Optimization of spatial and temporal configuration of a pressure sensing array to predict posture and mobility in lying
Optimization of spatial and temporal configuration of a pressure sensing array to predict posture and mobility in lying
Commercial pressure monitoring systems have been developed to assess conditions at the interface between mattress/cushions of individuals at risk of developing pressure ulcers. Recently, they have been used as a surrogate for prolonged posture and mobility monitoring. However, these systems typically consist of high-resolution sensing arrays, sampling data at more than 1 Hz. This inevitably results in large volumes of data, much of which may be redundant. Our study aimed at evaluating the optimal number of sensors and acquisition frequency that accurately predict posture and mobility during lying. A continuous pressure monitor (ForeSitePT, Xsensor, Calgary, Canada), with 5664 sensors sampling at 1 Hz, was used to assess the interface pressures of healthy volunteers who performed lying postures on two different mattresses (foam and air designs). These data were down sampled in the spatial and temporal domains. For each configuration, pressure parameters were estimated and the area under the Receiver Operating Characteristic curve (AUC) was used to determine their ability in discriminating postural change events. Convolutional Neural Network (CNN) was employed to predict static postures. There was a non-linear decline in AUC values for both spatial and temporal down sampling. Results showed a reduction of the AUC for acquisition frequencies lower than 0.3 Hz. For some parameters, e.g., pressure gradient, the lower the sensors number the higher the AUC. Posture prediction showed a similar accuracy of 63−71% and 84−87% when compared to the commercial configuration, on the foam and air mattress, respectively. This study revealed that accurate detection of posture and mobility events can be achieved with a relatively low number of sensors and sampling frequency.
convolutional neural network, high-resolution pressure sensing arrays, optimized configuration, posture and mobility, pressure ulcers, receiver operating characteristic curve
6872
Caggiari, Silvia
58f49054-6ca6-429b-b499-49b93357e5ba
Jiang, Liudi
374f2414-51f0-418f-a316-e7db0d6dc4d1
Filingeri, Davide
42502a34-e7e6-4b49-b304-ce2ae0bf7b24
Worsley, Peter
6d33aee3-ef43-468d-aef6-86d190de6756
2 August 2023
Caggiari, Silvia
58f49054-6ca6-429b-b499-49b93357e5ba
Jiang, Liudi
374f2414-51f0-418f-a316-e7db0d6dc4d1
Filingeri, Davide
42502a34-e7e6-4b49-b304-ce2ae0bf7b24
Worsley, Peter
6d33aee3-ef43-468d-aef6-86d190de6756
Caggiari, Silvia, Jiang, Liudi, Filingeri, Davide and Worsley, Peter
(2023)
Optimization of spatial and temporal configuration of a pressure sensing array to predict posture and mobility in lying.
Sensors, 23 (15), , [6872].
(doi:10.3390/s23156872).
Abstract
Commercial pressure monitoring systems have been developed to assess conditions at the interface between mattress/cushions of individuals at risk of developing pressure ulcers. Recently, they have been used as a surrogate for prolonged posture and mobility monitoring. However, these systems typically consist of high-resolution sensing arrays, sampling data at more than 1 Hz. This inevitably results in large volumes of data, much of which may be redundant. Our study aimed at evaluating the optimal number of sensors and acquisition frequency that accurately predict posture and mobility during lying. A continuous pressure monitor (ForeSitePT, Xsensor, Calgary, Canada), with 5664 sensors sampling at 1 Hz, was used to assess the interface pressures of healthy volunteers who performed lying postures on two different mattresses (foam and air designs). These data were down sampled in the spatial and temporal domains. For each configuration, pressure parameters were estimated and the area under the Receiver Operating Characteristic curve (AUC) was used to determine their ability in discriminating postural change events. Convolutional Neural Network (CNN) was employed to predict static postures. There was a non-linear decline in AUC values for both spatial and temporal down sampling. Results showed a reduction of the AUC for acquisition frequencies lower than 0.3 Hz. For some parameters, e.g., pressure gradient, the lower the sensors number the higher the AUC. Posture prediction showed a similar accuracy of 63−71% and 84−87% when compared to the commercial configuration, on the foam and air mattress, respectively. This study revealed that accurate detection of posture and mobility events can be achieved with a relatively low number of sensors and sampling frequency.
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372_Optimization of Spatial and Temporal Configuration of a Pressure Sensing Array to Predict Posture and Mobility in Lying
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Accepted/In Press date: 31 July 2023
Published date: 2 August 2023
Additional Information:
Funding Information:
This research was funded by the Engineering and Physical Sciences Research Council (EPSRC), grant number EP/W031558/1.
Publisher Copyright:
© 2023 by the authors.
Keywords:
convolutional neural network, high-resolution pressure sensing arrays, optimized configuration, posture and mobility, pressure ulcers, receiver operating characteristic curve
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Local EPrints ID: 481168
URI: http://eprints.soton.ac.uk/id/eprint/481168
ISSN: 1424-8220
PURE UUID: f9a9e17d-9102-40fe-9215-071af6356e5d
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Date deposited: 17 Aug 2023 16:39
Last modified: 18 Mar 2024 04:00
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