A method for converting a legacy building into a smart building. The method including calculating a distance between a first connection point and a second connection point; creating a cable having a first length based on the distance between the first connection point and the second connection point; installing a demarcation point; installing a plurality of systems; connecting the demarcation point and a system using the cable, to create a smart building system; connecting the smart building system to a portal; and testing the connection of the smart building system to the portal.

In one embodiment, a method includes receiving a request from a user computing device associated with a user for one or more items from an in-vehicle vending apparatus during a ride. The method also includes sending information associated with the user to start a vending session using the in-vehicle vending apparatus. The method also includes receiving an indication that the user associated with the user computer device accessed the in-vehicle vending apparatus. The method also includes determining that the user associated with the user computing device is the only user associated with the ride, determining that the user associated with the user computing device is one of a plurality of users associated with the ride, or determining that the user associated with the user computing device is associated with the in-vehicle vending apparatus.

Novel modular smart management devices in the form of drop safes include the modular components of a chassis, door and technology cabinet. The drop safes enable retailers to make cash deposits quickly and safely within or near their own facilities. Various technology, including RFID readers, RFID tags, and other equipment allow the drop safes to identify each deposited bag. Employees utilize specialized apps on their mobile devices to facilitate deposit creation and other tasks. Novel methodologies for accessing the drop safes for emptying employ single-use, time-expiration type authorization codes along with other security measures to minimize risk and to provide other benefits. Novel structures along with methodologies for replacing, on-site, modular components with auto-detection of functionality during initialization and re-initialization enables for efficient replacement and upgrading of components, including the upgrading of safes to provide additional functionality.

Various embodiments, relate to a system of lockers including a plurality of tracks and a plurality of walls. At least two of the plurality of walls slidably coupled to at least two of the plurality of tracks. Four of the plurality of walls form four sides of a locker cavity. The system also includes a plurality of doors. Each of the plurality of doors are oriented perpendicular to the plurality of the walls. A first door of the plurality of doors is coupleable to a second door of the plurality of doors so as to form a third door, and at least one of the plurality of doors form one side of the locker cavity. The system also includes a back wall, which forms one side of the locker cavity. The system further includes a lock for securing positions of the plurality of walls and of the plurality of doors.

A smart lock for securing a door comprising: a housing mountable to the door; an actuator within the housing configured to actuate a lock mechanism between a locked position and an unlocked position, the lock mechanism including a latch bolt with an angled front face, the latch bolt configured to be retractable against a biasing force provided by a biasing means such that the door is closeable when the lock mechanism is in the locked position; and a receiver within the housing configured to wirelessly receive a signal to control operation of the actuator; a sensor mountable exclusively to the door so as to generate a signal indicative of the door beginning to move; a controller arranged to receive the signal indicative of the door beginning to move, the controller configured to control the actuator to actuate the lock mechanism in response to the signal indicative of the door beginning to move.

This document discloses a storage device for theft-proof storage of valuable articles, comprising a cabinet, having at least one drawer space, a safe drawer, which is received in the drawer space, a safe housing, comprising side walls and a top wall connecting the side walls, wherein the safe drawer is slidably connected to the safe housing and wherein the safe housing is mounted to the cabinet in the drawer space, a locking member, which is movably connected to the safe drawer or to the safe housing, an actuator, which is operatively connected to the locking member, for controlling a movement of the locking member, and a controller, which is operatively connected to the actuator, and which is configured to control the actuator. The controller is configured for receiving a control signal, based on which the controller is configured to control the actuator. The locking member is movable between a first position, in which the locking member locks safe drawer relative to the cabinet, and a second position, wherein the safe drawer is unlocked relative to the cabinet.

A system for managing a transaction of an item between first and second users includes a first lock attached to the item, a storage unit having a second lock attached thereto and physically storing the item, and a processor that manages a first privilege to open the first lock and a second privilege to open the second lock. The processor performs management so that a holder of the first and second privileges is the first user. Upon receiving, from the storage unit, information indicating the second lock being opened, the processor performs management so that a first transaction is concluded in which the first user tentatively receives the item from the second user. Upon receiving, from the first lock, information indicating the first lock being opened, the processor performs management so that a second transaction is concluded in which the first user inspects the item and finally receives the item.

There is provided a method and a system for authorizing a user device to send a request to a vehicle in order to prevent a physical layer relay attack. The system comprises a vehicle comprising an acoustic transducer and an RF transceiver and a user device comprising an acoustic transducer and an RF transceiver. The method relates to a signaling scheme using a combination of acoustic and RF signals for preventing a successful physical layer relay attack.

The present disclosure provides a lock system including automated notification and surveillance integration. In the lock system of the present disclosure, when any of the locks included in the lock system are locked or unlocked, a notification or communication signal is sent to at least one other device. The at least one other device may be a receiver, smart phone, smart watch, laptop, desktop, and/or an Internet connected or Internet of Things (IoT) device. In one aspect, the at least one other device is an image capturing device that captures one or more images of the lock that has been locked or unlocked and the surrounding area the lock is disposed in responsive to the notification or communication signal sent. The lock system of the present disclosure is configured for use with electronic locks, mechanical locks, and/or hybrid electronic-mechanical locks.

A system for access control is provided. A computing device schedules a hardware service event for a hardware component, the hardware component locked in a physically locked position by a locking mechanism of a hardware lock. The computing device, at a time corresponding to the hardware service event, authorizes a service technician to access the hardware component. The computing device instructs the hardware lock to disengage the locking mechanism based, at least in part, on the authorizing of the service technician. The computing device determines that an end condition for the hardware service event has been met. The computing device terminates the hardware service event based, at least in part, on the determining that the end condition for the hardware service event has been met.