This paper proposes an autonomous mobile robot navigation system without grid maps in outdoor environments. The system integrates local navigation based on deep reinforcement learning and localization using RTK-GNSS. Local navigation is to travel between waypoints by using a learned policy. Localization is required for state of learning-based navigation and arrival evaluation of waypoints. First, a robot learns a policy traveling between waypoints in an environment that imitates an actual outdoor environment and avoiding collision with obstacles in our original simulator. DDQN(Double Deep Q-Network) is applied as an learning algorithm. We aim for learning that a robot can take an adequate action from obstacle positions obtained from 2D-LiDAR, a relative distance and a relative angle to a destination. Then, a robot performs navigation in outdoor environments based on the learned policy. Experimental results include learning in several environments, accuracy of RTK-GNSS and the integrated navigation system in an actual outdoor environment. Especially, our proposed system could travel approximately 600[m] in a general urban environments.