Robotic mowing of separated lawn areas

What is claimed is: 1. A method of mowing multiple areas, the method comprising: training an autonomous lawnmowing robot to mow the multiple areas by generating data indicative of a first boundary of a first of the multiple areas and a second boundary of a second of the multiple areas; training the robot to traverse the first of the multiple areas by generating data indicative of a user-selected route through the first of the multiple areas; transmitting the data indicative of the route and the data indicative of the first boundary and the second boundary to a mobile computing device to present a representation of the first boundary, the second boundary, and the route on a display of the mobile computing device; and initiating a mowing operation in which the robot autonomously disables a mowing function, subsequent to disabling the mowing function, travels to the second of the multiple areas by following the route without mowing the first of the multiple areas, and subsequent to traveling to the second of the multiple areas, activates the mowing function to mow the second of the multiple areas. 2. The method of claim 1 , further comprising training the robot to traverse a space by generating data indicative of a user-selected traversal route through the space, the space separating the first of the multiple areas and the second of the multiple areas, wherein, during the mowing operation, the robot travels to the second of the multiple areas by following the traversal route through the space without mowing the space. 3. The method of claim 2 , further comprising training the robot to traverse the space by generating data indicative of one or more user-selected points of the traversal route through the space. 4. The method of claim 1 , wherein: generating the data indicative of the first boundary and the second boundary comprises generating data indicative of the first boundary while the robot is manually navigated along the first boundary, and generating data indicative of the second boundary while the robot is manually navigated along the second boundary; and training the robot to traverse the first of the multiple areas comprises generating the data indicative of the route while the robot is manually navigated along the route. 5. The method of claim 1 , wherein: generating the data indicative of the first boundary and the second boundary comprises generating data indicative of the first boundary based on a user selection of the first boundary, and generating data indicative of the second boundary based on a user selection of the second boundary. 6. The method of claim 5 , further comprising wirelessly receiving, from the mobile computing device, the user selection of the first boundary and the user selection of the second boundary. 7. The method of claim 1 , wherein training the robot to mow the multiple areas comprises receiving a user selection of a movement pattern to cover the first of the multiple areas and a user selection of a movement pattern to cover the second of the multiple areas. 8. The method of claim 1 , wherein training the robot to traverse the first of the multiple areas comprises receiving data representing an automatically selected route through the first of the multiple areas before generating the data indicative of the route. 9. The method of claim 1 , further comprising wirelessly receiving, from the mobile computing device, the user selection of the route, wherein the user selection of the route overrides an automatically selected route through the first of the multiple areas. 10. The method of claim 9 , wherein: wirelessly receiving the user selection of the route comprises wirelessly receiving a plurality of user-selected points defining the route, the user-selected points including a launch point defining a start of the route and a landing point defining an end of the route, and the data indicative of the route is generated based on the received user-selected points. 11. The method of claim 10 , wherein the launch point corresponds to a location of a charging dock operable to charge a power source of the robot. 12. The method of claim 9 , wherein wirelessly receiving the user selection of the route comprises receiving a user instruction to store a current position of the robot. 13. The method of claim 1 , wherein training the robot to traverse the first of the multiple areas comprises generating the data indicative of the route through the first of the multiple areas while the robot is manually navigated along the route. 14. A method of controlling an autonomous lawnmowing robot to mow multiple areas, the method comprising: initiating a training mode in which a user navigates the robot along a first boundary of a first of the multiple areas and along a second boundary of a second of the multiple areas; transmitting, to the robot, data indicative of a user-selected route through the first of the multiple areas to train the robot to traverse the first of the multiple areas such that, during a mowing operation, the robot autonomously disables a mowing function, subsequent to disabling the mowing function, travels to the second of the multiple areas by following the route without mowing the first of the multiple areas, and subsequent to traveling to the second of the multiple areas, activates the mowing function to mow the second of the multiple areas; and presenting, on a display of a mobile computing device, a representation of the first boundary, the second boundary, and the route. 15. The method of claim 14 , further comprising wirelessly transmitting, to the robot, an instruction to initiate the mowing operation. 16. The method of claim 14 , further comprising transmitting, to the robot, data indicative of a user-selected traversal route through a space separating the first of the multiple areas and the second of the multiple areas, wherein, during the mowing operation, the robot travels to the second of the multiple areas by following the traversal route through the space without mowing the space. 17. The method of claim 14 , wherein transmitting the data indicative of the route comprises transmitting a plurality of user-selected points defining the route, wherein the user-selected points include a launch point defining a start of the route and a landing point defining an end of the route. 18. A method of controlling an autonomous lawnmowing robot to mow multiple areas, the method comprising: navigating the robot along a first boundary of a first of the multiple areas; navigating the robot along a second boundary of a second of the multiple areas to train the robot to mow the multiple areas; selecting a route through the first of the multiple areas to train the robot to traverse the first of the multiple areas; initiating presentation of a representation of the first boundary, the second boundary, and the route on a display of a mobile computing device; and initiating a mowing operation in which the robot autonomously disables a mowing function, subsequent to disabling the mowing function, travels to the second of the multiple areas by following the route without mowing the first of the multiple areas, and subsequent to traveling to the second of the multiple areas, activates the mowing function to mow the second of the multiple areas. 19. The method of claim 18 , further comprising selecting a traversal route through a space separating the first of the multiple areas and the second of the multiple areas, wherein, during the mowing operation, the robot trave