A quick release mounting system that utilizes two opposing plate assemblies configured for attachment. The two opposing plate assemblies are configured for attachment by a pair of spaced apart posts positioned in a male plate assembly connecting to a female plate assembly. The pair of spaced apart posts has an actuator mechanism positioned within the posts, and a series of ball bearing around a circumference of the posts. In a preferred embodiment the actuation mechanism is configured to bias the ball bearing out from the circumference of each of the posts, with the actuation mechanism configured to release the outer bias on the ball bearings. Alternatively, the actuation mechanism can be configured such that the actuation mechanism biases the ball bearings out when the mechanism is actuated by a user. The actuation mechanism can utilize a mechanical actuator, such as a rotary or linear actuator, or an electro-mechanical actuator, which utilizes a mechanical actuator that is actuated by an electrical device, such as a solenoid.

A vehicle system having a driving module, at least one mission module and at least one container. The driving module has a receptacle which can receive at least one aforementioned mission module. As a result of the receiving possibility, various mission modules can be received, depending on requirement. Thus, the mission is built up modularly in the same driving module. The container is configured to be box-shaped and closed on all sides by walls, with the exception of the top. Furthermore, the mission module is configured to be open on all sides, with the exception of the top, and the top of the mission module is designed to be closed by a wall. As a result, a modular mission module is produced, which can optionally be received in a container or in the receptacle in the driving module.

A vehicle system having a driving module, at least one mission module and at least one container. The driving module has a receptacle which can receive at least one aforementioned mission module. As a result of the receiving possibility, various mission modules can be received, depending on requirement. Thus, the mission is built up modularly in the same driving module. The container is configured to be box-shaped and closed on all sides by walls, with the exception of the top. Furthermore, the mission module is configured to be open on all sides, with the exception of the top, and the top of the mission module is designed to be closed by a wall. As a result, a modular mission module is produced, which can optionally be received in a container or in the receptacle in the driving module.

Methods and apparatus are disclosed to facilitate equipment status verification in a storage device. An example vehicle comprises: an equipment rack, a processor and memory, and a display. The equipment rack includes sensors to generate presence and securement information. The processor and memory are in communication with the sensors and are configured to: determine a presence status of an object assigned to the equipment rack, determine a securement status of the object in the equipment rack, and display a report of the presence and securement statuses via the display.

Methods and apparatus are disclosed to facilitate equipment status verification in a storage device. An example vehicle comprises: an equipment rack, a processor and memory, and a display. The equipment rack includes sensors to generate presence and securement information. The processor and memory are in communication with the sensors and are configured to: determine a presence status of an object assigned to the equipment rack, determine a securement status of the object in the equipment rack, and display a report of the presence and securement statuses via the display.

A quick release mounting system that utilizes two opposing plate assemblies configured for attachment. The two opposing plate assemblies are configured for attachment by a pair of spaced apart posts positioned in a male plate assembly connecting to a female plate assembly. The pair of spaced apart posts has an actuator mechanism positioned within the posts, and a series of ball bearing around a circumference of the posts. In a preferred embodiment the actuation mechanism is configured to bias the ball bearing out from the circumference of each of the posts, with the actuation mechanism configured to release the outer bias on the ball bearings. Alternatively, the actuation mechanism can be configured such that the actuation mechanism biases the ball bearings out when the mechanism is actuated by a user. The actuation mechanism can utilize a mechanical actuator, such as a rotary or linear actuator, or an electro-mechanical actuator, which utilizes a mechanical actuator that is actuated by an electrical device, such as a solenoid.

Method and apparatus are disclosed for secure access to storage devices within vehicle cargo compartments. An example vehicle includes a rear gate including a gate lock, a cargo compartment accessible via the rear gate, a storage device positioned within the cargo compartment and including a storage lock, and a body control module (BCM) communicatively coupled to the gate lock and the storage lock. The BCM is to simultaneously unlock the rear gate and the storage device for a predefined period-of-time responsive to receiving a storage-access request.

Representative implementations of devices and techniques provide a seat attachment assembly to receive and to support an implement (such as a handgun, for example) or an implement holster (such as a handgun holster, for example), in a variety of configurations. The seat attachment assembly includes a planar seat attachment unit arranged to be mounted in various locations using one or more straps threaded through a portion of the seat attachment unit, for temporarily and safely stowing the implement, while making the implement easily accessible to the user.

Methods and apparatus are disclosed to facilitate equipment status verification in a storage device. An example vehicle comprises: an equipment rack, a processor and memory, and a display. The equipment rack includes sensors to generate presence and securement information. The processor and memory are in communication with the sensors and are configured to: determine a presence status of an object assigned to the equipment rack, determine a securement status of the object in the equipment rack, and display a report of the presence and securement statuses via the display.

Methods and apparatus are disclosed to facilitate equipment status verification in a storage device. An example vehicle comprises: an equipment rack, a processor and memory, and a display. The equipment rack includes sensors to generate presence and securement information. The processor and memory are in communication with the sensors and are configured to: determine a presence status of an object assigned to the equipment rack, determine a securement status of the object in the equipment rack, and display a report of the presence and securement statuses via the display.