A shunt resistor according to the present invention includes a pair of electrode plates spaced apart from each other in a plate surface direction and a resistive alloy plate that connects the pair of electrode plates and that has a predetermined set resistance value. A surface of the resistive alloy plate is provided with a visually recognizable character string pattern that is formed by laser processing and that indicates the set resistance value of the resistive alloy plate, and a surface area and a carving depth of the character string pattern are set in such a manner that the resistive alloy plate has the set resistance value.

Disclosed are a cost-effective light source device that can eliminate highlights or hotspots and reduce halo phenomenon on resistor surface and a method for reading resistor value with computer vision, in which an image of a body of a resistor is extracted through irradiation by an annular light source and reflection by a replaceable diffuse reflection hood such as paper box, paper bowl, or paper cup inside pasted with white paper and extraction by an image extraction device, followed by a series of image processing operations conducted by a control unit to calculate a disposition angle of the resistor in an image. Luminous elements on opposite axial ends of the resistor are activated, according to the disposition angle, for illumination, while luminous elements on opposite lateral sides of the resistor are shut down so that a clear color resistor image can be obtained.

Disclosed are a cost-effective light source device that can eliminate highlights or hotspots and reduce halo phenomenon on resistor surface and a method for reading resistor value with computer vision, in which an image of a body of a resistor is extracted through irradiation by an annular light source and reflection by a replaceable diffuse reflection hood such as paper box, paper bowl, or paper cup inside pasted with white paper and extraction by an image extraction device, followed by a series of image processing operations conducted by a control unit to calculate a disposition angle of the resistor in an image. Luminous elements on opposite axial ends of the resistor are activated, according to the disposition angle, for illumination, while luminous elements on opposite lateral sides of the resistor are shut down so that a clear color resistor image can be obtained.

Embodiments include a method of stress testing an electronics package with components that include a visual indicator. In an embodiment, the method comprises populating a plurality of components on an electronics package. In an embodiment, the plurality of components each comprise a visual indicator that is responsive to heat. In an embodiment, the method further comprises stress testing the electronics package and categorizing the plurality of components based on the visual indicators. In an embodiment, the method may further comprise modifying the plurality of components.

A resistor component includes an insulating substrate; a resistance layer disposed on a first surface of the insulating layer; and first and second terminals, spaced apart from each other, disposed on an external surface of the insulating substrate and connected to the resistance layer; a marking pattern portion disposed on a second surface of the insulating layer, opposing the first surface of the insulating substrate; and a marking protection layer disposed on the second surface and covering the marking pattern portion.

A over-current protection device includes a positive temperature coefficient (PTC) polymeric element having two opposite surfaces, two electrodes respectively connected to the surfaces of the PTC polymeric element, and a power-free trip indicator disposed on at least one of the electrodes for sensing temperature of the over-current protection device.

A resistor component includes an insulating substrate; a resistance layer disposed on a first surface of the insulating layer; and first and second terminals, spaced apart from each other, disposed on an external surface of the insulating substrate and connected to the resistance layer; a marking pattern portion disposed on a second surface of the insulating layer, opposing the first surface of the insulating substrate; and a marking protection layer disposed on the second surface and covering the marking pattern portion.

A over-current protection device includes a positive temperature coefficient (PTC) polymeric element having two opposite surfaces, two electrodes respectively connected to the surfaces of the PTC polymeric element, and a power-free trip indicator disposed on at least one of the electrodes for sensing temperature of the over-current protection device.

Provided is a current sensing resistor made of electrically conductive metal, the resistor including a code display portion obtained by encoding characteristic information specific to the current sensing resistor and displaying the encoded characteristic information in a readable manner.

Provided is a current sensing resistor made of electrically conductive metal, the resistor including a code display portion obtained by encoding characteristic information specific to the current sensing resistor and displaying the encoded characteristic information in a readable manner.