A study on selfbalancing for a quadruped robot / En studie om självbalansering av en fyrbent robot

Knälmann, Joachim, Saläng, Marcus

January 2023

This report will cover the work involved in building a quadruped robot which should to a certain extent resemeble a four-legged mammal. The introduction will present information related to what has inspired the project, purpose/aim, specifications, limitations and research questions. Most important in the introduction are probably the purpose/aim and research questions. Mainly, the goal was to have the robot be able to self-balance and later also be able to walk to some degree if possible. The first research question concerns how well a PID controller would affect the stability of the robot and the second question is about answering if referencing a fourlegged mammal is a good idea when building a quadruped robot. Theory and methods were combined and written as one chapter. This way relevant information could be provided in the appropriate places as the method for creating the robot was described. The chapter dives into the primary parts of the robot which are the choice of components, construction, inverse kinematics and last but not least the code including the implementation of a PID. The results show that PID regulation improves stability and performance, but PI regulation actually performed the best. Furthermore, the question regarding referencing a four-legged mammal remains inconclusive even though the model was sufficient for the task.

Mechatronics

Quadruped robot

Inverse Kinematics

PID controller

Quadruped gait.

Mekatronik

Fyrbent robot

Inverterad kinematik

PID regulator

Fyrbent robot gång.

Engineering and Technology

Teknik och teknologier

Statically stable walking robot : Gait pattern generation for a quadruped using PID control

Alnasrallah, Awad, Ebbesen, Erik

January 2023

This report is a bachelor thesis in Mechatronics at KTH. The purpose of the thesis is to design a statically stable walking robot capable of forward movement. A quadrupedal robot is designed, as well as a PID control system. To easily control the legs with sufficient accuracy servo motors are used. The control system is used to generate an effective gait pattern that gives rise to the desired functionality. To achieve this the center of mass needs to be approximated, which is done through force sensitive resistors in its feet. The control systems and mathematical models used are tested with the help of a simulation in Simulink. A prototype is also built in order to test the models in practice. The results show that the robot is capable of upholding balance in the simulations, even with shifts in parameters such as the weight and the location of the center of mass. The prototype performed significantly worse, which is mainly accredited to the lack of quality among the force sensors. In future projects the use of different methods to approximate the location of the center of mass is recommended. If the use of sensors is preferred, strain gauges could be a viable alternative to the force sensitive resistors used. More expensive force sensitive resistors of a higher quality could also be an option. / Denna rapport är ett kandidatexamensarbete i Mekatronik på KTH. Syftet med rapporten är att designa en gående robot som erhåller statiskt stabilitet vid gång framåt. En fyrbent robot samt ett PID regler system designades. För att styra benen med bra noggranhet används servomotorer. Reglersystemet används för att generera en stabil bana för fötterna att följa. Detta kräver en uppskattning av robotens masscentrum som möjliggös m.h.a. tryckkänsliga motstånd i fötterna. Reglersystemet samt framtagna matematiska modeller testas med hjälp av simulering i Simulink. Sedan byggs en prototyp av roboten för att testa modellerna i verkligheten. Resultat visar att roboten kan balansera och presterar bra i simulationen, även då parametrar så som vikt och masscentrumets läge ändras. I verkligheten fungerade roboten betydligt sämre, vilket tycks vara orsakat av opålitliga kraftsensorer i fötterna. I framtida projekt föreslås användning av olika metoder för att uppskatta positionen av robotens masscentrum. Om användningen av sensorer är föredragen kan tryckkänsliga motstånd ersättas med töjningsgivare för att mäta normalkrafterna, alternativt kan tryckkänsliga motstånd av högre kvalitet användas.

PID

Quadrupedal robot

Walking

Gait

Control theory

Mechatronics

Robotics

Statically stable

Self balancing

PID

Fyrbent robot

Gåendes

Gait

Reglerteknik

Mekatronik

Robotik

Statiskt stabil

Självbalanserande

Engineering and Technology

Teknik och teknologier