To make it possible to comprehensively predict the movement of people by associating an elevator control system in a facility such as a building and an external system other than this system with each other and thereby provide a new service that has not existed before. There is provided an elevator operation management system for controlling and managing multiple elevator devices in a facility, the system including: a reception unit that acquires information on the number of users to use the elevator devices and elevator car destination information; a learning unit that stores and learns, as past experience data, the information on the number of users and the elevator car destination information acquired from the reception unit; a per-floor number-of-people estimation unit that estimates the number of users getting off at each elevator hall floor using storage information of the learning unit; and a request information output unit that outputs the number of people getting off thus estimated in the facility to a system other than the elevator operation management system.

An information processing apparatus includes a controller configured to predict a state of congestion of an elevator installed in a building and generate, based on the predicted state of congestion, a proposal message to propose a departure time for the building to a user planning to travel to the building.

An elevator system configured to determine and transmit an estimated elevator boarding time to a mobile call input device, wherein the boarding time includes the arrival time of the elevator car based on a registered target floor registration information and the duration of time to place the elevator car door and the hoistway door in a fully open state.

A method of controlling an elevator installation with several elevator cages per elevator shaft, wherein a destination call to a desired destination story is actuated on a call input story by at least one passenger and at least one most favorable call allocation for transport of the passenger by the elevator cage from a start story to a destination story, is determined for the destination call by at least one destination call control. If at least one disadvantage parameter is set, at least one disadvantage-free call allocation for transport of the passenger by the elevator cage from a start story to a destination story is determined by the destination call control, in which it is possible the start story and call input story or the destination story and desired destination correspond.

A method and an apparatus for computing allocation decisions in an elevator system is provided. Historical passenger batch journey data relating to the elevator system is obtained, wherein each passenger batch journey includes an origin and a destination floor of the journey, the number of passengers of the journey and the time of the journey. Historical passenger traffic statistics are constructed based on the passenger batch journey data, and expected calls are modelled based on the passenger traffic statistics. The modelled expected call is taken into account in computing subsequent allocation decisions in the elevator system.

A method for elevator call allocations in an elevator group of an elevator system includes applying statistical traffic forecasts modelling future passenger arrivals in the elevator system; receiving an indication of at least one elevator call; generating, for a fixed parameter, a set of scenarios based on the statistical traffic forecasts; determining a quality attribute for each candidate allocation policy of a set of candidate allocation policies by simulating, for each candidate allocation policy, the set of scenarios according to the candidate allocation policy in a current elevator call allocation situation in the elevator system; selecting a candidate allocation policy based on the quality attributes associated with the candidate allocation policies; and allocating the at least one elevator call to at least one elevator in the elevator group according to the selected candidate allocation policy.

An elevator control method, apparatus, and system, and an electronic device. The elevator control method includes: receiving a notification message, the notification message carrying a target moment, and the target moment being a moment at which an elevator door opens, or being a preset moment before the elevator door opens; performing a preset operation for instructing a driverless smart device to enter/exit an elevator in a case of determining, based on the target moment carried by the notification message, that a preset condition is met; and instructing an elevator control device to call the elevator in a case of determining, based on the target moment carried by the notification message, that the preset condition is not met.

A method for operating an elevator installation includes receiving a destination call of a passenger at a control unit and selecting an elevator car from a set of available elevator cars for transporting the passenger. The elevator car is selected such that elevator car spacing rules are observed. The method further includes determining an arrival time of the selected elevator car at the boarding floor, and determining a first arrival time of the passenger at an elevator landing corresponding to the selected elevator car on the boarding floor. The method includes directing, under the proviso that the first arrival time of the passenger at the elevator landing precedes the arrival time of the selected elevator car by a defined margin, the passenger to a waiting zone of a set of available waiting zones. The waiting zone is selected such that waiting zone spacing rules are observed.

To make it possible to comprehensively predict the movement of people by associating an elevator control system in a facility such as a building and an external system other than this system with each other and thereby provide a new service that has not existed before. There is provided an elevator operation management system for controlling and managing multiple elevator devices in a facility, the system including: a reception unit that acquires information on the number of users to use the elevator devices and elevator car destination information; a learning unit that stores and learns, as past experience data, the information on the number of users and the elevator car destination information acquired from the reception unit; a per-floor number-of-people estimation unit that estimates the number of users getting off at each elevator hall floor using storage information of the learning unit; and a request information output unit that outputs the number of people getting off thus estimated in the facility to a system other than the elevator operation management system.

An passenger conveyance system includes a depth-sensing sensor within a passenger conveyance enclosure for capturing depth map data of objects within a field of view that includes a passenger conveyance door. A processing module is in communication with the depth-sensing sensor to receive the depth map data, the processing module uses the depth map data to track an object and calculate passenger data associated with the tracked object. a passenger conveyance controller receives the passenger data from the processing module to control operation of a passenger conveyance door in response to the passenger data.