It is inevitable that the robots will move from the structured and controlled environments, such as industry and laboratories, into our daily lives. To achieve the integration of robots into our daily lives, we have to solve two fundamental problems related to these tasks. (1) Each individual robot user has a different environment, needs, tasks and tools. This demands acquisition of a vast amount of very specific skills, thus the transfer of the skill from the user to the robot must be intuitive, adaptable and fast. (2) Many daily tasks require us to deal with physical interaction with unpredictable and unstructured environment. Because of this, the acquisition of models is very complex and makes the classical robot control difficult. To make robots successfully operate in such environment, it is necessary to find alternative ways to teach the robot how do deal with such interactions. In the first part of the first chapter, there is an introduction into the research field with an overview of the state-of-the-art. The second part explains the goals of the thesis. The last part contains an overview of the performed experiments. The second chapter presents the human-in-the-loop teaching method. The method is based on human sensorimotor learning ability that allows the demonstrator to first obtain the skill necessary for controlling the robot and then transfer that skill to the robot. This is followed by a presentation of methods to encode the control strategy (skill). These methods include: sensorimotor pairs, trajectory of motion and adaptive oscillators for describing the state of periodic motion. In the last part of this chapter, we present two machine learning methods that were utilised in our methods (Gaussian Process Regression and Locally Weighted Regression). The third chapter presents the proposed method for teaching humanoid robots how to deal with physical interaction of its body with human and environment. To this end, a method for converting robot sensory information into a human sensory stimulation was developed to give the demonstrator the necessary feedback about the robot body dynamics during the teaching process. In this scope, we developed a special haptic interface that exerted forces on the demonstrator's body. After that, we present a method for on-line robot learning where the control of the robot body is shared between the currently learnt strategy and human demonstrator. This enables a gradual transfer of the control responsibility from the demonstrator to the robot and offers an additional feedback about the state of the learning. In the last part, we propose a method that allows merging human-demonstrated posture-control skill with arm motion control based on inverse kinematics solution. The fourth chapter presents the proposed methods for teaching robot how to manipulate with unstructured and unpredictable environment. These methods were based on the ability of demonstrator to modulate and teach the impedance of robotic arm. We developed methods that allow the demonstrator to control the robot's stiffness in real-time. This approach was then used to solve tasks related to use of elementary tools, human-robot cooperation and part assembly. These tasks are crucial for future robot operation in human daily lives or in their participation in space exploration, where the available means are limited. The fifth chapter presents a method for exoskeleton control. These devices are made to enclose the human body parts and directly assist the motion in the joints. In the framework of integration of robots into the human daily lives, exoskeletons are a complement to the humanoid robots that are designed to provide assistance on a more indirect level. The proposed control method is based on minimisation of human muscle activity through adaptive learning of robot assistive joint torques. The main advantage of this method is that it does not require models of human and robot. Necessary compensation torques are adaptively derived according to the current conditions. The method was validated on multiple subjects and we analysed the human-robot co-adaptation. The last chapter recapitulates the main contributions of the dissertation and presents its conclusions.