS

Knitted fabric

Multi directional Stretchability

34
FABRICS

Woven Fabric

Inextensible; particularly in the
direction of wrap and weft

35
EXTENSIBILITY BY PLEATED GEOMETRY

Yap, Hong Kai, et al. "Design and characterization of low-cost fabric-based flat
pneumatic actuators for soft assistive glove application." 2017 International 36
Conference on Rehabilitation Robotics (ICORR). IEEE, 2017.
BENDING BY ASYMMETRIC EXTENSIBILITY
Mono directional extensible Fabric

inextensible Fabric

Elastic Wrap

37
 requires higher pressure for Easier extension; requires lower
extension pressure for extension
Acceptable stiffness even in the Less stiff in the mid-range
mid-range extension/bending extension/bending
Stiff at the end of bending course Stiff at the end of bending course

38
TEXTILE BASED SOFT ACTUATORS

39
Thalman, Carly M., et al. "A novel soft elbow exosuit to supplement bicep lifting
capacity." IROS IEEE, 2018.
ACTUATION BY INEXTENSIBILITY OF TEXTILE

40
Thalman, Carly M., et al. "Design of a soft ankle-foot orthosis exosuit for foot
drop assistance." ICRA IEEE, 2019.
SOFT ACTUATION BY NEGATIVE PRESSURE

41
QUESTION

Any solution for generating motion (such as contraction) by vacuum?

42
DESIGN ACTUATOR BEHAVIOR: CONTRACTION

VACUUM

43
Positive pressure/expansion elongation Negative pressure/collapse & contraction

Resist extension Resist buckling

44
DESIGN ACTUATOR BEHAVIOR: CONTRACTION

VACUUM

45
 46
Yang, Dian, et al. "Buckling pneumatic linear actuators inspired by
muscle." Advanced Materials Technologies 1.3 (2016): 1600055.
 47
Li, Shuguang, et al. "Fluid-driven origami-inspired artificial muscles." Proceedings of the
National academy of Sciences 114.50 (2017): 13132-13137.
FOAM ACTUATORS

Rigid body

Inextensible Fabric
Soft Foam

Vacuum gate

49

Babu, SP Murali, et al.., et al. R-AL 2020
FOAMY SOFT SENSORY ACTUATORS

50

Murali Babu, Saravana Prashanth, et al. Advanced Intelligent Systems 2021
FOAMY SOFT SENSORY ACTUATORS

Babu, S. P. M., et al, IEEE Robotics and Babu, S. P. M., et al, Advanced Intelligent
Automation Letters, 2020 Systems 2021

51
PNEUNET CAN WORK WITH BOTH POSITIVE & NEGATIVE PRESSURES

52
QUESTIONS?

53
 SOFT ACTUATORS
SOFT ROBOTICS DESIGN AND MANUFACTURING
14 MAY 2024

ALI SADEGHI
DEPARTMENT OF BIOMECHANICAL ENGINEERING
UNIVERSITY OF TWENTE
Prismatic Joint Rotary Joint Link

55
Link

56
QUESTION: What would be the alternative joint-linkage model of an
inflatable ball?

57
QUESTION: What happen if we add positive pressure inside this
geometry?

58
QUESTION: What happen if we add positive pressure inside each
geometry?

1 2 5

3 4

59
QUESTION: What happen if we add positive pressure inside each
geometry?
5
1

4
2&3

60
QUESTION: What if we apply negative pressure?

61
QUESTION: What happen if we add positive pressure inside each
geometry?

Extensible Textile Extensible Textile

Inextensible Textile Inextensible Textile

62
QUESTION: How to make a bending finger with textile?

What about a segmented bending
finger?

63
SOFT BY Material Geometry

A combination of both

64
SOFT BY GEOMETRY

65
QUESTION

Do you know any actuation technique that is soft because of its geometry?

66
FIBER LIKE ACTUATORS

CABLE DRIVEN
TENDON DRIVEN
WIRE DRIVEN

67
COMPLIANT POWER TRANSMITTERS

Transmit the power from a bulky and
powerful system to a miniature,
compact mechanism in a compliant
manner

Benefit the maturity of rigid robotics in
actuation & control

https://www.youtube.com/watch?v=71BxGuRCH4A

68
SCALABLE

69
WIDELY USED IN SOFT ASSISTIVE AND REHABILITATION ROBOTICS

Transmit the power from a bulky and powerful
system to a miniature, compact mechanism in
a compliant manner
Relatively silent
Relatively energy efficient

70
WIDELY USED IN SOFT ASSISTIVE AND REHABILITATION ROBOTICS

71
SNU BioRobotics Lab
GEOMETRICALLY CAN SIMULATE NATURAL TENDONS AND MUSCLE
FIBERS

https://www.youtube.com/watch?v=GzXvqFWgIs4

72
Min, Sungjae, and Sooyeong Yi. "Development of Cable-driven Anthropomorphic Robot
Hand." IEEE Robotics and Automation Letters 6.2 (2021): 1176-1183.
POSSIBILITY OF UNDER-ACTUATION

73
Manti, Mariangela, et al. "An under-actuated and adaptable soft robotic
gripper." Conference on Biomimetic and Biohybrid Systems. 2015.
PREDEFINED DEFORMATIONS BY ADDING NODES TO THE CABLE

Node
Fixing Point Guide/Stopper
Fixing Point

74
COMPLEX DEFORMATIONS BY ARRANGING FIBER LOCATION IN SOFT
STRUCTURE

75
Mazzolai, Barbara, et al. "Octopus‐Inspired Soft Arm with Suction Cups for Enhanced
Grasping Tasks in Confined Environments." Advanced Intelligent Systems 1.6 (2019)
CABLES CAN PULL BUT NOT PUSH
Solutions for bidirectional motion?

Fixing point

Guide

A1
A1 A2 A1

One actuator Two actuators Spring

76
 Fixed joint stiffness Adjustable joint stiffness by Force on the spring side is determined
Asymmetric displacement of cables antagonistic actuation by the pretension and the stiffness of
can affect the tension of the cable Controlled tension on either spring.
that results in; or loosening or side The actuator force is smaller than other
overloading of cable on one side. Doubled number of actuators is mechanisms when the same actuator is
Design consideration for cable required used, because the actuator is required
tensioning is required to pull the spring.
The cable tension can always be
maintained appropriately without
additional components.
Simple cable routing

77
Jung, Yeongtae, and Joonbum Bae. "An asymmetric cable-driven mechanism for force
control of exoskeleton systems." Mechatronics 40 (2016): 41-50.
TENDON DRIVEN ARM AND GRIPPER

78
Mishra, Anand Kumar, et al. "SIMBA: Tendon-driven modular continuum arm with soft
reconfigurable gripper." Frontiers in Robotics and AI 4 (2017): 4.
 https://www.youtube.com/watch?v=lG-a8kHVwN0&t=9s

79
Bern, James M., et al. "Trajectory Optimization for Cable-Driven Soft Robot
Locomotion." Robotics: Science and Systems. 2019.
ANTAGONISTIC ACTUATION AND STIFFNESS TUNING

https://www.youtube.com/watch?v=lG-a8kHVwN0&t=9s

80
Bern, James M., et al. "Trajectory Optimization for Cable-Driven Soft Robot
Locomotion." Robotics: Science and Systems. 2019.
SHAPE MEMORY ALLOY (SMA) WIRES

Al-Humairi, Safaa Najah Saud. "Cu-based shape memory alloys: modified structures and their 81
related properties." Recent Advancements in the Metallurgical Engineering and
Electrodeposition (2019).
SMA ACTUATORS

“Nitinols are:
relatively soft and malleable at the
martensite phase (Young's modulus:
∼28–41 GPa)
&
transform into a hard and rigid austenite
phase (Young's modulus: ∼82–100 GPa)
when heated beyond a threshold
temperature.”

Huang, Xiaonan, et al. "Shape memory materials for electrically-
powered soft machines." Journal of Materials Chemistry B 8.21 (2020):
4539-4551.

https://youtu.be/g8oS8rzAQXk?t=33

82
 SMA ACTUATORS

High force-to-weight ratio (∼100)
Fast actuation response (L1

A

A2>A1
42
Force, touch and deformation
sensing by 3D printed conductive
foam and fibers
Deformation of composite can cause result rearrangement of
particles and result change of resistance.

43
Hybrid & Sensorized Soft Robotics Hand
by Multi Material 3D Printing
Bone Luca Grignaffini

Ninjaflex

PLA

44
 Resin Based
Off the Shelf 3D Printing Solutions
Filament Based

Dragon
Ecoflex Skin

SEBS family
(Styrene-ethylene-
butylene-styrene)

45
Buckling of the soft filaments is a
challenge in FDM printing

Filament

Feeder

Heater
Nozzle

46
Pellet Extrusion a Solution for FDM
Printing of Hyper Elastic Thermoplastics

47
SEBS Soft Like Dragonskin

48
N. Willemstein, H. van der Kooij, A. Sadeghi “3D Printing of thin highly expandable
thermoplastic membranes” To be uploaded on arXiv
SOFT SENSOR BASED ON FLUIDIC PRESSURE

49
N. Willemstein, H. van der Kooij, A. Sadeghi “3D Printing of thin highly expandable thermoplastic
membranes” Submitted
 50
Zou, Shibo, et al. "A retrofit sensing strategy for soft fluidic robots." Nature
Communications 15.1 (2024): 539.
 SOFT SENSOR BASED ON FLUIDIC PRESSURE

Deformable chamber Pressure Sensor

51
Gruebele, Alexander, et al. "A Stretchable Tactile Sleeve for Reaching into
Cluttered Spaces." IEEE Robotics and Automation Letters (2021).
Making rubber structures even Gas producing chemical reaction
softer by adding porosity to them

Gas injection

Dissolvable agents/particles Gas

52
InFoam Method:
Exploiting liquid rope coiling for
printing porous structures. Nick Willemstein

53
N. Willemstein, H. van der Kooij, A. Sadeghi "Direct 3D Printing of Soft Fluidic
Actuators with Graded Porosity." Soft Matter (2022)
InFoam Method:
Graded porosity & higher
flexibility 200 times lower stiffness

54
N. Willemstein, H. van der Kooij, A. Sadeghi "Direct 3D Printing of Soft Fluidic
Actuators with Graded Porosity." Soft Matter (2022)
Graded Porosity for Programming Actuator Behavior

55
N. Willemstein, H. van der Kooij, A. Sadeghi "Direct 3D Printing of Soft Fluidic
Actuators with Graded Porosity." Soft Matter (2022)
Force, Touch and Deformation
Sensing by 3D printed Conductive
Foam and Fibers

56
57
58
 Willemstein, N., Sridar, S., van der Kooij, H., & Sadeghi, A. 3D Printed Graded 59
Porous Sensors for Soft Sensorized Insoles with Gait Phase & Ground Reaction
Forces Estimation. arXiv 2023
Soft sensors saturate quickly Muti resolution sensing by InFoam method

Force
Force

Soft sensor can saturate
quickly

Time Time

60
N. Willemstein, H. van der Kooij, A. Sadeghi "Graded Foam Sensor for Multi-Resolution
Grasping Force Sensing." submitted to Soft Matter
Muti resolution sensing

Minimum load of 2 gram (a paper clip) Maximum applied load of 3.750 Kg

61
N. Willemstein, H. van der Kooij, A. Sadeghi "Graded Foam Sensor for Multi-Resolution
Grasping Force Sensing." submitted to Soft Matter
OTHER METHODS?

62
OPTICAL FIBER BENDING SENSOR

Higher light intensity output after bending

63
Zhao, Huichan, Rukang Huang, and Robert F. Shepherd. "Curvature control of
soft orthotics via low cost solid-state optics." 2016 ICRA.
OPTICAL FIBER BENDING SENSOR

Engraved pattern
Darling transistor

64
Zhao, Huichan, Rukang Huang, and Robert F. Shepherd. "Curvature control of
soft orthotics via low cost solid-state optics." 2016 ICRA.
INDUCTIVE SOFT SENSOR

Ecoflex 0010 blended with the same weight of
iron powder (Sigma Aldrich, CAS#7439-89-6,
Product#12310, MO, USA), resulting 11.7% iron
particles of the total composite volume.

65
Wang, Hongbo, et al. "A wireless inductive sensing technology for soft pneumatic
actuators using magnetorheological elastomers." 2019 RoboSoft.
INDUCTIVE SOFT SENSOR

66
Wang, Hongbo, et al. "A wireless inductive sensing technology for soft pneumatic
actuators using magnetorheological elastomers." 2019 RoboSoft.
SHAPE SENSING BY
LEARNING
ALGORITHMS

Recorded by camera

Constructed by sensor measurements and trained prior

67
Glauser, Oliver, et al. "Deformation capture via soft and stretchable sensor
arrays." ACM Transactions on Graphics (TOG) 38.2 (2019): 1-16.
ANYTHING (SOFT) THAT CAN
CONVERT THE
DEFORMATION/MOVEMENTS/IN
TERACTIONS OF A SOFT
ROBOT TO A MEASURABLE
SIGNAL COULD POTENTIALLY
BE USED AS A SOFT SENSING
SOLUTION.

68
QUESTION?

69
 SOFT ROBOTICS
Stiffness Regulation Techniques
ALI SADEGHI
DEPARTMENT OF BIOMECHANICAL ENGINEERING
30 MAY 2024 (LECTURE 5)
WHAT IS STIFFNESS MODULATION?
𝑭𝒐𝒓𝒄𝒆 (𝑭)
𝒔𝒕𝒊𝒇𝒇𝒏𝒆𝒔𝒔(𝑲) =
𝑫𝒆𝒇𝒐𝒓𝒎𝒂𝒕𝒊𝒐𝒏 (𝜹)

Transition between soft and stiff

2
WHY STIFFNESS MODULATION?

In rigid robotics:
It can provide compliance, safe & adaptive
interaction &…

In soft robotics:
To withstand/apply load
Increase robot controllability
Actuation and storing energy
Shape locking and energy saving
Morphing & …

3
IF YOU WHAT TO REGULATE YOUR SOFT ROBOT
STIFFNESS, WHAT KIND OF SOLUTION/S YOU
WILL THINK ABOUT?

By
Actuation itself
Structure/geometry
Material properties
Combination of all

4
STIFFNESS MODULATION
BY
SOFT ACTUATION

5
ANTAGONISTIC ACTUATION

https://keystagewiki.com/index.php/Antagonistic_Muscles

Migliore, Shane A., Edgar A. Brown, and Stephen P. DeWeerth.
"Biologically inspired joint stiffness control." ICRA, 2005.

6
ANTAGONISTIC ACTUATION

PAM2
PAM1

P1

https://keystagewiki.com/index.php/Antagonistic_Muscles

Verrelst, Björn, et al. "The pneumatic biped “Lucy”
actuated with pleated pneumatic artificial
muscles." Autonomous Robots 18.2 (2005): 201-213.

7
ANTAGONISTIC FLUIDIC/CABLE DRIVEN ACTUATION

Positive pressure

Cable actuators

8
McMahan, William, Bryan A. Jones, and Ian D. Walker. "Design and
implementation of a multi-section continuum robot: Air-octor." IROS 2005.
 9
Maghooa, Farahnaz, et al. "Tendon and pressure actuation for a bio-inspired
manipulator based on an antagonistic principle." ICRA 2015.
ANTAGONISTIC ACTUATION

10
Babu, S. M., Sadeghi, A., Mondini, A., & Mazzolai, B. Antagonistic pneumatic actuators
with variable stiffness for soft robotic applications. RoboSoft 2019
STIFFNESS TUNABLE SOFT ACTUATION
WHY?

11
Carpi, Federico, et al. "Enabling variable-stiffness hand rehabilitation orthoses with
dielectric elastomer transducers." Medical engineering & physics 36.2 (2014): 205-211.
12
STIFFNESS TUNING AT
STRUCTURAL LEVEL

13
 GEOMETRICAL SOLUTIONS

Stiff

Directional stiffness due to the
asymmetric section of leaf springs Leaf spring

Flexible
14
GEOMETRICAL SOLUTIONS

15
ANY IDEA?

16
GEOMETRICAL SOLUTIONS

17
Zhai, Zirui, et al. "In situ stiffness manipulation using elegant curved
origami." Science advances 6.47 (2020): eabe2000.
GEOMETRICAL SOLUTIONS

18
GRANULAR JAMMING

Fluid-like medium

Vacuum

Solid-like and Stiff
Friction between granules results a
higher structural stiffness

19

Brown, Eric, et al. “PNAS 2010
 20

Brown, Eric, et al. “PNAS 2010
GRANULAR JAMMING

21
Arezzo, Alberto, et al. "Total mesorectal excision using a soft and flexible robotic arm: a
feasibility study in cadaver models." Surgical endoscopy 31.1 (2017): 264-273.
HIGHLY ARTICULATED ARM

https://www.youtube.com/watch?v=0DNJwM8lyBo

22
Cheng, Nadia G., et al. "Design and analysis of a robust, low-cost, highly articulated
manipulator enabled by jamming of granular media." ICRA, 2012.
 23
Cheng, Nadia G., et al. "Design and analysis of a robust, low-cost, highly articulated
manipulator enabled by jamming of granular media." ICRA, 2012.
SHAPE MORPHING & LOCOMOTION BY STIFFNESS TUNABLE SKIN

https://www.youtube.com/watch?v=SbqHERKdlK8

24
Steltz, Erik, et al. "Jsel: Jamming skin enabled locomotion." 2009 IEEE/RSJ
International Conference on Intelligent Robots and Systems. IEEE, 2009.
STIFFNESS TUNABLE SKIN FOR HAPTIC & INTERACTIVE TECHNOLOGY

https://www.youtube.com/watch?v=rZZ1rhUvTLA

25
Stanley, Andrew A., et al. "Haptic jamming: A deformable geometry, variable stiffness tactile
display using pneumatics and particle jamming." WHC IEEE, 2013.
STIFFNESS TUNABLE FINGERS & PASSIVE GRANULAR JAMMING

26
Li, Yingtian, et al. "Passive particle jamming and its stiffening of soft robotic
grippers." IEEE Transactions on Robotics 33.2 (2017): 446-455.
HIGHLY ADAPTABLE SUCKER

Vacuum
Coffee

Soft Joint

Air

27
 SOME PRACTICAL OUTCOMES
Arman Goshtasbi

Vacuum
Coffee Collapse of rubbery membrane by vacuum Vacuum
Soft Joint results granular jamming of coffee grains
Air Stiff Joint

45° 60° 85° 75° 60° 45°

28
Goshtasbi, Arman, and Ali Sadeghi. "A bioinspired stiffness tunable sucker for passive adaptation
and firm attachment to angular substrates." Frontiers in Robotics and AI 10 (2023).
29
 LAYER JAMMING
No vacuum; flexible structure
due to the gap between
layers

Flexible layers
Flexible airtight bag
(e.g. paper)

Vacuum
Friction between layers results https://www.youtube.com/watch?v=bzeCr5YaXWI
a higher structural stiffness

30
Narang, Yashraj S., Joost J. Vlassak, and Robert D. Howe. "Mechanically versatile soft
machines through laminar jamming." Advanced Functional Materials 2018
 LAYER JAMMING

Paper

31
Kim, Yong-Jae, et al. "Design of a tubular snake-like manipulator with stiffening capability by
layer jamming." IROS, 2012.
 32
Gao, Yuan, et al. "A novel variable stiffness compliant robotic gripper based on
layer jamming." Journal of Mechanisms and Robotics 12.5 (2020).
LAYER JAMMING

https://www.youtube.com/watch?v=v_jZ8EBBUuA&t=222s

33
HOW THEORETICALLY YOU CAN EXPLAIN IT?

L

34
TEXTILE JAMMING

Before vacuum After vacuum

35
Sadeghi, Ali, et al. "Preliminary experimental study on variable stiffness structures based
on textile jamming for wearable robotics." WeRob 2018.
TEXTILE JAMMING

Under pressure, hinges are locked
by intraction of rigid segments
36
Sadeghi, Ali, et al. "Preliminary experimental study on variable stiffness structures based
on textile jamming for wearable robotics." WeRob 2018.
TEXTILE JAMMING

37
Sadeghi, Ali, et al. "Preliminary experimental study on variable stiffness structures based
on textile jamming for wearable robotics." WeRob 2018.
TEXTILE BASED CLUTCH (TBC)

In the disengaged mode the semi-spherical
bumps easily slide over each other.

38

Sadeghi, A. et al. "A Vacuum Powered Soft Textile-Based Clutch." Actuators. 2019.
TEXTILE BASED CLUTCH (TBC)

10 Kg

No vacuum P = -0.8 atm

39

Sadeghi, A. et al. "A Vacuum Powered Soft Textile-Based Clutch." Actuators. 2019.
SENSORIZED TEXTILE BASED CLUTCH (STBC)

40
Sadeghi, Ali, et al. "A Wearable Sensory Textile‐Based Clutch with High Blocking
Force." Advanced Engineering Materials 21.11 (2019): 1900886.
QUASI PASSIVE SOFT EXOSKELETON BY SOFT STIFFNESS TUNING

41
ELECTRO-ADHESION SOFT CLUTCHES

Hinchet, Ronan, & Herbert Shea. "High Force Density Textile Diller, Stuart B., et al. "The effects of electroadhesive clutch
Electrostatic Clutch." Advanced Materials Technologies 2020 design parameters on performance characteristics." Journal of
Intelligent Material Systems and Structures 2018

42
Rigid segments are placed inside the rope

https://www.freemagictricks4u.com/rope-tricks.html

43
 44
Sadeghi, Ali, et al. "soft-legged Wheel-Based robot with Terrestrial locomotion
abilities." Frontiers in Robotics and AI 3 (2016): 73.
LOW MELTING MATERIALS: WAX

45
Cheng, Nadia G., et al. "Thermally tunable, self‐healing composites for soft
robotic applications." Macromolecular Materials and Engineering 2014
LOW MELTING MATERIALS: LOW MELTING POINT ALLOY (LMPA)
Melting temperature: (47–62 °C, depending on the alloy composition).
In the solid state, they have relatively high stiffnesses(e.g. more than 3 Gpa.)

Fabrication process for the self healing properties

46
Tonazzini, Alice, et al. "Variable stiffness fiber with self‐healing
capability." Advanced Materials 28.46 (2016): 10142-10148.
LOW MELTING MATERIALS: LOW MELTING POINT ALLOY (LMPA)

47
Tonazzini, Alice, et al. "Variable stiffness fiber with self‐healing
capability." Advanced Materials 28.46 (2016): 10142-10148.
LOW MELTING MATERIALS: THERMO PLASTICS

48
Coulson, Ryan, et al. "Versatile Soft Robot Gripper Enabled by Stiffness and
Adhesion Tuning via Thermoplastic Composite." Soft Robotics (2021).
 LOW MELTING MATERIALS: CONDUCTIVE THERMO PLASTICS

Commercially available conductive
thermoplastic 3D printer filament

49
Taghavi, Majid, et al. "3D-printed ready-to-use variable-stiffness structures." IEEE
Robotics and Automation Letters 3.3 (2018): 2402-2407.
ELECTRORHEOLOGICAL (ER) FLUIDS

Electrorheological (ER) fluids are suspensions of
extremely fine dielectric particles (up to 50μm
diameter) in an electrically insulating fluid. The
apparent viscosity of these fluids changes
reversibly up to 100,000 times in response to an
electric field.

HV

50

Sadeghi, Alì, et al. "Innovative soft robots based on electro-rheological fluids." IROS 2012
STIFFNESS TUNABLE COMPOSITE BASED ON ELECTRORHEOLOGICAL
FLUIDS

Porous Matrix

ER Fluid Electrodes

51
ERF STIFFNESS TUNABLE SENSORY COMPOSITE
High Voltage
parallel lines

ERF chambers
Ecoflex 0030

Conductive textile as HV electrodes

Ecoflex 0030
ERF chambers
52
ELECTRORHEOLOGICAL VALVES

53

Sadeghi, Alì, et al. "Innovative soft robots based on electro-rheological fluids." IROS 2012
FLUIDIC CONTROL BY ER VALVES

Two valves are integrated in a single structure

54

Sadeghi, Alì, et al. "Innovative soft robots based on electro-rheological fluids." IROS 2012
FLUIDIC CONTROL & STIFFNESS MODULATION BY ER VALVES

55

Sadeghi, Alì, et al. "Innovative soft robots based on electro-rheological fluids." IROS 2012
MAGNETORHEOLOGICAL (MR) FLUID BASED CLUTCH

56
Majidi, Carmel, and Robert J. Wood. "Tunable elastic stiffness with microconfined
magnetorheological domains at low magnetic field." Applied Physics Letters 97.16 (2010)
FLUIDIC CONTROL BY MR VALVE

https://www.youtube.com/watch?v=2eILuBbEH_k

57
McDonald, Kevin, et al. "Magnetorheological Fluid‐Based Flow Control for Soft
Robots." Advanced Intelligent Systems 2020
WHICH OF THE DISCUSSED TECHNIQUES LOOKS MORE PROMISING
AND WHY?

https://www.dewivandeklomp.nl/
58
STIFFNESS TUNABLE SUCKER FOR UNEVEN SURFACES, BASED ON
GRANULAR JAMMING

Vacuum Gate

Granular medium

Suction cavity

59
SOFT ACESSORIES

60
SOFT KINK VALVES

Luo, Kai, et al. "Soft kink valves." Journal of the Rothemund, Philipp, et al. "A soft, bistable valve
Mechanics and Physics of Solids 131 (2019): 230-239. for autonomous control of soft
actuators." Science Robotics 2018

61
VALVE INTEGRATED SUCKER

Touching a substrate causes the sucker
deformation & results the opening of
negative pressure/vacuum to the sucker
cavity.
62
PRESSURE
GENERATION AND
PUMPING

63
PEANO HASEL Hydraulically amplified self-healing electrostatic (HASEL)

64
Wang, Xingrui, et al. "High‐Strain Peano‐HASEL Actuators." Advanced
Functional Materials 30.7 (2020): 1908821.
COMBUSTION

Butane and Oxygen

65
Bartlett, Nicholas W., et al. "A 3D-printed, functionally graded soft robot powered
by combustion." Science 349.6244 (2015): 161-165.
 CHEMICAL REACTION

Hydrogen peroxide as the fuel in the presence of the
platinum catalyst results the following reaction:
2H2O2 (l) → 2H2O (l, g) + O2 (g). Check the Ref.

This reaction results in volumetric expansion by a factor of
approximately 240 (at ambient pressure).
At the operating pressure of 50 kPa, an expansion to 160
times the original volume is expected.

66
Wehner, Michael, et al. "An integrated design and fabrication strategy for entirely
soft, autonomous robots." Nature 536.7617 (2016): 451-455.
ELECTRIC COMMANDED EVAPORATION

67
Miriyev, Aslan, Kenneth Stack, and Hod Lipson. "Soft material for soft actuators." Nature
communications 8.1 (2017): 1-8.
LIGHT COMMANDED EVAPORATION
PLASMONIC EFFECT

Laser irradiation (808 nm, 475 mW cm-2)

68
Meder, Fabian, et al. "Remotely Light‐Powered Soft Fluidic Actuators Based on
Plasmonic‐Driven Phase Transitions in Elastic Constraint." Advanced Materials 2019.
 69
Meder, Fabian, et al. "Remotely Light‐Powered Soft Fluidic Actuators Based on
Plasmonic‐Driven Phase Transitions in Elastic Constraint." Advanced Materials 2019.
 HUMIDITY RESPONSIVE ACTUATORS
Plant materials rich source of inspiration for smart fabrics and composites
Conifer tissue

70
QUESTIONS?

71
Embodied Intelligence &
Bio Inspired Soft Robotics
Ali Sadeghi
Department of Biomechanical Engineering
Faculty of Engineering Technology
04-06-2024
Nature inspired
ART vs. ENGINEERING

Nature-inspired art is often subjective
and focused on emotional and aesthetic
qualities,
while engineering is objective and
focused on functionality and problem-
solving.

I²CBaMBUS, a flower robot
by BBS 1 - Technik - Kaiserslautern

2
WHAT IS INTELLIGENCE?
WHICH ONE IS MORE INTELLIGENT & WHY?

3
INTELLIGENCE

Merriam Webster
The ability to learn or understand or to
deal with new or trying situations

Journal of Educational Psychology (1921)
The ability to carry on abstract thinking. L. Terman
The capacity to learn or profit by experience. W. F. Dearborn
Having learned or ability to learn to adjust oneself to the environment. S. S. Colvin
The ability to adapt oneself adequately to relatively new situations in life. R. Pintner
The capacity for knowledge, and knowledge possessed. V. A. C. Henmon
4
EMBODIED INTELLIGENCE (EI)

The classical approach: The focus is Embodied Intelligence: The focus is on
on the brain and central processing. the interaction with the environment.

5
Pfeifer, Rolf, and Josh Bongard. How the body shapes the way we think: a new
view of intelligence. MIT press, 2006.
PHYSICAL INTELLIGENCE (PI)

PHYSICAL INTELLIGENCE (PI)

EI
ENVIRONMENT BODY BRAIN

6
Sitti, Metin. "Physical intelligence as a new
paradigm." Extreme Mechanics Letters 46 (2021): 101340.
BODY’S PERFORMANCE AFFECTS
BRAIN’S COMPUTATION LOAD

7
STRANDBEAST A GOOD EXAMPLE OF
PHYSICAL INTELLIGENCE

Theo Jansen

8
 86 billion 12.8 billion 2 Billion neurons

1,000,000 NEURONS

9
Robert Full
The sticky wonder of gecko feet

Spagna, Joseph C., et al. Bioinspiration & biomimetics 2007

10
BIOINSPIRED ENGINEERING
 LEVELS OF BIO INSPIRATION

Inspiration of form Inspiration of process Inspiration of system

The Eastgate Centre in
Geng, Hongya, et al. "Plant leaves inspired
sunlight-driven purifier for high-efficiency clean
Harare, Zimbabwe, inspired
water production." Nature communications 10.1
(2019): 1512.
by termite mounds

12
Fayemi, P-E., et al. "Bio-inspired design characterisation and its links with problem solving
tools." DS 77: Proceedings of the DESIGN 2014 13th International Design Conference. 2014.
BIOINSPIRED ENGINEERING

SOLUTION DRIVEN

Abbas ibn Firnas 810-887

PROBLEM DRIVEN

Kingfisher Shinkansen
13
HOW TO TRANSLATE BIOLOGY TO ENGINEERING SOLUTIONS?

Where to start? Where to focus?

14
BIO INSPIRED ENGINEERING

Understanding
the principle Conceptualization
Application
Imagination Prototyping
and
abstraction

15
Faster by the help of BIOLOGISTS
Finding a common language is a MUST

Understanding
the principle Conceptualization
Application
Imagination Prototyping
and
abstraction

1
6
FINDING A COMMON LANGUAGE, THE SUCCESS KEY FOR MULTIDISCIPLINARY
COLLABORATION

17
TRY TO FIND A
COMMON
QUESTION,
FOCUS AND
INTEREST

18
DO NOT
FORGET THE B’ B
ROLE OF
ENVIRONMENT A
C
A’ C’

19
20
SOME EXAMPLES
FROM
UNDERSTANDING BIOLOGY
TO
TRANSLATION TO ARTIFICIAL SYSTEMS

21
SOFT &
HIGHLY ADAPTABLE
CRAWLING & CLIMBING
ON
SLIPPERY SUBSTRATES

22
NOT EVERY TRAVELING WAVE CAN WORK

23
THE IMPORTANT ROLE OF LONGITUDINAL MUSCLES

Trueman, E. R. "Retrograde locomotion in
gastropods." Journal of Molluscan Studies 50.3 (1984):
235-237.

24
THE IMPORTANT ROLE OF LONGITUDINAL MUSCLES

Trueman, E. R. "Retrograde locomotion in
gastropods." Journal of Molluscan Studies 50.3 (1984):
235-237.

25
 FOAM BASED ACTUATOR

Inextensible Fabric
Soft Foam

Vacuum gate
MICROSCOPIC FLYING
OVER SUBSTRATE

26
Babu, S. P. M., Visentin, F., Sadeghi, A., Mondini, A., & Mazzolai, B. A Soft Sensorized Foot
Module to Understand Anisotropic Terrains During Soft Robot Locomotion. RA-L 2020
ACTIVITY

DESIGN A WINDOW THAT LETS AIR
CIRCULATION WHEN THE HUMIDITY IN A
ROOM IS TOO HIGH.

2
7
LET'S CHECK YOUR DESIGNS

28
Power Supply Control Unit Actuator

Position signal

Humidity
Sensor

29
WHAT A BOUT A BIO INSPIRED APPROACH?

FOR EXAMPLE, IF WE WANT TO ACTIVATE IT
WIHTOUT ELECTRICITY

30
31
 HygroScope - Centre Pompidou Paris

Achim Menges in collaboration with Steffen Reichert
Institute for Computational Design
Transsolar Climate Engineering
 PLANTS
MOVE WITHOUT
MUSCLE
THINK
WITHOUT BRAIN
&
SENSE WITHOUT
NERVOUS SYSTEM

33
Javan cucumber

34
ANY INSPIRATION?

36
MAPLE SEED MONOCOPTER FLYING ROBOT

University of Maryland

37
MAPLE SEED MONOCOPTER FLYING ROBOT

38

Cikalleshi, Kliton, et al. Science Advances 2023
TILLANDSIA:
AIR PLANTS

Raux, Pascal S., Simon Gravelle, and Jacques
Dumais. "Design of a unidirectional water valve in
Tillandsia." Nature communications11.1 (2020):
1-7.

TOWN OF SERRANO, BOLIVIA

39
PLANT ROOTS
AMAZING
SOIL
EXPLORERS

40
BIO INSPIRED ENGINEERING

Understanding
the principle Conceptualization
Application
Imagination
Prototyping
and
abstraction

41
ROOT ANATOMY
MATURE ROOT:
Stationary conditions
Lateral hairs development
Anchored to the soil

ELONGATION ZONE:
Cell elongation
Pressure up to 1 MPa
Moving in the soil

MERISTEMATIC
REGION
Cell division

ROOT CAP
Border cell sloughing
Mucilage production
42
MOVING BY GROWING

MATURE ROOT

ELONGATION ZONE

MERISTEMATIC REGION

ROOT CAP
43
MOVING BY GROWING

MATURE ROOT A1

A2
ELONGATION ZONE

A3
MERISTEMATIC
REGION
A4

An

ROOT CAP
44
SLOUGHING CELLS

Create a sleeve around the root:
Facilitate the penetration
Protect the root cells from soil pressure

Similar to molting in insects

45
Can balloon expansion and
extension simulate root growth?

46
FIRST CONCEPT

Sadeghi, Ali, et al. ICRA 2013

47
SLOUGHING MECHANISM

Sadeghi, Alì, et al. ICRA 2013

48
SLOUGHING MECHANISM (1ST PROTOTYPE)

Improving the anchorage by artificial hairs
Penetration force evaluation

1mm/s skin displacement

49

Sadeghi, Ali, et al. "Robotic mechanism for soil penetration inspired by plant root." ICRA 2013
 CHALLENGES SOLUTION
A SYSTEM THAT CAN REALY MIMIC THE
GROWTH
To soft to tolerate soil pressure.

High internal friction due to the shaft
and sleeve contact.

Unabale in bending and overcoming
obstacles.

50
EVERSION SLEEVE

51
Hawkes, Elliot W., et al. "A soft robot that navigates its environment through
growth." Science Robotics 2.8 (2017).
MIMIKING GROWTH
BY ADDITIVE
MANUFACTURING

52
GROWING FROM THE TIP: ADDITION OF NEW MATERIAL

53
Sadeghi, Ali, et al. "A novel growing device inspired by plant root soil penetration
behaviors." PloS one 9.2 (2014): e90139.
GROWING MECHANISM (2ND PROTOTYPE)

Addition of new material at the tip level

54
Sadeghi, Ali, et al. "A novel growing device inspired by plant root soil penetration
behaviors." PloS one 9.2 (2014): e90139.
EFFICIENT SOIL PENETRATION BY GROWING

No Growing

Lower Power consumption(saving
Growing
more than 70%, roughly independent
from the depth)

Faster Penetration (40% faster)

55
Sadeghi, Ali, et al. "A novel growing device inspired by plant root soil penetration
behaviors." PloS one 9.2 (2014): e90139.
BENDING BY DIFFERENTIAL
GROWTH/ELONGATION

56
3D PRINTER INTEGRATED GROWING ROBOT

Plotter

Feeder

Controller

Extruder

Sadeghi, Alì, et al. RoboSoft 2017

57
3D PRINTER INTEGRATED GROWING ROBOT

Sadeghi, Alì, et al. RoboSoft 2017

58
MOVEING BY GROWING

59
Sadeghi, Ali et al. "Toward self-growing soft robots inspired by plant roots and based on
additive manufacturing technologies." Soft robotics (2017).
INTERACTION WITH ENVIRONMENT
Temperature
Gravity

Humidity

Touch
Chemicals

60

Sadeghi, A., et al. Bioinspiration & Biomimetics 2016
PASSIVE OBSTACLE AVOIDANCE AND CRACK PROPAGATION
In loose soil In hard soil

61
INTERACTION WITH ENVIRONMENT

HYPOTHESIS:
Material is soft and
malleable when it is
deposited, so it
enables the robot to
passively adapt

62
PASSIVE ADAPTATION

63
Sadeghi, Ali, et al. "Passive morphological adaptation for obstacle avoidance in a
self-growing robot produced by additive manufacturing." Soft robotics 2020
 SOIL PENETRATION BY
GROWING IS
ENERGY EFFICIENT,
HIGHLY ADAPTIVE, AND
PROVIDES CONNECTION
TO THE GROUND SOIL
PRESSURE
&
FRICTION

64
APPLICATIONS

Providing tubular structure SMASH
Adaptable Smart Machine for Agricultural Solutions
Hightech
Controllable
Energy efficient

65
APPLICATIONS
Rescue Space Exploration

66
 STUDENT
APPLICATIONS JOB
AVAILABLE

Painless Colonoscopy Minimally-Invasive Surgery

67
 SOIL PENETRATION BY
GROWING IS
ENERGY EFFICIENT,
HIGHLY ADAPTIVE, AND
PROVIDES CONNECTION TO
THE GROUND

SOIL
PRESSURE
&
FRICTION

68
WHAT KIND OF BIOLOGICAL MODELS YOU LOOK AT
FOR
CLIMBING A POLE?

69
70
HUMAN INSPIRED
POLE CLIMBING ROBOTS

W W

Ahmadabadi, M. Nili, et al.,
CARPI, 2010

71
HUMAN INSPIRED
POLE CLIMBING ROBOT

W

Sadeghi, A., et al., Robotica, 2008 and 2012

72
THE HAPPIEST ANIMALS OF THE WORLD?

73
 74

https://www.youtube.com/watch?v=9rxf_2EgwfE
SOFT ADEHSION INSPIRED
BY SEA URCHIN
TUBE FOOT

75
 76

https://askabiologist.asu.edu/sea-urchin-anatomy
TUBE FOOT CAN
ELONGATE AND ADHER
TO WIDE RANGE OF
SURFACES

1 - Madreporite A filtered opening that allows water into the water vascular
system.
2 - Aquifer Water-filled area.
3 - Ring canal The ring canal circles the intestine and has five branches
called radial canals.

4 - Radial canal There are five radial canals that supply water to the tube
feet.
5 - Ampulla Part of the tube foot that expands when water is forced
inside and contracted by using internal muscles.

6 - Podia Suction end found at the end of each tube foot

77
D. Nichols, “The histology and activities of the tube-feet of
Echinocyamus pusillus.” Quarterly Journal of Microscopical
Science 3(52): 539-555, 1959. Suction process

78
ADHESION BY SUCTION & SECRETION

Attachment & detachment sequences

J. Smith, “The Activities of the Tube Feet of Asterias
Rubens L.” Quarterly Journal of Microscopical Science
3(1): 1-14, 1947.

Santos, Romana, et al. "Adhesion of echinoderm tube feet
to rough surfaces." Journal of Experimental Biology 208.13
(2005): 2555-2567.

79
Fluid gate
Rigid core
Hydrophobic Silicone Hydrophilic Pattern

Soft skin

Laser Cutter

Pre-streched Silicone Relaxed result

80
Sadeghi, A., et al. "Design and development of innovative adhesive suckers
inspired by the tube feet of sea urchins." BioRob 2012
ENHANCED ADHESION BY MUCUS (EDIBLE GELATIN)

Pulling force on cement

Ecoflex

Ecoflex + Mucus

Dragon Skin

Dragon Skin + Mucus

81
Sadeghi, A., et al. "Design and development of innovative adhesive suckers
inspired by the tube feet of sea urchins." BioRob 2012
ELONGATION BY WATER PRESSURE & CONTRACTION BY MUSCLES

J. Smith, “The Activities of the Tube Feet of Asterias
Rubens L.” Quarterly Journal of Microscopical
Sadeghi, A., et al., BioRob 2012
Science 3(1): 1-14, 1947.

82
Sadeghi, A., et al. "Design and development of innovative adhesive suckers
inspired by the tube feet of sea urchins." BioRob 2012
 83
Sadeghi, A., et al. "Design and development of innovative adhesive suckers
inspired by the tube feet of sea urchins." BioRob 2012
ECHINODERMS DON’T SUCK
Further tests with different setups
are required

84
Hennebert, Elise, Romana Santos, and Patrick Flammang. "Echinoderms don’t suck: evidence
against the involvement of suction in tube foot attachment." Zoosymposia 7.1 (2012): 25-32.
ROBOTIC INSPIRED BIOLOGY

85
SOFT ROBOTICS ROOTS TO STUDY COMMUNICATION AMONG ROOTS

86

Sadeghi, A., et al. Bioinspiration & Biomimetics 2016
CIRCUMNUTATION TEST

80 times
87

Del Dottore, Emanuela, et al. Bioinspiration & biomimetics 2017
 Flexibility is a key feature for adaptive interaction.
It is very easy to be lost easily in the complexity of natural systems, don’t lose your focus.
Large design data base is great help in easier translation of nature solutions to an engineering design.
Illustration skill is a most in communication and helping imagination.
Prototyping is a required step that should not be delayed to the last moments.

Understanding
the principle Conceptualization
Application
Imagination Prototyping
and
abstraction

88
Brown, Eric, et al. “PNAS 2010 The National Museum of Iran

89
TED talk Stefano Mancuso

90
 SOFT ROBOTICS
Introduction (Lecture 1)
Ali Sadeghi
Department of Biomechanical Engineering
02-05-2024
WHY SOFT COURSE PROJECT REPORT & PROJECT
ROBOTICS OVERVIEW DEFINITION EXAMINATION SELECTION
3
4
5
6
 SOFTNESS a material properties a geometrical properties

The opposite of stiffness

𝐹𝑜𝑟𝑐𝑒 (𝐹)
𝑆𝑡𝑖𝑓𝑓𝑛𝑒𝑠𝑠(𝐾) =
𝐷𝑒𝑓𝑜𝑟𝑚𝑎𝑡𝑖𝑜𝑛 (δ)

𝐷𝑒𝑓𝑜𝑟𝑚𝑎𝑡𝑖𝑜𝑛(δ)
𝑆𝑜𝑓𝑡𝑛𝑒𝑠𝑠 =
𝐹𝑜𝑟𝑐𝑒 (𝐹) a combination of both

7
 8

https://www.youtube.com/watch?v=OiMuuPdkw50
RIGID ROBOTS ARE NOT WELL PREPARED
FOR UNCERTAIN CONDITIONS AND CHALLENGING ENVIRONMENTS

9
SOUTH KOREAN
WOMAN'S HAIR 'EATEN'
BY ROBOT VACUUM
CLEANER AS SHE
SLEPT.

https://www.theguardian.com/wo
rld/2015/feb/09/south-korean-
womans-hair-eaten-by-robot-
vacuum-cleaner-as-she-slept

https://www.fox19.com/20
19/02/15/robotic-vacuum-
blame-ky-house-fire/

10
SOFT ROBOTS SAFE AND ADAPTIVE

Jiang, Hao, et al. IJRR 2021 11
SOFT ROBOTICS

… is the specific subfield of robotics dealing with Made by soft materials or
constructing robots from highly compliant materials, structures
similar to those found in living organisms.
Soft robotics draws heavily from the way in which living
Highly flexible & adaptable
organisms move and adapt to their surroundings. In
contrast to robots built from rigid materials, soft robots
allow for increased flexibility and adaptability for
accomplishing tasks, as well as improved safety when Safe
working around humans. These characteristics allow for
its potential use in the fields of medicine and
manufacturing. Bioinspired

12
ROBOTS MADE BY COMPLAINT MATERIALS & STRUCTURES

13
SAFE INTERACTION
DUE TO INTRINSIC FLEXIBILITY F

Softer is the structure smaller is the F

14
INCREASED SAFETY

15
INCREASED SAFETY: SAFE INTERACTION WITH ENVIRONMENT

https://www.colowrap.com/blog/looping_video

Manfredi, Luigi, et al. "AS oft Pneumatic Inchworm Double
balloon (SPID) for colonoscopy." Scientific reports 2019

16
SAFE INTERACTION &
REDUCED NEED OF SENSING
DUE TO THE CAPABILITY OF
ADAPTATION

Distributed stress

17
ADAPTIVE & SAFE GRASPING

Sinatra, Nina R., et al. Science Robotics 2019

Hao, Yufei, et al. 35th Chinese control conference
(CCC). IEEE, 2016.
18
ADAPTIVE GRASPING OF UNKNOW OBJECTS

Mazzolai, Barbara, et al. "Octopus‐Inspired Soft Arm with Suction Cups for Enhanced Grasping
Tasks in Confined Environments." Advanced Intelligent Systems 1.6 (2019): 1900041.
19
INCREASED DEXTERITY
AND RANGE OF MOTION
obstacle
obstacle
obstacle

obstacle

obstacle
obstacle
obstacle

20
ADAPTATION TO UNKNOWN SITUATIONS

Sadeghi, Ali, et al. “Soft-Legged Wheel-Based Robot with Terrestrial Locomotion
Abilities." Frontiers in Robotics and AI 3 (2016): 73.

21
 LIGHTNESS, COMFORT & SAFETY

Polygerinos, Panagiotis, et al. ICRA 2015.

Thalman, Carly et al. RoboSoft 2020.
Sridar, Saivimal, et al. IROS 2017.

22

Thalman, Carly M., et al. IROS 2018.
LIGHTWEIGHT GIGANTIC ROBOTS

Nate Edwards by Brigham Young University Ant-Roach by otherlab
23
BIO COMPATIBLE & BIO SIMILAR MATERIALS

Roche, Ellen T., et al. Science translational medicine 2017 24
BIO COMPATIBLE & BIO SIMILAR MATERIALS

Fras, Jan, and Kaspar Althoefer. "Soft biomimetic prosthetic hand: Design, manufacturing and
preliminary examination." IROS 2018.
NO CONVECTIONAL ASSEMBLY; EASIER TO MINIATURIZE

Kim, Jaeyoun Jay. "Soft Robotic Micro-Tentacle: A Case Study." Microscale Soft Robotics.
Springer, Cham, 2017. 39-58.

26
RESILIENCE

Tolley, Michael T., et al. "A resilient, untethered
soft robot." Soft robotics (2014) Seok, Sangok, et al. "Meshworm: a peristaltic soft robot with antagonistic nickel titanium coil
actuators." IEEE/ASME Transactions on mechatronics 18.5 (2012)

27
EDIBLE & BIODEGRADABLE SOFT ROBOTS

Shintake, Jun, et al. "Soft pneumatic gelatin Miyashita, Shuhei, et al. "Ingestible, controllable, and degradable
actuator for edible robotics." IROS 2017 origami robot for patching stomach wounds." ICRA 2016.

28
EDIBLE & BIODEGRADABLE SOFT ROBOTS

Cornell’s Collective Embodied Intelligence Lab

29
RIGID ROBOTICS SOFT ROBOTS
POWER ADAPTATION
ACCURACY SAFETY
REPEATABILITY COMFORT

Jiang, Hao, et al. IJRR 2021

30
 SOFT ROBOTICS BRINGS THE CONCEPT OF ROBOTICS AT THE LEVEL
OF MATERIAL AND STRUCTURE.
Joints
& Actuators

Links

31
SOFT ROBOTICS BRINGS THE CONCEPT OF ROBOTICS AT THE LEVEL
OF MATERIAL AND STRUCTURE.

32
33
COURSE OBJECTIVES;
DICUSS SOFT ROBOTICS STATE OF THE ART
PRACTICE THE DESIGN AND FABRICATION TECHNIQUES

LEARNING BY DOING

34
CHALLENGES
Defined number of joints, links

Defined number of actuators &
sensors

β Commercial components
α

Standard design & simulation tools

Standard control techniques
Rigid Robot
Standard fabrication techniques

35
CHALLENGES
Undefined
Defined number
numberofofjoints,
joints,links
links

Defined number of actuators &
Soft actuators & sensors
n2 sensors
n1 n∞
β NoCommercial
commercially
components
components
α

No
Standard
standard
design
design
& simulation
& simulation
tools
tool

Standard
challenging
control control
techniques
Rigid
Soft Robot
Robot
No
Standard
standard
fabrication
fabrication
techniques
technique

36
COURSE PROGRAM
Stiffness tuning
Introduction Actuation I Actuation II Sensing & accessories
Week 1 Week 2 Week 3 Week 4 Week 5

L L P L P L P L P

Bioinspiration
Soft Manufacturing & Embodied intelligence Projects Demo Exam
Week 6 Week 7 Week 8 Week 9 Week 10

L Pr L Pr Pr D E

37
You need to develop your own actuators and sensors and they can
interference the performance of each other.
Stiffness tuning
Introduction Actuation I Actuation II Sensing & accessories
Week 1 Week 2 Week 3 Week 4 Week 5

L L P L P L P L P

Bioinspiration
Soft Manufacturing & Embodied intelligence Projects Demo Exam
Week 6 Week 7 Week 8 Week 9 Week 10

L Pr L Pr Pr D E

38
Too soft cannot exert sufficient forces or even withstand its own weight.

https://www.dewivandeklomp.nl/

39
Too soft cannot exert force or even withstand its own weight.

Stiffness tuning
Introduction Actuation I Actuation II Sensing & accessories
Week 1 Week 2 Week 3 Week 4 Week 5

L L P L P L P L P

Bioinspiration
Soft Manufacturing & Embodied intelligence Projects Demo Exam
Week 6 Week 7 Week 8 Week 9 Week 10

L Pr L Pr Pr D E

40
Unconventional, bio inspired design and manufacturing

41
Unconventional, bio inspired design and manufacturing

Stiffness tuning
Introduction Actuation I Actuation II Sensing & accessories
Week 1 Week 2 Week 3 Week 4 Week 5

L L P L P L P L P

Bioinspiration
Soft Manufacturing & Embodied intelligence Projects Demo Exam
Week 6 Week 7 Week 8 Week 9 Week 10

L Pr L Pr Pr D E

42
Think to any application of soft robotics in your field of
interest or related to your hobbies.

43
What was the application?

44
WHICH SKILL FITS YOU THE
MOST?
Design & Prototyping
Modeling/Theoretical analysis
Academic writing
Familiar with Arduino or similar products
High quality imaging/rendering and illustration

45
PROJECTS
PROJECT1: CABLE DRIVEN SOFT ARM INSPIRED BY SEA URCHIN
TUBE FOOT
Stiffness tu