Exemplary embodiments described in this disclosure are generally directed to systems and methods for reducing latency in a passive entry system of a vehicle. In an exemplary method, a computer detects a presence of a passive entry device inside a passive entry zone of the vehicle. The passive entry device may be a phone-as-a-key (PaaK) device or a key fob, and the passive entry zone is an area around the vehicle that is monitored by a wireless detection system of the vehicle. The computer authenticates the passive entry device, which can include determining an identity of an individual authorized to use the passive entry device. Upon successful authentication, the computer may unlock a door of the vehicle and provide a visual prompt to the individual to unlatch the unlocked door. The visual prompt can include an unlatch icon displayed upon a door access panel of the vehicle.

Disclosed is an electronic device including a communication circuit and a processor. The processor may be configured to communicate with an external electronic device based on a specified protocol, using the communication circuit, to receive first information at least including type information of the external electronic device based on the specified protocol, using the communication circuit, and to determine a positioning master for measuring a distance between the electronic device and the external electronic device based at least on the first information among the electronic device and the external electronic device. Other various embodiments as understood from the specification are also possible.

Systems, instruments, and methods for monitoring a premises, including, for example, a school, home, or other building.

An illustrated view of an exemplary key fobs for remotely opening and closing of a vehicle's window(s) and other activities is presented. The key fob is useful for allowing a driver or other person to remotely open and close a vehicle's window without having access an interior of the vehicle. Thus, the vehicle may be further secured after the driver or other person has left and locked the vehicle by closing the windows. Further, prior to entering the vehicle to start and drive the vehicle, the key fob is useful in remotely opening the window for such a condition as to reduce the temperature inside of the vehicle prior to starting the vehicle, thus reducing use of air conditioning to lower the inside vehicle temperature.

The invention relates to a digital access system (1), an electric vehicle (100) with such an access system and a method (200) for granting an access authorization to an electric vehicle with such an access system, comprising an unlocking unit (11) for positioning in the vehicle (100), at least one access unit (12) and at least one activation unit (13) for use outside the vehicle (100), wherein the activation unit (13) activates the unlocking unit (11) by means of wireless data communication (21) to the unlocking unit (11) at least for a period, the access unit (12) arranging access arranging access to the vehicle (100) from the outside by means of an independent wireless data communication (22) separate to the previous data communication (21) with the previously activated receiving unit (11), wherein the unlocking unit (11) transmits control signals (14) to the system controller (110) in response to the data communication (22) with the access unit (12) for controlling the locking system and activating at least one locking component (140) for allowing access to the vehicle to its loading.

A common premise facility system with: (i) an area of land consisting of ten acres or less; (ii) a retail facility on the area of land; (iii) a rentable storage facility comprising a plurality of shipping containers on the area of land and external from the retail facility; and (iv) wherein each shipping container in the plurality of shipping containers comprises a plurality of doors for accessing respective rentable storage units within a shipping container.

A method of contact-less access control to a device available for rental, access and use in an environment, by scanning multi-level machine-readable codes displayed in the environment using web-enabled mobile phones wirelessly connected to a wireless access control network. To practice a facility-level, site-level access and/or device-level access control method, a web-enabled mobile phone is used to scan facility-level, site-level and/or device-level machine-readable codes in the environment, and in response, rental transaction identifiers are stored within the cache on the web-enabled mobile phone scanning the machine-readable code. Each rental transaction identifier identifies the web-enabled mobile phone that is linked to a specific device rental transaction. After renting the selected device at either a facility-level, site-level or device-level location in the environment, the web-enabled mobile phone is used to scan the device-level machine-readable code on the rented device. The web-enabled mobile phone uses the rental transaction identifier stored within its cache to automatically enable access to the rented device at the selected site for use in the environment. While not required by the access methods, the user may set a passcode for entry into the system using the web-enabled mobile phone, to further constrain access to the rented device.

A GPS-tracked wireless-networked electric convenience vehicle (ECV) includes a body portion adapted for supporting the body of passenger; a GPS system for providing GPS-location services to the GPS-tracked wireless-networked ECV; a transport system with wheels and a drive mechanism, for supporting and transporting the body portion; and a wireless electronic control module being integrated with the transport system, and in wireless communication with a wireless communication infrastructure, for controlling said wheels and/or the drive mechanism. When a web-enabled mobile phone is used to (i) scan a device-level machine-readable code displayed on the GPS-tracked wireless-networked ECV, (ii) complete an ECV rental transaction over the wireless communication infrastructure, and (iii) obtain access control over the rented GPS-tracked wireless-networked ECV, then the wireless electronic control module enables the GPS-tracked wireless-networked ECV to be operated on a ground surface.

Rental property management technology, in which reservation data is accessed on a rental property management server, and a request from a mobile device for an upcoming reservation at a property is detected. In response to detecting the request, the rental property management server confirms the upcoming reservation based on the accessed reservation data. In response to confirming the upcoming reservation, the reservation management server generates a unique access code. The rental property management server transmits the unique access code to the mobile device and to a monitoring system on the property. The rental property management server also transmits data to the monitoring system indicating that the unique access code grants access to the property.

Novel security clearance delivery assistance system for healthcare providers working in hospitals nationwide that improves patient care by reducing or eliminating the amount of time needlessly wasted by manually presenting security clearance smart cards to the security reader for authentication while transporting patients across hospitals. In life or death situations, which occur routinely in hospitals, quick delivery of patients to destinations such as the operating room could mean life or death. A health care professional's ability to save lives may depend in part on their ability to quickly transport patients through secured areas, which currently require the transporter to stop and authenticate at each doorway. With the likelihood of survival decreasing exponentially as time passes, reducing or eliminating interruptions during transportation will enable healthcare providers more time to perform life saving procedures and dramatically increase the likelihood of survival.