It is an essential design requirement to understand the method to represent the pressure deformation of elastomers as a crucial aspect of pneumatic actuator behavior. Most research focus on the motion of positive pressure kinematics and ignore the contribution of negative pressure to soft actuators in free space. This study presents an analytical model for soft pneumatic networks (Pneu-net) at both positive and negative pressures. The analytical model, based on finite strain membrane and hyperelastic material models, describes the relationship between pressures and volume change in the actuator’s chamber, and predicts the Pneu-net’s deformation and tip force under both positive and negative pressures. Experimental validation shows that the model can accurately predict the Pneu-net’s deformation behavior under low pressure (−20 to 20 kPa) with an error band of less than 15%. The model’s accuracy decreases beyond ±20 kPa due to material nonlinearity. This model addresses a gap in the research of Pneu-net kinematics at negative pressure, which will put forward the optimal design of Pneu-net and its potential applications in soft robotics such as soft grippers and biomimetics at both positive and negative pressure.
LiuWDuoYLiuJ, et al. Touchless interactive teaching of soft robots through flexible bimodal sensory interfaces. Nat Commun2022; 13: 5030.
2.
WangYXuQ.Design and testing of a soft parallel robot based on pneumatic artificial muscles for wrist rehabilitation. Sci Rep2021; 11: 1273.
3.
ChenXZhangSCaoK, et al. Development of a wearable upper limb rehabilitation robot based on reinforced soft pneumatic actuators. Chin J Mech Eng2022; 35: 83.
4.
PanMYuanCLiangX, et al. Soft actuators and robotic devices for rehabilitation and assistance. Adv Intell Syst2022; 4: 2100140.
5.
RogatinskyJReccoDFeichtmeierJ, et al. A multifunctional soft robot for cardiac interventions. Sci Adv2023; 9: eadi5559.
6.
XieZYuanFLiuJ, et al. Octopus-inspired sensorized soft arm for environmental interaction. Sci Robot2023; 8: eadh7852.
7.
ZhangYWangNZhaoW, et al. Development and performance analysis of pneumatic variable stiffness imitation dolphin tail actuator. J Bionic Eng2024; 21: 2271–2290.
8.
ZhangZNiXGaoW, et al. Pneumatically controlled reconfigurable bistable bionic flower for robotic gripper. Soft Robot2022; 9: 657–668.
9.
QiuJJiAZhuK, et al. A gecko-inspired robot with a flexible spine driven by shape memory alloy springs. Soft Robot2023; 10: 713–723.
10.
Lalegani DezakiMBodaghiMSerjoueiA, et al. Adaptive reversible composite-based shape memory alloy soft actuators. Sens Actuators A Phys2022; 345: 113779.
11.
WuSHongYZhaoY, et al. Caterpillar-inspired soft crawling robot with distributed programmable thermal actuation. Sci Adv2023; 9: eadf8014.
12.
TangCDuBJiangS, et al. A review on high-frequency dielectric elastomer actuators: materials, dynamics, and applications. Adv Intell Syst2024; 6: 2300047.
13.
JiangJLinCXuS, et al. Application-oriented modeling of soft actuator ionic polymer–metal composites: a review. Adv Intell Syst2024; 6: 2300568.
14.
LiJTianASunY, et al. The development of a Venus flytrap inspired soft robot driven by IPMC. J Bionic Eng2023; 20: 406–415.
15.
López-DíazADe La MorenaJBraicA, et al. Proprioception and control of a soft pneumatic actuator made of a self-healable hydrogel. Soft Robot2024; 11: 889–901.
16.
ZhangXAzizSZhuZ.Tough and fast thermoresponsive hydrogel soft actuators. Adv Mater Technol2025; 10: 2401920.
17.
SunYFengHManchesterIR, et al. Static modeling of the fiber-reinforced soft pneumatic actuators including inner compression: bending in free space, block force, and deflection upon block force. Soft Robot2022; 9: 451–472.
18.
WuJWuMChenW, et al. Multimodal soft amphibious robots using simple plastic-sheet-reinforced thin pneumatic actuators. IEEE Trans Robot2024; 40: 1874–1889.
19.
FontouraCPAguzzoliC.Development of magnetically actuated pillars with NiTi–polydimethylsiloxane integration for advanced mobility in soft robotics. Adv Eng Mater2025; 27: 2402468.
20.
Sachin WangZHiraiS. Analytical modeling of a soft Pneu-net actuator subjected to planar tip contact. IEEE Trans Robot2022; 38: 2720–2733.
21.
LiuTWangX.A novel inclined membrane contact model for analyzing the Pneu-net soft actuator lateral wall contact. Smart Mater Struct2024; 33: 035015.
22.
KokubuSVinocourPETYuW.Development and evaluation of fiber reinforced modular soft actuators and an individualized soft rehabilitation glove. Robot Auton Syst2024; 171: 104571.
23.
Tortós-VinocourPEWangYHuangSY, et al. Multiple fiber-reinforced internal chambers for thumb-assist soft pneumatic actuators. IEEE Access2025; 13: 85563–85584.
24.
ChenYLiWGongY.Static modeling and analysis of soft manipulator considering environment contact based on segmented constant curvature method. Ind Rob2021; 48: 233–246.
25.
LiuSJiaoJDingN, et al. Dynamic modeling incorporating water damping for a fiber-reinforced soft actuator based on Euler–Bernoulli and Cosserat rod theories. IEEE/ASME Trans Mechatron2025; 30: 403–413.
26.
XavierMSFlemingAJYongYK.Finite element modeling of soft fluidic actuators: Overview and recent developments. Adv Intell Syst2021; 3: 2000187.
27.
FerrentinoPRoelsEBrancartJ, et al. Finite element analysis-based soft robotic modeling: simulating a soft actuator in SOFA. IEEE Robot Autom Mag2024; 31: 97–105.
28.
ZhongGDouWZhangX, et al. Bending analysis and contact force modeling of soft pneumatic actuators with pleated structures. Int J Mech Sci2021; 193: 106150.
29.
XuQLiuJ.Effective enhanced model for a large deformable soft pneumatic actuator. Acta Mech Sin2020; 36: 245–255.
30.
LiuZWangFLiuS, et al. Modeling and analysis of soft pneumatic network bending actuators. IEEE/ASME Trans Mechatron2021; 26: 2195–2203.
31.
WangNChenBGeX, et al. Design, kinematics, and application of axially and radially expandable modular soft pneumatic actuators. J Mech Robot2021; 13: 021019.
32.
JiangQXuF.Design and motion analysis of adjustable pneumatic soft manipulator for grasping objects. IEEE Access2020; 8: 191920–191929.
33.
YangCKangRBransonDT, et al. Kinematics and statics of eccentric soft bending actuators with external payloads. Mech Mach Theory2019; 139: 526–541.
34.
WuYLuMDingL, et al. Design and motion analysis of a bidirectional parallel-chamber soft pneumatic actuator. Proc Inst Mech Eng C J Mech Eng Sci2024; 238: 4982–4998.
35.
SrivastavaAHuiCY. Large deformation contact mechanics of long rectangular membranes. I. Adhesionless contact. Proc R Soc A2013; 469: 20130424.
