An automatic alarm system for a vehicle includes a sensor adapted to detect electromagnetic data, a computer system, and an automatic alarm mechanism. The computer system receives data from the sensor. A computer processor compares the electromagnetic data detected by the sensor with known patterns of electromagnetic data emitted by emergency vehicles that are stored in a library. The automatic alarm mechanism activates in response to the processor determining that the comparison matches a known pattern of electromagnetic data for an emergency vehicle resulting in the computer processor sending a first signal to activate an alarm of the vehicle.

Systems and methods for control systems for facilitating situational awareness of a vehicle are provided. Sensors located around a stationary vehicle may detect moving objects that pose potentially dangerous situations for the vehicle occupants and for the object. This can cause the doors to lock automatically in order to make the situation safer. Additionally, electromagnetic radiation sensors located around the vehicle may detect the lights and sounds of emergency vehicles. If the electromagnetic data from the electromagnetic radiation sensors match a known pattern of electromagnetic data emitted by emergency vehicles stored in a library an alarm may be sounded through the speakers of the vehicle in order to alert the vehicle occupants of an emergency vehicle in the vicinity.

An information processing apparatus includes circuitry configured to, when to increase or decrease one or more services that can be used by a user, identify a second service that can be coordinated with a first service based on definition information defining coordination relationship settable between a plurality of services; and in response to identifying the second service, notify a service serving as coordination origin, information on a service serving as coordination destination, the service serving as the coordination origin and the service serving as the coordination destination selectable from the first service and the second service.

A method for controlling a robot to take elevator, a system for controlling a robot to take elevator, an elevator system, a robot system, and a computer-readable storage medium. The method for controlling a robot to take elevator includes receiving an elevator-taking request from a robot; acquiring current passenger information in at least one elevator car; and determining whether the elevator car meets a pre-set carrying condition according to the acquired current passenger information: if yes, instructing the robot to board the elevator car in response to the elevator-taking request; otherwise, rejecting the elevator-taking request.

A computer-implemented method is provided. The computer-implemented method is executed by a processor of a mobile device. The mobile device is in communication with an elevator system. The computer-implemented method automatically provides direct real-time travel indications with respect to an elevator trip of the elevator system. The computer-implemented method includes receiving, by the mobile device, a request for the elevator trip. The computer-implemented method includes directly receiving, by the mobile device, feedback signals from the elevator system with respect the elevator trip in response to the request. The computer-implemented method includes automatically providing, by a user interface of the mobile device, direct real-time travel indications of the elevator trip as the mobile device progresses through the elevator system.

A touchless keyboard system for operating an elevator through an existing touch-sensitive keyboard of the elevator, the touchless keyboard system including a touchless detection device comprising at least one sensor for detecting non-touch indications from users for opted floors, an actuation device comprising at least one actuator for physical engaging buttons of the existing touch-sensitive keyboard of the elevator corresponding to the opted floors, and a controller in communication with the detection device and with the actuation device for receiving and processing output signals from the at least one sensor and controlling movement of the at least one actuator based on the processed output signals. The touchless keyboard system further comprises a touchless keyboard housing for receiving the touchless detection device and the actuation device, where the touchless keyboard housing is operatively mountable to the touch-sensitive keyboard of the elevator. There is also provided a device unit, and a method of operating an elevator through an existing touch-sensitive keyboard of the elevator.

The number of bacteria present on an elevator button is almost 40 times higher than on a public toilet seat. An elevator that requires no physical contact is the answer. Just by the use of the mobile-phone, the transmission of diseases and viruses will be enormously reduced. The first part of the system is the motion sensors on the outside of the elevator, which are used to summon the elevator (up or down). The second part is an app. With the typing of desired floor number, the app generates a QR code which then scan the QR scanner inside the elevator. Lastly there is the Universal Communication Unit which translates the info taken in by the QR scanner and sends it to the operating system for the elevator to then trigger the correct response.

A destination call, as an example of an action, is automatically generated in an elevator system when detected current connection data correspond to a stored behavior pattern for the usage of the elevator system. A communicative link between a sensor in a sensor system that comprises a multitude of sensors and the mobile electronic device of a passenger is detected, and connection data about the communicative link are recorded. The connection data are compared with data stored in a memory device containing at least one behavior pattern in order to determine whether the connection data correspond to a stored behavior pattern.

Elevators and other facilities in buildings and other constructed environments can be controlled remotely. In an advanced controlling method at least one person is guided through constructed environment along a predetermined route. When the route is known facilities, such as elevators, may be called or activated in advance so that the person guided along the route does not need to do it when arriving at the area of influence of the facility. When there are more than one person travelling the routes may be combined such that the central system controlling allocations of facilities may call or activate resources more than one person.

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.