Adaptive Hierarchical Decision Making for an Autonomous Underwater Vehicle / Adaptiv hierarkisk beslutsfattning för en autonom undervattensfarkost

Gilbert, Michael, Helsing, Albin

January 2024

In the realm of autonomous underwater exploration and surveillance, the capability of Autonomous Underwater Vehicles (AUV) to make informed decisions in dynamic and often unpredictable environments is crucial. This thesis investigates how a software architecture can be designed and implemented for autonomous decision making on the remotely operated vehicle BlueROV2. Using raw sensor data and external information inputs, situational awareness (SA) is achieved. This is used as a basis for real-time decision making during a search mission that is set up. The thesis aims for the AUV to base its actions on the SA. This is demonstrated through a search scenario in which the AUV is assigned the task of locating a number of targets in an underwater environment. To solve the task, the AUV is able to use two different methods to solve the same problem. Either by using the sonar to locate points of interest and subsequently investigate those locations or systematically traversing the entire search area using a camera to search. The trade-off between thoroughness and time consumption makes the methods favourable in different situations. Four modules are developed and implemented in the architecture. A sensor module that collects the data, an SA module that refines the data, a decision module that handles decisions in two layers and an execution module that performs the actions. A modular architecture is developed, which enables the AUV to decide which search method to prioritise and interpret the surroundings to differentiate between targets and decoy objects. Dynamic decision-making is accomplished by changing search strategies during missions and returning when all targets are found. The targets are located with a precision high enough to make out individual targets and keep track of previously seen targets. The research contributes to the field of autonomous decision making by laying a foundation for adding more sophisticated algorithms for future problem-solving. The implemented algorithms are placeholders to showcase the capabilities developed, and the architecture is modular to enable future changes and extensions of the work.

AUV

Situational Awereness

Decision Making

BlueROV2

Autonomy

Autonoma farkoster

Situationsförståelse

Beslutsfattning

Autonomi

BlueROV2

Vehicle Engineering

Farkostteknik

Robotics

Robotteknik och automation

Förståelse vid krishantering

Wedebrand, Christoffer

January 2017

Studiens syfte är tvåfaldigt. Dels är syftet att undersöka hur organisationers förståelse (i meningen deras lägesbild och situationsförståelse) och handlande tycks förhålla sig sinsemellan. Dels är syftet att undersöka hur organisatoriska skillnader tycks påverka förståelsen (återigen i meningen deras lägesbild och situationsförståelse). I båda fallen inom sammanhanget av samhällelig krishantering. Studiens forskningsfrågor besvaras genom en kombination av kvalitativa metoder. Det empiriska materialet utgörs av intervjuer med personal inom somliga av de räddningstjänster som inblandades i hanteringen av en omfattande skogsbrand på Gotland, våren 2016.

Operating picture

Operational picture

Common operating picture

Common operational picture

Situational awareness

Situation awareness

Sensemaking

Sense making

Crisis

Crisis management

Collaboration

Organization

Organisation

Karl Weick

Weick

Erna Danielsson

Lägesbild

Gemensam lägesbild

Situationsförståelse

Begripliggörande

Kris

Krishantering

Förståelse

Samverkan

Organisation

Karl Weick

Weick

Erna Danielsson