A set of acceleration electrodes for the acceleration of charged particles in a vacuum ion optical system, wherein each acceleration electrode comprises a conical section and at least an elongated leg protruding from the conical section, the elongated leg and any further elongated leg each being configured as a mechanical support and as an electrical connection between the conical section and an intended source of electric potential.

The present disclosure provides an electronic device. The electronic device includes a flexible element, and a sensing element adjacent to the flexible element and configured to detect a biosignal. The electronic device also includes an active component in the flexible element and electrically connected with the sensing element. A method of manufacturing an electronic device is also disclosed.

A thermal monitoring system (101) for sensing a temperature of a monitored device (104) includes a carrier (102) having a first surface (112) and a biasing element (122) coupled to the carrier (102) and configured to extend between the carrier (102) and the monitored device (104) to provide a first thermal conduction path therebetween. The biasing element (122) includes a first end (128) contacting the first surface (112) and a second end (130) opposite the first end (128) and configured to contact the monitored device (104). The biasing element (122) further includes a main body (132) formed of a thermally conductive material extending continuously between the first end (128) and the second end (130). The main body (132) is compressible between the monitored device (104) and the carrier (102). The thermal monitoring system (101) further includes a temperature sensor (124) coupled to the carrier (102) and configured to detect a temperature of the monitored device (104).

A vaporizer device may include a pressure sensor and an ambient pressure sensor. The pressure sensor may be configured to measure a first pressure in an air flow path in the vaporizer device. The ambient pressure sensor may be configured to measure a second pressure corresponding to an atmospheric pressure. The vaporizer device may further include a controller. The controller may be configured to transition the vaporizer device to a first standby mode when the first pressure is equal to or greater than the second pressure for a first threshold quantity of time. While the vaporizer device is in the first standby mode, the controller may be further configured to transition the vaporizer device to a second standby mode when the second pressure is a threshold quantity greater than the first pressure and no motion event is detected for a second threshold quantity of time.

An electro-mechanical park lock actuator includes a shaft and a circuit board. The shaft is arranged for connecting to a transmission park pawl. The circuit board includes a first non-contact inductive position sensor integrated circuit, a first trace electrically connected to the first non-contact inductive position sensor integrated circuit for determining an angular position of the shaft, and an electrical connector for connecting the circuit board to an external master controller. In some example embodiments, the electro-mechanical park lock actuator includes an electric motor drivingly connected to the shaft, and a transmission arranged in a torque path between the electric motor and the shaft.

The invention relates to a deformable display, more in particular a flexible, stretchable, and transparent deformable display based on light-emitting elements such as for example light-emitting diodes (LEDs). The invention also relates to the use and applications of such deformable display, including systems and methods making use of such deformable display. In addition the invention relates to a flexible, stretchable and transparent display being deformable in real-time while maintaining deformability.

A module assembly is attached on a headlining of a vehicle and includes a base where an upper portion thereof is open, a first printed circuit board (PCB) and a second PCB sequentially stacked on a plurality of supporting pillars extending in a vertical direction to an inner bottom surface of the base and electrically connected to each other by a flexible cable, and a cover assembled with the base to cover the first and second PCBs stacked on the base.

This disclosure relates to storage bin for a door of a motor vehicle. In an example, a door, which provides a boundary between a passenger compartment of the motor vehicle and an exterior of the motor vehicle, includes a storage bin configured such that an item in the storage bin is accessible both from the passenger compartment and from the exterior.

A circuit board includes a first outer wiring layer, a circuit substrate, and a second outer wiring layer stacked. The circuit substrate includes a first inner wiring layer, an insulating layer, and a second inner wiring layer stacked. A plurality of thermally conductive pillars is arranged at intervals on the first inner wiring layer, a liquid storage space is formed between every two adjacent thermally conductive pillars, and a thermally conductive agent is received in the liquid storage space. The first outer wiring layer is formed on the plurality of thermally conductive pillars. The second outer wiring layer is formed the second inner wiring layer. A first groove penetrates the second outer wiring layer, the second inner wiring layer and the insulating layer, exposes a portion of the first inner wiring layer, and corresponds to the thermally conductive pillars. At least one heating element is installed in the first groove.

The present disclosure provides an electronic device and method of manufacturing the same. The electronic device includes a first region, a second region, an electronic component, and a first sensing element. The second region is adjacent to the first region. The first region has a first pliability. The second region has a second pliability. The second pliability is greater than the first pliability. The electronic component is disposed at the first region. The first sensing element is disposed at the second region and electrically connected to the electronic component.