An apparatus is provided with a component configured to be operatively coupled to an interface. In a first state, the component is mechanically and/or electrically attached to a substrate. Exposure of the interface to a thermal event that meets or exceeds a first temperature the resilient material is subject to undergo a state change to a second state. The state change includes a physical transformation of the interface, and includes a position change of the component.

A reconfigurable electronic component comprising a channel having first and second ends and outer walls defining a lumen; a liquid phosphonic acid within the lumen; and a liquid metal within the lumen. A first electrical contact at the first end of the channel and a second electrical contact in communication with the lumen at the second end of the channel. A predetermined amount of a solvent and a liquid metal may be within the lumen, and the solvent may comprise ethanol. The liquid metal may be selected from the group consisting of eutectic gallium indium (EGaIn) and eutectic gallium-indium-tin alloys. The phosphonic acid may be selected from the group consisting of decylphosphonic acid (DPA), fluorobenzylphosphonic acid (FPA), and difluorobenzylphosphonic acid (DFPA). The first and second electrical contacts comprise copper. An overflow channel and a reservoir for the liquid metal and phosphonic acid may be in fluid communication with the lumen.

An apparatus is configured with a component having a coating comprising a material in a first phase (e.g., solid and/or liquid phase) with a transition temperature. The component is mechanically and/or electrically attached to a substrate. Exposure of the coating to a temperature that meets or exceeds the transition temperature causes the material to undergo a phase change. The phase change of the material alters the position of the component, including separation of the component from the substrate. The separation disrupts the attachment, thereby mitigating damage to the substrate and/or component.

A component having a coating comprising a material in a first phase (e.g., solid and/or liquid phase) with a transition temperature. The component is mechanically and/or electrically attached to a substrate. Exposure of the coating to a temperature that meets or exceeds the transition temperature causes the material to undergo a phase change. The phase change of the material alters the position of the component, including separation of the component from the substrate. The separation disrupts the attachment, thereby mitigating damage to the substrate and/or component.

An apparatus is provided with a component configured with an interface comprising a resilient material. In a first state, the component is mechanically and/or electrically attached to a substrate. Exposure of the interface to the temperature that meets or exceeds the transition temperature of interface causes the resilient material to undergo a state change. The state change of the interface alters the position of the component, including separation of the component from the substrate. The separation disrupts the attachment thereby mitigating damage to the substrate and/or component.

A Lighting module for an automotive vehicle, comprising: a light source; a binning electrical network comprising a configurable resistance; and an electrical driver module configured to supply an electrical current to the light source through the binning electrical network. And a method for configuring a lighting module for an automotive vehicle to electrically drive a light source thereof according to predetermined characteristics of the light source, the method comprising: providing the lighting module for an automotive vehicle, the lighting module comprising: the light source with the brightness class; and an electrical driver module configured to supply an electrical current to the light source through a binning electrical network; providing the binning electrical network, the binning electrical network comprising a configurable resistance.

An apparatus is provided with a component configured with an interface comprising a resilient material. In a first state, the component is mechanically and/or electrically attached to a substrate. Exposure of the interface to the temperature that meets or exceeds the transition temperature of interface causes the resilient material to undergo a state change. The state change of the interface alters the position of the component, including separation of the component from the substrate. The separation disrupts the attachment thereby mitigating damage to the substrate and/or component.

A method for forming a three-dimensional object with at least one conductive trace comprises providing an intermediate structure that is generated (e.g., additively or subtractively generated) from a first material in accordance with a model design of the three-dimensional object. The intermediate structure may have at least one predefined location for the at least one conductive trace. The model design includes the at least one predefined location. Next, the at least one conductive trace may be generated adjacent to the at least one predefined location of the intermediate structure. The at least one conductive trace may be formed of a second material that has an electrical and/or thermal conductivity that is greater than the first material.

Discussed is a flexible printed circuit board for overcurrent protection including a deformation layer formed between a first adhesive layer and a first polyimide layer or on the first polyimide layer. The deformation layer can include a shape memory material configured to be deformed in a certain predetermined direction at a predetermined temperature or higher.

The printed circuit board includes metallic zones including: a first, second and third positive terminal, a first and second negative terminal, wherein the second negative terminal is connected to the first negative terminal, and electric contacts for the mounting of one or more LEDs and electric traces such that the LEDs are connected in series forming a LED string. The printed circuit board comprises selection means implemented with electric traces and metallic contacts adapted to be short-circuited via links in order to permit all of the following connections: a connection of the LED string between the first and third positive terminal, a connection of the LED string between the first positive terminal and the first negative terminal, a connection of the LED string between the second and third positive terminal, and a connection of the LED string between the second positive terminal and the first negative terminal.