Surrogates for roadside objects, such as concrete dividers, can be used for vehicle testing. A surrogate for a concrete divider can have substantially the same size and/or shape as the concrete divider that the surrogate is mimicking. The surrogate can be configured to exhibit substantially the same characteristics as their actual counterpart concrete divider when sensed by one or more vehicle sensors (e.g., cameras, radar sensors, and/or LIDAR sensors). Such surrogates can be used to test autonomous vehicles, one or more vehicle sensors, a vehicle sensor system, and/or one or more vehicle system (e.g., a road departure mitigation system). The surrogates can be configured to withstand being crashed into by a test vehicle without being damaged and without damaging the test vehicle.

The technology provides designs and methods for the transit management system, which facilitates transit vehicle operations and control for connected automated transit vehicles (CATVs) systems. The transit management system provides transit vehicles with customized/non-customized information and time-sensitive control instructions for transit vehicle to fulfill the driving tasks such as vehicle routing, lane changing, turning. The transit management system also realizes transit vehicle lane design, transportation operations and management services for transit vehicle. The transit management system consists of one of more of the following physical subsystems: (1) Roadside Unit (RSU) network, (2) Traffic Control Unit (TCU) and Traffic Control Center (TCC) network, (3) Vehicle Onboard Unit (OBU), (4) Traffic Operations Centers (TOCs), (5) Cloud platform. The transit management system realizes one or more of the following function categories: sensing, transportation behavior prediction and management, planning and decision making, and vehicle control. The transit management system is supported by road infrastructure, real-time wired and/or wireless communication, the power supply networks, and cyber safety and security services.

The technology provides designs and methods for the transit management system, which facilitates transit vehicle operations and control for connected automated transit vehicles (CATVs) systems. The transit management system provides transit vehicles with customized/non-customized information and time-sensitive control instructions for transit vehicle to fulfill the driving tasks such as vehicle routing, lane changing, turning. The transit management system also realizes transit vehicle lane design, transportation operations and management services for transit vehicle. The transit management system consists of one of more of the following physical subsystems: (1) Roadside Unit (RSU) network, (2) Traffic Control Unit (TCU) and Traffic Control Center (TCC) network, (3) Vehicle Onboard Unit (OBU), (4) Traffic Operations Centers (TOCs), (5) Cloud platform. The transit management system realizes one or more of the following function categories: sensing, transportation behavior prediction and management, planning and decision making, and vehicle control. The transit management system is supported by road infrastructure, real-time wired and/or wireless communication, the power supply networks, and cyber safety and security services.

Responsive to the difficulties encountered in recycling, disposing of, and repurposing spent tires, as well as the need for durable construction materials, concentric tire structures and methods for making the same are provided herein.

Responsive to the difficulties encountered in recycling, disposing of, and repurposing spent tires, as well as the need for durable construction materials, concentric tire structures and methods for making the same are provided herein.

The barrier is of the type formed by a flexible or compact impact absorbing structure, in which inner or outer ducts are defined for the passage of cables having various functions, such as power supply, sensing, signaling and/or communication with a central traffic control unit, with the particularity that various barrier units are grouped to form a segment (4) that determines the lower level of a hierarchical distribution system with different autonomous and independent levels, providing a grid controlled by a data receiving, transmitting and managing central unit, in such a way that each segment (4) comprises an independent controller (8) comprising an electric power supply socket for the segment and a wireless communication module (9), ensuring the integrity of the grid, both horizontally, i.e. within the same level, thus avoiding any physical interruption to the transmission of signals, and vertically, i.e. hierarchically within the system.

A modular highway warning strip system which comprises a modular warning strip segment having first and second ends, a length extending between the first and second ends, two opposing lengthwise sides, a width extending between the opposing lengthwise sides of the segment, top and bottom surfaces, and a thickness. Each of the first and second ends comprise at least one male protrusion and at least one female receptacle, wherein the at least one male protrusion is configured to engage the at least one female receptacle for joining a plurality of the segments together end-to-end. A segmented metallic plate is disposed between upper and lower rubber layers, the segmented plate comprising a plurality of segments separated by slits comprising living hinges.

A modular highway warning strip system which comprises a modular warning strip segment having first and second ends, a length extending between the first and second ends, two opposing lengthwise sides, a width extending between the opposing lengthwise sides of the segment, top and bottom surfaces, and a thickness. Each of the first and second ends comprise at least one male protrusion and at least one female receptacle, wherein the at least one male protrusion is configured to engage the at least one female receptacle for joining a plurality of the segments together end-to-end. A segmented metallic plate is disposed between upper and lower rubber layers, the segmented plate comprising a plurality of segments separated by slits comprising living hinges.

A transition barrier for transitioning from a permanent median barrier to a temporary median barrier, the transition barrier having: a) a first end; the first end being connectable to the permanent median barrier by a permanent median barrier connector; b) a second end; the second end being connectable to the temporary median barrier by a temporary median barrier connector; c) a transition section defining a transition wall of a predetermined length between the first end and the second end; the transition wall having a top, bottom, front and a back; d) at least one barrier brace proximate the transition wall, for supporting said transition wall; and e) at least one spacer, proximate the back of the transition wall for contact with a surface of the permanent concrete barrier.

A modular cover panel including two or more cover panels that cover a parapet or barrier along a roadway. Multiple cover segments may overlap one another to form the modular cover panel and each cover panel is individually hung or suspended by brackets affixed to the parapet. Each cover segment has one more surfaces intersecting with other to cover the parapet and a top surface that overhangs a top surface of the parapet. A cable may be disposed through a slot of a hanging bracket and a pin may secure the cable thereby providing a mechanical attachment to the assembly.