In an elevator installation, an elevator control system is configured to receive an elevator call from a person via a call terminal and from a robot via a radio transceiver. A current transport capacity of the elevator installation is determined. An elevator call originating from the robot is recognized by the elevator control system, the call including a priority level set by a dispatcher, wherein the priority level is one of a high, a medium and a low priority range, wherein the elevator call is indicative of a boarding floor. The allocation of the elevator call originating from the robot to the elevator car is delayed if the priority level is set to the medium priority range and the current transport capacity is lower than a first threshold value, or if the priority level is set to the low priority range and the current transport capacity is lower than a second threshold value.

The invention refers to an elevator system having a plurality of elevator cars, which elevator cars comprise several first cars and at least one second car, which second car differs from the first cars in its size and/or technical configuration, whereby the first cars and the second car run together within one and the same elevator shaft, which elevator system comprises an elevator control comprising a call allocation control having a first part connected to at least one call input device for allocating the first elevator cars and a second part connected to at least one call issuing means for the call allocation of the second car, whereby the first and second part of the call allocation control are configured to work independently of each other.

A method and system for providing destination dispatch in an elevator control system, includes identifying a user, retrieving a user profile associated with the user, receiving a destination request associated with the user, analyzing the user profile and the destination request, determining a plurality of assignments, identifying a preferred assignment of the plurality of assignments, and prompting the user to opt-out of the preferred assignment.

A method of taking an elevator by an unmanned device is provided including: through a remote communication connection established with a cloud platform, sending a start floor elevator call request to the cloud platform; receiving real-time running information of at least one elevator returned by the cloud platform; selecting a target elevator according to the real-time running information of the at least one elevator, and entering the target elevator; and establishing a communication connection with an elevator controlling communication device of the target elevator, and sending a target floor elevator call request to an elevator controlling device of the target elevator through the communication connection such that the elevator controlling device controls the target elevator to run to a target floor based on the target floor elevator call request, where the elevator controlling communication device of the target elevator is connected with the elevator controlling device of the target elevator. Further, an elevator controlling method, an elevator scheduling method, an unmanned device, an elevator controlling device, an elevator scheduling cloud platform and a system for taking an elevator by an unmanned device are provided.

A method for generating a control signal to a conveyor system, the conveyor system configured to serve at least a plurality of robots, includes receiving, in a control entity, a service call for a first robot, the service call being associated with a priority of the first robot; determining, by the control entity, the priority of the first robot; and generating, by the control entity, a control signal to the conveyor system to serve the service call for the first robot in accordance with the determined priority of the first robot. A control entity, a robot and a system are also provided.

An elevator calling operation based on a wrist-wearable smart device. An elevator calling operation system of the present invention comprises: an elevator control apparatus, and a wrist-wearable smart device wirelessly connected to the elevator control apparatus, wherein the wrist-wearable smart device comprises an identity identification module which stores identity identification information about a passenger, and a motion sensor which is used for acquiring elevator calling motion information about the passenger performing an elevator calling operation, and the wrist-wearable smart device transmits the elevator calling motion information, in association with the identity identification information, to the elevator control apparatus; and the elevator control apparatus comprises: a passenger identity recognition module and an elevator calling operation recognition module, the elevator calling operation recognition module used for recognizing the elevator calling operation of the passenger according to the elevator calling motion information from the motion sensor.

According to one embodiment, an autonomous mobile robot includes a communication device, a memory, and a hardware processor connected to the communication device and the memory. The communication device receives list information indicating ride conditions of a car from the elevator control system when transmitting a car call message to an elevator control system on a hall of any floor. The hardware processor includes a ride determination unit and a movement control unit. The ride determination unit determines whether the robot is able to ride in the car or not, based on the list information when the car arrives. The movement control unit allows the robot to ride in the car and move to a destination floor when the robot is able to ride.

The invention relates to a method for the processing of call inputs of a user by an elevator controller of an elevator installation in which a user inputs either an external call and an internal call or a destination call into the elevator controller, wherein the elevator controller generates at least two sub-calls in reaction to the internal call or the destination call, wherein the sub-calls comprise at least one external call and/or at least one internal call whose destination floor is different from the destination floor of the internal call input by the user. The invention furthermore relates to a method in which an elevator controller generates a destination call or an internal call in reaction to an external call. The invention furthermore relates to corresponding elevator installations designed for carrying out these methods.

An elevator scheduling method and an apparatus, a server, and a computer-readable storage medium are provided. The elevator scheduling method is applied to a server, and comprises: determining an elevator schedule request, wherein the elevator schedule request comprises starting floor information and target floor information; determining a target elevator to be scheduled to a target robot based on the elevator schedule request and operation information of schedulable elevators; generating a control instruction based on the starting floor information, the target floor information, and identification information of the target elevator; and sending the control instruction to an elevator control device, wherein the elevator control device controls movement of the target elevator.

According to an aspect, a method includes receiving a passenger request to reserve an elevator car of an elevator system to travel to a targeted destination. At least two different travel options to the targeted destination are determined based on a plurality of elevator car travel plans comprising at least two elevator cars having different travel ranges. The at least two different travel options are output to an interactive display. At least one of the at least two elevator cars is reserved responsive to a user selection of one of the at least two different travel options.