Abstract: A system computes a timing interval between high-capacity vehicles (HCVs) for each of a plurality of HCV corridors within a geographic region, each respective HCV corridor of the plurality of HCV corridors including a start area. For each respective HCV corridor, the system transmits, via a network communication interface, (i) first data to a first computing device associated with a first HCV, the first data indicating the start area of the respective HCV corridor, and a first start time for the first HCV, and (ii) second data to a second computing device associated with a second HCV, the second data indicating the start area of the respective HCV corridor and a second start time for the second HCV, wherein the first start time for the first HCV and the second start time for the second HCV are based on the computed timing interval for the respective HCV corridor.

Abstract: A network computer system operates to receive service requests from requesters. Based at least in part on a proximity between the current locations of a first and a second requester, the system can match the first service request and the second service request by (i) selecting pickup locations for the first and second requesters, (ii) transmitting rendezvous information to the computing devices of the first and second requesters, (iii) determining an estimated time interval for each of the first requester and the second requester to arrive at their pickup locations, and (iv) selecting a transport provider to service both the first transport request and the second transport request.

Abstract: A computing system computes a timing interval between high-capacity vehicles (HCVs) for each HCV corridor within a geographic region to control rates of HCVs entering and exiting each of the HCV corridors. For each of the HCV corridors, the computing system schedules a first HCV to provide a transport service along the corridor beginning at a first starting time, transmits first schedule data for the corridor to the first HCV, schedules a second HCV to provide the transport service along the corridor beginning at a second starting time after the first starting time according to the timing interval for the corridor, and transmits second schedule data for the corridor to the second HCV.

Abstract: A system computes a timing interval between high-capacity vehicles (HCVs) for each of a plurality of HCV corridors within a geographic region, each respective HCV corridor of the plurality of HCV corridors including a start area. For each respective HCV corridor, the system transmits, via a network communication interface, (i) first data to a first computing device associated with a first HCV, the first data indicating the start area of the respective HCV corridor, and a first start time for the first HCV, and (ii) second data to a second computing device associated with a second HCV, the second data indicating the start area of the respective HCV corridor and a second start time for the second HCV, wherein the first start time for the first HCV and the second start time for the second HCV are based on the computed timing interval for the respective HCV corridor.

Abstract: A computing system can integrate fleet vehicles of a fleet operator into a rideshare network to increase utilization of the fleet vehicles, optimize fleet size for fleet operators, and supplement the fleet vehicles with the rideshare network during peak periods to service the rider base of the fleet operator.

Abstract: A network computer system operates to receive service requests from requesters. Based at least in part on a proximity between the current locations of a first and a second requester, the system can match the first service request and the second service request by (i) selecting pickup locations for the first and second requesters, (ii) transmitting rendezvous information to the computing devices of the first and second requesters, (iii) determining an estimated time interval for each of the first requester and the second requester to arrive at their pickup locations, and (iv) selecting a transport provider to service both the first transport request and the second transport request.

Abstract: A computing system computes a timing interval between high-capacity vehicles (HCVs) for each HCV corridor within a geographic region to control rates of HCVs entering and exiting each of the HCV corridors. For each of the HCV corridors, the computing system schedules a first HCV to provide a transport service along the corridor beginning at a first starting time, transmits first schedule data for the corridor to the first HCV, schedules a second HCV to provide the transport service along the corridor beginning at a second starting time after the first starting time according to the timing interval for the corridor, and transmits second schedule data for the corridor to the second HCV.

Abstract: A multi-leg transport system receives a transport request and determines a number of transfer locations between the origin location and the destination. The system selects a first provider to transport the user from the origin location to a transfer location and remotely monitors the position of the user as the user travels to the transfer location. In response to determining that the travel time to the transfer location is within a threshold, the system selects a second provider to transport the user from the transfer location to either the next transfer location or the destination for the transport request.

Abstract: A multi-leg transport system receives a transport request and determines a number of transfer locations between the origin location and the destination. The system selects a first provider to transport the user from the origin location to a transfer location and remotely monitors the position of the user as the user travels to the transfer location. In response to determining that the travel time to the transfer location is within a threshold, the system selects a second provider to transport the user from the transfer location to either the next transfer location or the destination for the transport request.

Abstract: A multi-leg transport system receives a transport request and determines a number of transfer locations between the origin location and the destination. The system selects a first provider to transport the user from the origin location to a transfer location and remotely monitors the position of the user as the user travels to the transfer location. In response to determining that the travel time to the transfer location is within a threshold, the system selects a second provider to transport the user from the transfer location to either the next transfer location or the destination for the transport request.