The present disclosure relates to a method for guiding a path of an electronic device and an electronic device. The method for guiding a path according to the present disclosure includes: acquiring a top-view image; extracting guiding information in a lane from lane information extracted from the top-view image; and guiding a path of a vehicle using the extracted lane information and the guiding information in the lane. According to the present disclosure, it is possible to promote safe driving by guiding a possible traveling direction on the path to a driver in real time through image analysis of a traveling road. In addition, it is possible to provide more detailed path guidance by providing the path guidance reflecting the necessity of lane change by recognizing the lane of the driving path.

Systems and methods described herein relate to simulating edge-computing deployment in diverse terrains. One embodiment receives a layer-selection input specifying which layers among a plurality of layers in a simulation model of an edge-computing deployment are to be included in a simulation experiment; receives a set of input parameters for each of the layers specified by the layer-selection input, the set of input parameters for one of the layers specified by the layer-selection input including selection of a vehicular application whose performance in the edge-computing deployment is to be evaluated via the simulation experiment; executes the simulation experiment in accordance with the layer-selection input and the set of input parameters for each of the layers specified by the layer-selection input; and outputs, from the simulation experiment, performance data for the selected vehicular application in the edge-computing deployment.

A system comprising a computer including instructions to collect object data about each of a plurality of objects within a zone from sensors on a roadside infrastructure unit. The zone includes a road intersection. The object data includes an object type, an object location, an object speed and an object direction of travel for each object. The computer further includes instructions to determine, based on the object data, an availability level for execution of one or more paths through the road intersection by a vehicle wherein the availability level for each of the one or more paths is based on a likelihood of interference between any of the objects and the vehicle as the vehicle traverses the respective path. The computer further includes instructions to transmit an availability message to the vehicle including the availability level for each of the one or more paths.

Among other things, one or more techniques and/or systems are provided for providing users with access to a route for travelling. A user, of a client device, may send a request for access to the route to a route planning service. The route may correspond to a starting location and an ending location. The route planning service may query a route database to identify an entry indicating that a restricted access road segment (e.g., a high occupancy vehicle lane, a shoulder lane, a bus lane, etc.) and/or a road segment (e.g., comprising a traffic light alteration capability) exists between the starting location and the ending location. Responsive to successfully authorizing the user for travelling the restricted access road segment and/or the road segment, the route, comprising the restricted access road segment and/or the road segment, may be provided to the client device.

A collaborative control system for a vehicle has a cloud server, a collaboration device, and an edge computing device. The cloud server stores road coordinates and traffic data corresponding to the road coordinates. The collaboration device is for being mounted in the vehicle. The edge computing device communicates with the cloud server and the collaboration device and is for being mounted in the vehicle. The edge computing device downloads one of the traffic data from the cloud server as an instant traffic datum according to a vehicle positioning coordinate corresponding to one of the road coordinates, and transmits the instant traffic datum to the collaboration device. The collaboration device displays the instant traffic datum.

Provided is a vehicle operation system including a first operation management server and a second operation management server. The first operation management server calculates a running route to the destination, a border point, and a scheduled arrival time at which the first vehicle is to arrive at the border point, and informs the second operation management server of these. Further, the first operation management server sends an operation instruction to the first vehicle to instruct it to run from the current position to the border point. The second operation management server sends an operation signal to a second vehicle to instruct it to arrive at the border point by the informed scheduled arrival time, and then to run from the border point to the destination after the user transfers from the first vehicle to the second vehicle at the border point.

The present disclosure relates to a method for guiding a path of an electronic device and an electronic device. The method for guiding a path according to the present disclosure includes: acquiring a top-view image; extracting guiding information in a lane from lane information extracted from the top-view image; and guiding a path of a vehicle using the extracted lane information and the guiding information in the lane. According to the present disclosure, it is possible to promote safe driving by guiding a possible traveling direction on the path to a driver in real time through image analysis of a traveling road. In addition, it is possible to provide more detailed path guidance by providing the path guidance reflecting the necessity of lane change by recognizing the lane of the driving path.

An example method determines a plurality of traffic sections for a geographical traffic area, each traffic section including a road segment and vehicle(s) traveling on the road segment; monitors a responsive vehicle rate for a first traffic section of the plurality of traffic sections; and assigns, based on the responsive vehicle rate of the first traffic section, the first traffic section to one of a first section server dedicated to manage the first traffic section and a remote management server capable of managing the plurality of traffic sections of the geographical traffic area, the first section server comprising computing device(s) of responsive vehicle(s) in the first traffic section.

Systems for heads-up display of transit industry vehicle information is provided. Information originating from various transit agency systems and arriving at transit industry vehicles may be selectively displayed on a heads-up display. Control and configuration of the information displayed on a heads-up display may be determined by a transit agency and may relate to data displayed on on-board mobile data terminals.

An example integrated circuit (IC) die in a multi-die IC package, the multi-die IC package having a test access port (TAP) comprising a test data input (TDI), test data output (TDO), test clock (TCK), and test mode select (TMS), is described. The IC die includes a Joint Test Action Group (JTAG) controller having a JTAG interface that includes a TDI, a TDO, a TCK, and a TMS, a first output coupled to first routing in the multi-die IC package, a first input coupled to the first routing or to second routing in the multi-die IC package, a master return path coupled to the first input, and a wrapper circuit configured to couple the TDI of the TAP to the TDI of the JTAG controller, and selectively couple, in response to a first control signal, the TDO of the TAP to either the master return path or the TDO.