An image sensor module comprises: a substrate having a first side and second side, the first side being an opposite of the second side, an image sensor attached to the first side of the substrate, bonding wires to bond the image sensor to pads on the first side of the substrate, a protective structure disposed on the first side of the substrate surrounding the image sensor, the bonding wires, and the pads, the protective structure having a dam and a lid, a cover glass disposed on the protective structure, and a set of solder balls attached to the second side of the substrate.

A three-dimensional object printer generates image data of an object being formed in the printer with a plurality of light sources and a plurality of optical sensor arrays. A controller receives the image data and identifies measurements of the object and of the features of the object. The controller compares the measurements to expected measurements and adds material or removes material from the object in response to the identified measurements being outside a predetermined range about the expected measurements.

A three-dimensional object printer generates image data of an object being formed in the printer with a plurality of light sources and a plurality of optical sensor arrays. A controller receives the image data and identifies measurements of the object and of the features of the object. The controller compares the measurements to expected measurements and adds material or removes material from the object in response to the identified measurements being outside a predetermined range about the expected measurements.

A three-dimensional object printer generates image data of an object being formed in the printer with an optical sensor and identifies the heights of object features above a substrate on which the object is being formed. A controller operates one or more actuators to move the optical sensor at a plurality of distances above the object to generate image data of the object at a plurality of heights above the object. The controller identifies the distances of the features of the object with reference to the image data generated by the optical sensor and the focal length of the optical sensor.

A three-dimensional object printer generates image data of an object being formed in the printer with an optical sensor and identifies the heights of object features above a substrate on which the object is being formed. A controller operates one or more actuators to move the optical sensor at a plurality of distances above the object to generate image data of the object at a plurality of heights above the object. The controller identifies the distances of the features of the object with reference to the image data generated by the optical sensor and the focal length of the optical sensor.

A three-dimensional object printer generates image data of an object being formed in the printer with an optical sensor array and identifies the color of an upper surface of the object. The controller compares the identified color to a predetermined range about an expected color for the upper surface and operates ejectors to eject material of a color different than the identified color in response to the identified color being outside of the predetermined range.

A three-dimensional object printer generates image data of an object being formed in the printer with an optical sensor array and identifies the color of an upper surface of the object. The controller compares the identified color to a predetermined range about an expected color for the upper surface and operates ejectors to eject material of a color different than the identified color in response to the identified color being outside of the predetermined range.

The present disclosure relates to a micro-scanning device that comprises a surface on which specimen to be scanned is positioned, and at least one micro lens configured to enable scanning of the specimen so as to obtain micro-details of the specimen. One or more micro lenses are installed below the flatbed surface in an array of movable configuration or in a stationary configuration. The device further incorporates a front panel to live-view micro-detail image of a specimen placed on the flatbed surface and incorporates means to focus, size, and zoom/scale the micro-detail image of the specimen. The device can be either a portable/handheld device or a stationary device and incorporates scan firmware to save and store or send copy of image incorporating micro-details on an associated/coupled computing device and/or in the internal memory of the scanner for performing any of stitching, printing, saving or sharing.

In one example, a document scanner has a fixed-position scan bar and a built-in translatable calibration target. The scan bar has a linear array of imaging elements aimed in an imaging direction. The calibration target is spaced apart from and parallel to the linear array, and has a planar surface orthogonal to the imaging direction spanning the length of the linear array. The target is translatable during a calibration in a direction in a plane of the surface.

An optical device includes: a restriction member that restricts part of reflected light from a target object, the restriction member being formed from resin, the restriction member having an opening and a hole, the opening extending in a first direction crossing a propagation direction of the reflected light and formed at an upstream end in the propagation direction, the hole extending through the restriction member in the propagation direction; an optical member that transmits the reflected light that has passed through the opening; and a correction member that holds the optical member, and that comes into contact with part of an inner circumferential surface of the hole to correct a width of the opening.