The invention relates to an elevator comprising an electric linear motor comprising at least one linear stator designed to be located in a fixed correlation to an environment, particularly building, and at least one mover designed for connection with an elevator car to be moved and co-acting with the stator to move the car, which motor comprises a stator beam supporting said at least one stator, which stator beam has at least one side face carrying ferromagnetic poles of said stator spaced apart by a pitch, and which mover comprises at least one counter-face facing said side face(s) of the stator beam, in which counter-face electro-magnetic components of the mover are arranged to co-act with the ferromagnetic poles mounted on the stator beam, which elevator comprises an elevator brake. According to the invention the side face of the stator beam facing the mover and/or the counter face of the mover facing the side face of the stator beam comprise(s) a brake surface which form(s) the brake interface of the elevator brake.

An elevator interface, communication, and control system including: a first elevator car configured to move through a first elevator shaft, the first elevator car including elevator doors configured to open and close; a first controller in electronic communication with the first elevator car; a conversion module in electronic communication with the first controller; and a first wireless access point in electronic communication with the conversion module through a hardwired connection, the first wireless access point being configured to wirelessly receive a first command from a first mobile computing device via a wireless protocol, wherein the first wireless access point is configured to transmit the first command to the conversion module, the conversion module is configured to transmit the first command to the first controller, and the first controller is configured to transmit the first command to the first elevator car.

An elevator system is provided in which an elevator car is movable in an elevator shaft between two adjacent floors of a building using a traction sheave drive, wherein an elevator control unit for moving the elevator car from one of the floors to the other of the floors controls the traction sheave drive by means of a control signal using a value for the traction sheave diameter, the elevator controller being further designed to control after an initial configuration of the elevator system with an iterative adaptation of the value for the traction sheave diameter used to determine the control signal in order to increase the landing accuracy of the elevator car.

Lift systems may include a first shaft unit and a second shaft unit, each of which may include a number of lift shafts. One or more single-car systems and/or multi-car systems may be disposed in the first shaft unit, whereas one or more shaft-changing multi-car systems may be disposed in the second shaft unit. A transporting operation may be carried out from an initial floor to a destination floor wherein a control unit determines whether to utilize one or more cars from the single car systems, the multi-car systems, the shaft-changing multi-car systems, or some combination thereof depending on factors such as the destination floors of the passengers, traffic density, energy demand, and/or availability of cars.

A method for training neural networks to assign calls to elevator cars simulates an environment in which first and second cars move between building floors in reaction to calls indicating desired floors, each simulation including steps: determining a current state of the environment including a current position of each car, a list of current calls and a new call; inputting first and second input data encoding at least a part of the current state into respective first and second neural networks each configured to convert the input data into output values indicating a probability and/or tendency for the cars to be assigned to the new call; determining a selected car using the output values; assigning the new call to the selected car, and determining reward values quantifying a usefulness of the assignment; training the neural networks using past simulation reward values to increase the usefulness of future assignments.

An elevator has a plurality of cars movable along different vertical axes between building floors and a sensor system providing sensor data indicative of the elevator current state. An elevator control method includes: receiving the sensor data including current position of each car relative to the floors, list of assigned current calls and a new call for assignment each indicating a destination floor; generating a list of eligible cars using the sensor data and at least one rule with which each car should comply when fulfilling the new call; inputting the sensor data as input data into an artificial neural network trained to convert the input data into one output value for each car indicating a probability and/or tendency for assignment of the car to the new call; determining one of the eligible cars as a selected car using the output values; assigning the new call to the selected car.

A modular elevator system has a pit module, one or more shaft modules that are attachable to the pit module and/or to an adjacent shaft module, and a cap module that is attachable to an uppermost shaft module. The pit module, the shaft modules, and the cap module are each pre-fabricated and transported to a site at which a building is under construction for assembly top of the pit module, the remaining shaft modules are secured sequentially on top of each other, and the cap module is secured on top of the uppermost shaft module.

An elevator communication system includes a first elevator controller, a second elevator controller communicatively connected to the first elevator controller, a first ethernet bus portion connected to the first elevator controller, a second ethernet bus portion connected to the second elevator controller, and at least one elevator system node communicatively connected to the first elevator controller via the first ethernet bus portion and to the second elevator controller via the second ethernet bus portion.