State and prospects of development of team interaction of robots on the example of competitions of the world tournament "Robocup"

Today, effective group work management is one of the main problems of mechatronics. As the development of generalized algorithms and principles of management is at an early level, the scientific community has formed several model tasks, one of which reads as follows: "By the middle of the XXI century the winner of the last world championship”. As part of the wording, the world's first RoboCup competition was launched in 1996 to promote research in the field of robot design and artificial intelligence. The main task of the article is to analyze and highlight the current state of algorithms for command control of robots on the example of the RoboCup world tournament. The article describes the general schemes of team interaction in the divisions of the tournament, the hardware characteristics of the agents, the history, chronological development and the current state of the rules of the divisions. Based on the analysis, a comparative table of basic technical parameters of RoboCup leagues and approaches used for team management is formed. The conclusion concerning the most actual directions of researches of methods of group interaction is made

Game Plan: What AI can do for Football, and What Football can do for AI

The rapid progress in artificial intelligence (AI) and machine learning has opened unprecedented analytics possibilities in various team and individual sports, including baseball, basketball, and tennis. More recently, AI techniques have been applied to football, due to a huge increase in data collection by professional teams, increased computational power, and advances in machine learning, with the goal of better addressing new scientific challenges involved in the analysis of both individual players’ and coordinated teams’ behaviors. The research challenges associated with predictive and prescriptive football analytics require new developments and progress at the intersection of statistical learning, game theory, and computer vision. In this paper, we provide an overarching perspective highlighting how the combination of these fields, in particular, forms a unique microcosm for AI research, while offering mutual benefits for professional teams, spectators, and broadcasters in the years to come. We illustrate that this duality makes football analytics a game changer of tremendous value, in terms of not only changing the game of football itself, but also in terms of what this domain can mean for the field of AI. We review the state-of-theart and exemplify the types of analysis enabled by combining the aforementioned fields, including illustrative examples of counterfactual analysis using predictive models, and the combination of game-theoretic analysis of penalty kicks with statistical learning of player attributes. We conclude by highlighting envisioned downstream impacts, including possibilities for extensions to other sports (real and virtual)

FC Portugal - High-Level Skills Within A Multi-Agent Environment

Ao longo dos anos a RoboCup, uma competição internacional de robótica e da inteligência artificia, foi palco de muitos desenvolvimentos e melhorias nestes duas áreas científicas. Esta competição tem diferentes desafios, incluindo uma liga de simulação 3D (Simulation 3D League). Anualmente, ocorre um torneio de jogos de futebol simulados entre as várias equipas participantes na Simulation 3D League, todas estas equipas deveram ser compostas por 11 robôs humanoides. Esta simulação obedece às leis da física de modo a se aproximar das circunstâncias dos jogos reais. Além disso, as regras da competição são semelhantes às regras originais do futebol com algumas alterações e adaptações. A equipa portuguesa, o FC Portugal 3D é um participante assíduo nos torneios desta liga e chegou até a ser vitoriosa várias vezes nos últimos anos, no entanto, para participar nesta competição é necessário que as equipas tenham os seus agentes capazes de executar skills (ou habilidades) de baixo nível como andar, chutar e levantar-se. O bom registo da equipa FC Portugal 3D advém do facto de os métodos utilizados para treinar os seus jogadores serem continuamente melhorados resultando em melhores habilidades. De facto, considera-se que estes comportamentos de baixo nível estão num ponto em que é possível mudar o foco das implementações para competências de alto nível que deveram ser baseadas nestas competências fundamentais de baixo nível. O futebol pode ser visto como um jogo cooperativo onde jogadores da mesma equipa têm de trabalhar em conjunto para vencer os seus adversários, consequentemente, este jogo é considerado como um bom ambiente para desenvolver, testar e aplicar implementações relativas a cooperações multi-agente. Com isto em mente, o objetivo desta dissertação é construir uma setplay multi-agente baseada nas skills de baixo nível previamente implementadas pela FC Portugal para serem usadas em situações de jogo específicas em que a intenção principal é marcar um golo. Recentemente, muitos participantes da 3D League (incluindo a equipa portuguesa) têm desenvolvido competências utilizando métodos de Deep Reinforcement Learning obtendo resultados satisfatórios num tempo razoável. A abordagem adotada neste projeto foi a de utilizar o algoritmo de Reinforcement Learning, PPO, para treinar todos os ambientes criados com o intuito de desenvolver a setplay pretendida, os resultados dos treinos estão presentes no penúltimo capítulo deste documento seguidos de sugestões para implementações futuras.Throughout the years the RoboCup, an international competition of robotics and artificial intelligence, saw many developments and improvements in these scientific fields. This competition has different types of challenges including a 3D Simulation League that has an annual tournament of simulated soccer games played between several teams each composed of 11 simulated humanoid robots. The simulation obeys the laws of physics in order to approximate the games as much as possible to real circumstances, in addition, the rules are similar to the original soccer rules with a few alterations and adaptations. The Portuguese team, FC Portugal 3D has been an assiduous participant in this league tournaments and was even victorious several times in the past years, nonetheless, to participate in this competition is necessary for teams to have their agents able to execute low-level skills such as walk, kick and get up. The good record of the FC Portugal 3D team comes from the fact that the methods used to train the robots keep being improved, resulting in better skills. As a manner of fact, it is considered that these low-level behaviors are at a point that is possible to shift the implementations' focus to high-level skills based on these fundamental low-level skills. Soccer can be seen as a cooperative game where players from the same team have to work together to beat their opponents, consequently, this game is considered to be a good environment to develop, test, and apply cooperative multi-agent implementations. With this in mind, the objective of this dissertation is to construct a multi-agent setplay based on FC Portugal's low-level skills to be used in certain game situations where the main intent is to score a goal. Recently, many 3D League participants (including the Portuguese team) have been developing skills using Deep Learning methods and obtaining successful results in a reasonable time. The approach taken on this project was to use the Reinforcement Learning algorithm PPO to train all the environments that were created to develop the intended setplay, the results of the training are present in the second-to-last chapter of this document followed by suggestions for future implementations

Game Plan: What AI can do for Football, and What Football can do for AI

The rapid progress in artificial intelligence (AI) and machine learning has opened unprecedented analytics possibilities in various team and individual sports, including baseball, basketball, and tennis. More recently, AI techniques have been applied to football, due to a huge increase in data collection by professional teams, increased computational power, and advances in machine learning, with the goal of better addressing new scientific challenges involved in the analysis of both individual players' and coordinated teams' behaviors. The research challenges associated with predictive and prescriptive football analytics require new developments and progress at the intersection of statistical learning, game theory, and computer vision. In this paper, we provide an overarching perspective highlighting how the combination of these fields, in particular, forms a unique microcosm for AI research, while offering mutual benefits for professional teams, spectators, and broadcasters in the years to come. We illustrate that this duality makes football analytics a game changer of tremendous value, in terms of not only changing the game of football itself, but also in terms of what this domain can mean for the field of AI. We review the state-of-the-art and exemplify the types of analysis enabled by combining the aforementioned fields, including illustrative examples of counterfactual analysis using predictive models, and the combination of game-theoretic analysis of penalty kicks with statistical learning of player attributes. We conclude by highlighting envisioned downstream impacts, including possibilities for extensions to other sports (real and virtual)

Scaling multi-agent reinforcement learning to eleven aside simulated robot soccer

Electrical and Electronic Engineerin

Boosting Studies of Multi-Agent Reinforcement Learning on Google Research Football Environment: the Past, Present, and Future

Even though Google Research Football (GRF) was initially benchmarked and studied as a single-agent environment in its original paper, recent years have witnessed an increasing focus on its multi-agent nature by researchers utilizing it as a testbed for Multi-Agent Reinforcement Learning (MARL). However, the absence of standardized environment settings and unified evaluation metrics for multi-agent scenarios hampers the consistent understanding of various studies. Furthermore, the challenging 5-vs-5 and 11-vs-11 full-game scenarios have received limited thorough examination due to their substantial training complexities. To address these gaps, this paper extends the original environment by not only standardizing the environment settings and benchmarking cooperative learning algorithms across different scenarios, including the most challenging full-game scenarios, but also by discussing approaches to enhance football AI from diverse perspectives and introducing related research tools. Specifically, we provide a distributed and asynchronous population-based self-play framework with diverse pre-trained policies for faster training, two football-specific analytical tools for deeper investigation, and an online leaderboard for broader evaluation. The overall expectation of this work is to advance the study of Multi-Agent Reinforcement Learning on Google Research Football environment, with the ultimate goal of benefiting real-world sports beyond virtual games

Aprendizagem automática de comportamentos para futebol robótico

Mestrado em Engenharia de Computadores e TelemáticaA soccer-playing robot must be able to carry out a set of behaviors, whose complexity can vary greatly. Manually programming a robot to accomplish those behaviors may be a difficult and time-consuming process. Automated learning techniques become interesting in this setting, because they allow the learning of behaviors based only on a very high-level description of the task to be completed, leaving the details to be figured out by the learning agent. Reinforcement Learning takes inspiration from nature and animal learning to model agents that interact with an environment, choosing actions that are more likely to lead them to accumulate rewards and avoid punishment. As agents experience the environment and the effect of their actions, they gain experience which is used to derive a policy. Agents can do this instantaneously after they observe the effect of their last action, or after collecting batches of these observations. The latter alternative, called Batch Reinforcement Learning, has been used in real world applications with very promissing results. This thesis explores the use of Batch Reinforcement Learning for learning robotic soccer behaviors, including dribbling the ball and receiving a pass. Practical experiments were undertaken with the CAMBADA simulator, as well as with the CAMBADA robots.Um robô futebolista necessita de executar comportamentos variados, desde os mais simples aos mais complexos e difíceis. Programar manualmente a execução destes comportamentos pode tornar-se uma tarefa bastante morosa e complicada. Neste contexto, os métodos de aprendizagem automática tornam-se interessantes, pois permitem a aprendizagem de comportamentos através de uma especificação a muito alto nível da tarefa a aprender, deixando a responsabilidade ao agente autónomo de lidar com os detalhes. A Aprendizagem por Reforço toma inspiração na natureza e na aprendizagem animal para modelar agentes que interagem com o seu ambiente de forma a escolherem as ações que aumentam a probabilidade de receberem recompensas e evitarem castigos. À medida que os agentes experimentam ações e observam os seus efeitos, ganham experiência e a partir dela derivam uma política. Isto é feito após cada observação do efeito de uma ação, ou após reunir conjuntos destas observações. Esta última alternativa, também chamada Aprendizagem por Reforço Batch, tem sido usada em aplicações reais com resultados promissores. Esta tese explora o uso de Aprendizagem por Reforço Batch para a aprendizagem de comportamentos para futebol robótico, tais como driblar a bola e receber um passe. Os resultados presentes neste documento foram obtidos de experiências realizadas com o simulador da equipa CAMBADA, assim como com os seus robôs

USING COEVOLUTION IN COMPLEX DOMAINS

Genetic Algorithms is a computational model inspired by Darwin's theory of evolution. It has a broad range of applications from function optimization to solving robotic control problems. Coevolution is an extension of Genetic Algorithms in which more than one population is evolved at the same time. Coevolution can be done in two ways: cooperatively, in which populations jointly try to solve an evolutionary problem, or competitively. Coevolution has been shown to be useful in solving many problems, yet its application in complex domains still needs to be demonstrated.Robotic soccer is a complex domain that has a dynamic and noisy environment. Many Reinforcement Learning techniques have been applied to the robotic soccer domain, since it is a great test bed for many machine learning methods. However, the success of Reinforcement Learning methods has been limited due to the huge state space of the domain. Evolutionary Algorithms have also been used to tackle this domain; nevertheless, their application has been limited to a small subset of the domain, and no attempt has been shown to be successful in acting on solving the whole problem.This thesis will try to answer the question of whether coevolution can be applied successfully to complex domains. Three techniques are introduced to tackle the robotic soccer problem. First, an incremental learning algorithm is used to achieve a desirable performance of some soccer tasks. Second, a hierarchical coevolution paradigm is introduced to allow coevolution to scale up in solving the problem. Third, an orchestration mechanism is utilized to manage the learning processes