The relationship between level of engagement in a non-driving task and driver response time when taking control of an automated vehicle

Abstract. A one-dimensional model is used to investigate the relationship between land subsidence and compaction of basin sediments in response to sediment loading. Analysis of the model equations and numerical experiments demonstrate quasi-linear systems behaviour and show that rates of land subsidence due to compaction: (i) can attain a significant fraction (>40%) of the long-term sedimentation rate; (ii) are hydrodynamically delayed with respect to sediment loading. The delay is controlled by a compaction response time τc that can reach values of 10-5-107 yr for thick shale sequences. Both the behaviour of single sediment layers and multiple-layer systems are analysed. Subsequently the model is applied to the coastal area of the Netherlands to illustrate that lateral variability in compaction-derived land subsidence in sedimentary basins largely reflects the spatial variability in both sediment loading and compaction response time. Typical rates of compaction-derived subsidence predicted by the model are of the order of 0.1 mm/yr but may reach values in excess of 1 mm/yr under favourable conditions.

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How does relaxing posture influence take-over performance in an automated vehicle?

Proceedings of the Human Factors and Ergonomics Society Annual Meeting ◽

10.1177/1541931218621157 ◽

2018 ◽

Vol 62 (1) ◽

pp. 696-700 ◽

Cited By ~ 4

Author(s):

Yucheng Yang ◽

Matthias Gerlicher ◽

Klaus Bengler

Keyword(s):

Influencing Factor ◽

Control Loop ◽

Knee Angle ◽

Automated Vehicle ◽

Level 3 ◽

Driving Task ◽

Torso Angle

The driver will not have to constantly monitor the vehicle while driving in a level-3 automation or at a higher level (SAE International, 2016), which enables the driver to conduct different activities and be out of the control loop. To achieve the goals of non-driving related tasks (NDRTs) rather than the driving task better, the driver may take other sitting positions, defined as “non-driving postures (NDPs)”. Different pos-tures represent different driver motoric states. This may result in different reactions to a take-over request (TOR). In this work, relaxing NDPs are built by manipulating the driver’s knee angle (133°) and torso an-gle (38°) via seat adjustments. Their take-over performances of each posture are evaluated. The torso angle is identified as a significant influencing factor: the reclined driver takes over more poorly, whereas a larger relaxing knee angle does not affect take-over performance if the heel is able to contact the pedal.

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The Relationship between the Number of Emergency Room Patient Visits with Triage Accuracy and Emergency Nurse Response Time in the Covid 19 Pandemic Season

INFLUENCE : International Journal of Science Review ◽

10.54783/influence.v3i1.122 ◽

2021 ◽

Vol 3 (1) ◽

pp. 21-24

Author(s):

Ali Humardani ◽

Yuly Peristiowati ◽

Agusta D. Ellina

Keyword(s):

Quality Of Service ◽

Response Time ◽

Search Strategy ◽

The Other ◽

Bleeding Control ◽

Electronic Database ◽

Standard Operating ◽

The Relationship ◽

Spine Control

Handling emergency cases must not only be carried out quickly but also must be precise. Standard Operating Procedures (SOP) is one of the instruments to measure the quality of service. the number of patient visits that can affect the quality of service. Triage is a way of sorting patients based on therapy needs and available resources. Therapy is based on ABC conditions (Airway, with cervical spine control, Breathing, and Circulation with bleeding control). On the other hand, the COVID-19 pandemic greatly affects the response time, impacting the number of patient visits. Response time is the time between the beginning of a request being responded to in other words it can be called response time. A good response time for patients is 5 minutes. The purpose of this study was to identify the relationship between the number of patient visits and the accuracy of triage implementation and response time. The electronic database used is PubMed, Springer, and Google Scholar with a search strategy using the PICO (patient, intervention, comparison, and outcome) method.

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Critical values of driver response time and its impact on reducing reliability and safety in road traﬃc

Eksploatacja i Niezawodnosc - Maintenance and Reliability ◽

10.17531/ein.2017.1.20 ◽

2016 ◽

Vol 19 (1) ◽

pp. 142-148

Author(s):

Andrzej Kornacki ◽

Jacek Wawrzosek ◽

Andrzej Bochniak ◽

Andrzej Szymanek ◽

Halina Pawlak

Keyword(s):

Response Time ◽

Road Traffic ◽

Critical Values ◽

Driver Response

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Driver Response Time to Midblock Crossing Pedestrians

10.4271/2018-01-0514 ◽

2018 ◽

Cited By ~ 1

Author(s):

Ryan Toxopeus ◽

Shady Attalla ◽

Sam Kodsi ◽

Michele Oliver

Keyword(s):

Response Time ◽

Driver Response

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Ear oximetry during combined hypoxia and exercise

Journal of Applied Physiology ◽

10.1152/jappl.1986.60.2.716 ◽

1986 ◽

Vol 60 (2) ◽

pp. 716-719 ◽

Cited By ~ 40

Author(s):

R. J. Smyth ◽

A. D. D'Urzo ◽

A. S. Slutsky ◽

B. M. Galko ◽

A. S. Rebuck

Keyword(s):

Response Time ◽

Skin Pigmentation ◽

Strenuous Exercise ◽

Hewlett Packard ◽

Hp Model ◽

Arterial Blood ◽

Progressive Exercise ◽

Arterial O2 Saturation ◽

The Relationship ◽

Qualitative Changes

Ear oximetry is widely used to detect arterial O2 desaturation during exercise in patients with cardiopulmonary disease. Although oximeters have been evaluated for accuracy, response time, and the influence of skin pigmentation, tests of their reliability have not been reported during strenuous exercise. Accordingly, we compared arterial O2 saturation (Sao2) measurements obtained by Hewlett-Packard (HP, model 47201A) and Biox II oximeters with those determined directly from arterial blood in six healthy volunteers during progressive exercise while rebreathing hypoxic gas mixtures. The relationship between the HP oximeter value and blood Sao2 was described by the equation: HP = 0.93 (Sao2) + 5.37 and for the Biox II: Biox = 0.55 (Sao2) + 38.97. With these equations, at a blood Sao2 value of 90%, the underestimation by both oximeters was less than 2%. At a blood value of 70%, the HP oximeter overestimated blood Sao2 by 0.7%, whereas the Biox II showed an overestimation of 10.7%. Below blood Sao2 of 83%, the Biox II tended to overestimate blood Sao2 by an amount greater than the error of the instrument, whereas the HP estimations were within the error of the instrument over all levels of blood Sao2 studied. We conclude that the HP oximeter provides valid estimates of Sao2 during exercise but that the Biox II oximeter, although reflecting qualitative changes in oxygenation that occur during exercise, does not provide accurate records of the degree of desaturation.

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