Predictive adaptive cruise control

The invention claimed is: 1. A method, comprising: engaging, by a cruise control system of a vehicle, in a vehicle-to-vehicle communication session with a plurality of vehicles travelling in succession; and during the vehicle-to-vehicle communication session: obtaining terrain information of an upcoming segment of road on which the plurality of vehicles are travelling; determining, by the cruise control system of the vehicle, first speed trajectory information including a predicted maximum speed trajectory of the vehicle for the upcoming segment; transmitting the first speed trajectory information including the predicted maximum speed trajectory of the vehicle to at least one vehicle of the plurality of vehicles that is ahead of the vehicle; receiving, subsequent to transmission of the first speed trajectory information, second speed trajectory information from an adjacent vehicle of the plurality of vehicles that is immediately ahead of the vehicle, wherein the second speed trajectory information is generated at least partially by the adjacent vehicle based at least partially on the first speed trajectory information; generating, by the cruise control system of the vehicle, third speed trajectory information based at least partially on the second speed trajectory information and the terrain information, the third speed trajectory information indicating predicted speeds of the vehicle during the upcoming segment; and controlling operation of the vehicle according to the third speed trajectory information during the upcoming segment. 2. The method of claim 1 , comprising: determining an operational scheme for energy efficient operation of the vehicle along the upcoming segment based at least partially on the terrain information and predicted speeds of the adjacent vehicle specified in the second speed trajectory information for positions along the upcoming segment, wherein the third speed trajectory information is generated based at least partially on the determined operational scheme. 3. The method of claim 2 , wherein the determined operational scheme is selected from a plurality of operational schemes that include a first operational scheme for navigating an incline grade, a second operational scheme for navigating a decline grade, and a third operational scheme for a decrease in speed by a fellow vehicle ahead. 4. The method of claim 1 , wherein the second speed trajectory information includes a first predicted speed trajectory of the adjacent vehicle for positions along the upcoming segment, and the third speed trajectory information includes a second predicted speed trajectory of the vehicle for the positions along the upcoming segment. 5. The method of claim 1 , wherein the at least one vehicle ahead of the vehicle is the adjacent vehicle, the method comprising: generating fourth speed trajectory information of the vehicle for the upcoming segment based at least partially on terrain information and characteristics of the vehicle; and receiving, from another vehicle of the plurality of vehicles prior to transmitting the first speed trajectory information, fifth speed trajectory information for the upcoming segment, wherein determining the first speed trajectory information includes determining, for one or more individual positions along the upcoming segment, a minimum speed among a first speed specified in the fourth speed trajectory information and a second speed specified in the fifth speed trajectory information. 6. The method of claim 1 , comprising: obtaining a measurement, by a sensor of the vehicle, that indicates a detected following distance of the vehicle to the adjacent vehicle; and determining following distance error of the vehicle to the adjacent vehicle based at least partially on a difference between a nominal platoon following distance and the detected following distance. 7. The method of claim 6 , wherein the at least one vehicle ahead of the vehicle is a lead vehicle of the plurality of vehicles, and the predicted maximum speed trajectory of the vehicle for the upcoming segment is determined based at least partially on terrain information and characteristics of the vehicle, the method comprising: transmitting, in association with the first speed trajectory information, the following distance error to the lead vehicle. 8. A system borne by a vehicle, comprising: a wireless communication interface; one or more processors; and memory coupled to the one or more processors and storing instructions that, as a result of execution by the one or more processors, cause the system to: engage in a vehicle-to-vehicle communication session with one or more cruise control systems of a plurality of vehicles including the vehicle traveling in succession; and during the communication session: obtain terrain information of an upcoming segment of road on which the plurality of vehicles are travelling; determine first speed trajectory information including a predicted maximum speed trajectory of the vehicle for the upcoming segment; transmit the first speed trajectory information including the predicted maximum speed trajectory of the vehicle to at least one vehicle of the plurality of vehicles that is ahead of the vehicle; receive, via the wireless communication interface, second speed trajectory information from an adjacent vehicle of the plurality of vehicles that is immediately ahead of the vehicle, wherein the second speed trajectory information is generated at least partially by the adjacent vehicle based at least partially on the first speed trajectory information; generate third speed trajectory information based at least partially on the second speed trajectory information and the terrain information, the third speed trajectory information indicating predicted speeds of the vehicle at positions along the upcoming segment; and control, during the upcoming segment, operation of the vehicle according to the third speed trajectory information. 9. The system of claim 8 , wherein execution of the instructions by the one or more processors further causes the system to: transmit, via the communication interface, the third speed trajectory information to another vehicle of the plurality of vehicles. 10. The system of claim 8 , wherein the second speed trajectory information indicates predicted speeds of the adjacent vehicle for positions along the upcoming segment, the third speed trajectory information indicates predicted speeds and following distances of the vehicle at the positions along the upcoming segment, and execution of the instructions by the one or more processors causes the system to control the operation of the vehicle to maintain the following distances to the adjacent vehicle. 11. The system of claim 8 , wherein execution of the instructions by the one or more processors further causes the system to: determine whether the vehicle is a lead vehicle of the plurality of vehicles or a following vehicle of the plurality of vehicles; and as a result of determining that the vehicle is the following vehicle, transmit, via the wireless communication interface, the first speed trajectory information to the adjacent vehicle, wherein the second speed trajectory information is received subsequent to transmission of the first speed trajectory information. 12. The system of claim 11 , wherein, as a result of determining that the vehicle is the following vehicle, execution of the instructions by the one or more processors further causes the system to: generate fourth speed trajectory information of the vehicle for the upcoming segment based at least partially on terrain information and characteristics of the vehicle; and receive, fro