A device having at least one power semiconductor die coated with a metallization and at least one light guide having two opposite ends. The first end is able to be connected at least to a light source and to a light receiver. The second end is permanently fixed facing to a surface of the metallization such that to form a light path towards said surface and a light path from said surface.

An optical device is mounted to an electronic circuit having a main face with at least one light source. The optical device is made from a block which includes, for each light source, a corresponding opening that passes through the block. The opening includes a cylindrical part with a threading on an inside surface.

Various approaches can be used to interrogate a surface such as a surface of a layered semiconductor structure on a semiconductor wafer. Certain approaches employ Second Harmonic Generation and in some cases may utilize pump and probe radiation. Other approaches involve determining current flow from a sample illuminated with radiation. Decay constants can be measured to provide information regarding the sample. Additionally, electric and/or magnetic field biases can be applied to the sample to provide additional information.

A system and method for rotary motion with vacuum sealing is provided. The system includes a vacuum chamber, a component mount disposed in the vacuum chamber, and a base. A bellows is disposed between the base and the component mount, and the bellows provides a seal between the base and the component mount. The bellows, the base, and the component mount define an actuator compartment therebetween. An actuator is disposed in the actuator compartment. The actuator is configured to rotate the component mount relative to the base in order to align a component disposed on the component mount. Rotation of the component mount relative to the base causes torsional elastic deformation of the bellows.

In an optical carrier injection method, a pulsed optical beam having pulse duration of 900 fs or lower is applied on a backside of a substrate of an integrated circuit (IC) wafer or chip, and is focused at a focal point in an active layer on a frontside of the substrate. Photons of the optical beam are absorbed at the focal point by nonlinear optical interaction(s) to inject carriers. The pulsed optical beam may be applied using a fiber laser in which the fiber is doped with Yb and/or Er. An output signal may be measured, comprising an electrical signal or a light output signal produced by the IC wafer or chip in response to the injected carriers. By repeating the applying, focusing, and measuring over a grid of focal points in the active layer, an image of the IC wafer or chip may be generated.

The present disclosure provides a dual-sided wafer imaging apparatus and methods thereof. The dual-sided wafer imaging apparatus includes one or more load ports, one or more mechanical arms for transporting a wafer, a wafer transfer stage, a first line scan camera mounted below the wafer transfer stage, a second line scan camera mounted above the wafer transfer stage, a first optical lens mounted on the first line scan camera, a second optical lens mounted on the second line scan camera, and line light sources respectively mounted below and above the wafer transfer stage. The load ports are configured for an automated load operation or unload operation of a wafer pod of an automated transport equipment. The wafer transfer stage includes vacuum suction points in contact with a backside of the wafer, and the wafer transfer stage further includes a drive motor producing a linear reciprocating motion for moving the wafer.

Various approaches can be used to interrogate a surface such as a surface of a layered semiconductor structure on a semiconductor wafer. Certain approaches employ Second Harmonic Generation and in some cases may utilize pump and probe radiation. Other approaches involve determining current flow from a sample illuminated with radiation. Decay constants can be measured to provide information regarding the sample. Additionally, electric and/or magnetic field biases can be applied to the sample to provide additional information.

A system for laser enhanced voltage contrast using an optical fiber is provided. The system includes a vacuum chamber with a stage that secures a wafer. A laser light source outside the vacuum chamber directs light to an optical fiber. The optical fiber transmits all wavelengths of light from the laser light source into the vacuum chamber through a wall of the vacuum chamber.

A test apparatus includes an electrical connection unit electrically connected to respective terminal of each of a plurality of LEDs to be tested, a light source unit which collectively irradiates the plurality of LEDs with light, a measuring unit which measures a photoelectric signal that each of the plurality of LEDs outputs via the electrical connection unit after photoelectrically converting the light with which the light source unit irradiates the plurality of LEDs, and a determination unit which determines pass or fail of each of the plurality of LEDs based on the measurement results by the measuring unit.

A device for converting electrical energy, including at least one switching-type semiconductor component, a cooling path for cooling the semiconductor component, and a device for determining a degradation of the cooling path based on a current having a predetermined current intensity that flows through the component. The device provides that the semiconductor component includes an optically active semiconductor material, which generates light having a brightness that is dependent on a temperature of the semiconductor component when the semiconductor component is traversed by current having a predetermined current intensity, and the device for determining the degradation includes a brightness sensor for recording the brightness of the generated light. The device has the advantage that the device for determining the degradation and the component are inherently galvanically isolated, and the degradation can be determined at a high resolution.