Tesi etd-10252024-163219 |
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Tipo di tesi
Tesi di laurea magistrale
Autore
PINIZZOTTO, ANNAMARIA
URN
etd-10252024-163219
Titolo
Hybrid force-position control during echographic vascular screening and implementation of a novel image-based sensing strategy for contact force estimation
Dipartimento
INGEGNERIA DELL'INFORMAZIONE
Corso di studi
INGEGNERIA ROBOTICA E DELL'AUTOMAZIONE
Relatori
relatore Prof. Bianchi, Matteo
Parole chiave
- echographic
- force estimation
- hybrid force-position control
- image-based
- ultrasound
Data inizio appello
03/12/2024
Consultabilità
Non consultabile
Data di rilascio
03/12/2094
Riassunto
Ultrasound imaging is a widely used diagnostic tool due to its safety, cost-effectiveness,
and non-invasive nature. However, challenges such as the aging population, limited
access to medical professionals, and the dependence on operator expertise significantly
influence the quality and accessibility of diagnostic services. To address these
issues, robotic ultrasound systems have been developed to provide autonomous,
precise control of the ultrasound probe, improving image consistency while reducing
the physical strain on sonographers. This thesis investigates force control in robotic
ultrasound applications, with the aim of enhancing image quality by optimizing
probe-tissue acoustic coupling. The study utilizes a six-degree-of-freedom Doosan
robotic arm equipped with a linear ultrasound probe mounted on a custom support.
The research explores two approaches: the implementation of a hybrid force-position
control system and the development of an innovative force estimation method based
on ultrasound data. Experimental results demonstrate that external pressure sensors
outperform internal robotic sensors in maintaining consistent force during scanning
procedures. This ensures improved acoustic coupling, reduces oscillations, and enhances
the diagnostic quality of ultrasound images. To mitigate the visual occlusions
caused by external sensors, the thesis introduces a novel method to estimate contact
force directly from raw RF ultrasound data. This technique uses phase values to
accurately estimate the applied force, achieving an error margin below one Newton,
while preserving image clarity. The findings emphasize the critical role of precise
force control in robotic ultrasound systems to ensure patient safety, improve image
quality, and reduce artifacts. However, further calibration is required for nonlinear
and organic tissues, which exhibit material-dependent behaviors under compression.
This research lays the groundwork for future advancements like real-time feedback
systems for probe alignment, and machine learning-based force estimation methods.
These innovations have the potential to enable fully autonomous robotic ultrasound
systems, offering reliable, high-quality diagnostics in complex clinical settings.
and non-invasive nature. However, challenges such as the aging population, limited
access to medical professionals, and the dependence on operator expertise significantly
influence the quality and accessibility of diagnostic services. To address these
issues, robotic ultrasound systems have been developed to provide autonomous,
precise control of the ultrasound probe, improving image consistency while reducing
the physical strain on sonographers. This thesis investigates force control in robotic
ultrasound applications, with the aim of enhancing image quality by optimizing
probe-tissue acoustic coupling. The study utilizes a six-degree-of-freedom Doosan
robotic arm equipped with a linear ultrasound probe mounted on a custom support.
The research explores two approaches: the implementation of a hybrid force-position
control system and the development of an innovative force estimation method based
on ultrasound data. Experimental results demonstrate that external pressure sensors
outperform internal robotic sensors in maintaining consistent force during scanning
procedures. This ensures improved acoustic coupling, reduces oscillations, and enhances
the diagnostic quality of ultrasound images. To mitigate the visual occlusions
caused by external sensors, the thesis introduces a novel method to estimate contact
force directly from raw RF ultrasound data. This technique uses phase values to
accurately estimate the applied force, achieving an error margin below one Newton,
while preserving image clarity. The findings emphasize the critical role of precise
force control in robotic ultrasound systems to ensure patient safety, improve image
quality, and reduce artifacts. However, further calibration is required for nonlinear
and organic tissues, which exhibit material-dependent behaviors under compression.
This research lays the groundwork for future advancements like real-time feedback
systems for probe alignment, and machine learning-based force estimation methods.
These innovations have the potential to enable fully autonomous robotic ultrasound
systems, offering reliable, high-quality diagnostics in complex clinical settings.
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