Dynamic Response Characteristics in Variable Stiffness Soft Inflatable Links

Ali, Ahmed Suliman B.; Althoefer, Kaspar; Konstantinova, Jelizaveta

doi:10.1007/978-3-030-23807-0_14

Cited by 2 publications

(2 citation statements)

References 18 publications

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“…The pressure modulated optical tracking (PMOT) stiffness sensor measures elasticity by varying its internal compliance and measuring the resulting tissue and membrane deformation. The compliance of the sensor increases with pressure due to two main factors: firstly, the increase of the internal pressure causes the internal air mass to rise in line with the ideal gas equation in (2), leading to an increase in internal stiffness [33]. Secondly, the membrane increases in strain as the internal pressure grows, causing the membrane to stiffen.…”

Section: Sensing Principle and Mechanical Design A Sensing Principlementioning

confidence: 99%

Soft-Tipped Sensor With Compliance Control for Elasticity Sensing and Palpation

Raitt,

Huseynov,

Homer-Vanniasinkam

et al. 2024

IEEE Trans. Robot.

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Stiffness sensing and palpation are essential for understanding object properties, including tissue health and fruit ripeness. Currently, there is limited research on using soft-tipped sensors for stiffness sensing and dynamic palpation. To address these challenges, we investigate how the pressure modulated optical tracking (PMOT) sensor can use compliance control to quantify tissue stiffness and detect margins in samples through dynamic palpation. Results show that the PMOT sensor modulus of elasticity sensing range is from 4.20 kPa up to 177.62 kPa. Across all untrained samples, elasticity was measured with a rootmean-square error (RMSE) of 7.72%. Further, it is shown that the sensor can locate margins between 13.4 kPa and embedded 29.3 kPa materials during palpation. When mounted on a linear rail, averaged for the direction of travel, the sensor's signal-tonoise ratio (SNR) was up to 39.5:1. Participants used the sensor to locate embedded margins in a teleoperation environment with visual feedback. This was achieved with an accuracy of 96.5%.

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Section: Sensing Principle and Mechanical Design A Sensing Principlementioning

confidence: 99%

Soft-Tipped Sensor With Compliance Control for Elasticity Sensing and Palpation

Raitt,

Huseynov,

Homer-Vanniasinkam

et al. 2024

IEEE Trans. Robot.

View full text Add to dashboard Cite

show abstract

“…The stiffness of the sensor increases with pressure due to two main factors. Firstly, the increase of the internal pressure causes the internal air mass to rise in line with the ideal gas equation, leading to an increase in internal stiffness [25]. Secondly, the membrane increases in strain as the internal pressure grows, causing the membrane to stiffen.…”

Section: Sensing Principle and Mechanical Design A Sensing Principlementioning

confidence: 99%

Soft, Stiffness-Controllable Sensing Tip for On-Demand Force Range Adjustment With Angled Force Direction Identification

et al. 2022

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Force sensors are essential for measuring and controlling robot-object interactions. However, current force sensors have limited usability in applications such as grasping and palpation, where the range of angled forces changes between tasks. To address this limitation this paper proposes a novel optical-based soft-tipped force sensor capable of adjusting its range and sensitivity through pneumatic modulation. This research describes the sensor's design and examines the relationship between the internal pressure of the sensor and its sensing range, sensitivity, single-axis force-sensing accuracy, and capability of measuring the angle and magnitude of non-normal forces. Results indicate that by increasing the pressure in the sensor, the sensing range can be increased and the sensitivity decreased. These results demonstrate that the sensor can measure normal forces reliably at each pressure using 4th order fits with root-mean-square error (RMSE)∈ [0.032 N 0.110 N]. Finally, it is also demonstrated that by using a neural network, the sensor can measure the angle and magnitude of non-normal forces with RMSEs on trained variables of 0.0120 Rad for Y-angle (θ Y ) measurements, 0.0109 Rad for X-angle (θ X ) measurements, and 0.102 N for force measurements.

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Dynamic Response Characteristics in Variable Stiffness Soft Inflatable Links

Cited by 2 publications

References 18 publications

Soft-Tipped Sensor With Compliance Control for Elasticity Sensing and Palpation

Soft-Tipped Sensor With Compliance Control for Elasticity Sensing and Palpation

Soft, Stiffness-Controllable Sensing Tip for On-Demand Force Range Adjustment With Angled Force Direction Identification

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