The techniques described herein enable a head-mounted display device to use a fiducial marker to identify an Internet of Things (IoT) device. The head-mounted display device can use the identifier to establish a network connection with the IoT device. For example, the identifier can include an Internet Protocol (IP) address, a Bluetooth address, a cloud IoT identifier (e.g., AZURE hub IoT identifier), or another type of an identifier. By using an electronic paper display, the IoT device can dynamically generate and display a new fiducial marker when a new identifier is assigned to the IoT device or is generated by the IoT device. Consequently, the head-mounted display device can detect the fiducial marker and extract the identifier for the IoT device from the fiducial marker so that the identifier can be used to establish a network connection with the IoT device.

A measurement device for measuring a relative position between alignment marks includes an illumination unit capable of illuminating the alignment marks at a plurality of wavelengths, a detection unit that detects light from the alignment marks, a processing unit that obtain the relative position between the alignment marks, and an adjustment unit that adjusts a relative amount between light amounts of the plurality of wavelengths so that a relative value between detection light amounts of light from the alignment marks falls within a predetermined range.

A measurement device for measuring a relative position between alignment marks includes an illumination unit capable of illuminating the alignment marks at a plurality of wavelengths, a detection unit that detects light from the alignment marks, a processing unit that obtain the relative position between the alignment marks, and an adjustment unit that adjusts a relative amount between light amounts of the plurality of wavelengths so that a relative value between detection light amounts of light from the alignment marks falls within a predetermined range.

The present disclosure provides compositions and methods for making and using a support (e.g., a sample slide) for sample analysis. The present disclosure also provides compositions, methods, and systems for processing a sample on the support for use in nucleic acid sequence detection.

An apparatus includes an optical source situated to produce a fiducial source beam, and an optical fiducial pattern generator situated to produce with the fiducial source beam at least one transient optical fiducial on a laser processing target that is in a field of view of a laser scanner situated to scan a laser processing beam across the laser processing target, so that a positioning of the laser processing beam on the laser processing target becomes adjustable relative to the at least one transient optical fiducial.

An apparatus includes an optical source situated to produce a fiducial source beam, and an optical fiducial pattern generator situated to produce with the fiducial source beam at least one transient optical fiducial on a laser processing target that is in a field of view of a laser scanner situated to scan a laser processing beam across the laser processing target, so that a positioning of the laser processing beam on the laser processing target becomes adjustable relative to the at least one transient optical fiducial.

Example methods, apparatuses, and computer program products related to analyzing fluid samples are provided. For example, an example computer-implemented method for analyzing fluid samples includes receiving digital holography image data associated with a fluid sample in a flow chamber device; extracting, from the digital holography image data, an upper reference mark image region associated with an upper reference mark and a lower reference mark image region associated with a lower reference mark; determining a maximum focal depth and a minimum focal depth associated with the digital holography image data, respectively; focusing each of a plurality of focal depth layers associated with the digital holography image data; and extracting, from the plurality of focal depth layers, one or more region of interest (ROI) portions that are associated with the fluid sample.

A reticle has a horizontal stadia line and a vertical stadia line. A plurality of elevation subtension markings having a thickness are connected to the vertical stadia line. A plurality of fine subtension markings are positioned along the horizontal stadia line. A plurality of coarse subtension markings are positioned along the horizontal stadia line. The thickness of the coarse subtension markings is greater than the thickness of the fine subtension markings. A Christmas tree dot pattern is provided below the horizontal stadia line with a hold point feature within a lower portion of the Christmas tree dot pattern.

A reticle has a horizontal stadia line and a vertical stadia line. A plurality of elevation subtension markings having a thickness are connected to the vertical stadia line. A plurality of fine subtension markings are positioned along the horizontal stadia line. A plurality of coarse subtension markings are positioned along the horizontal stadia line. The thickness of the coarse subtension markings is greater than the thickness of the fine subtension markings. A Christmas tree dot pattern is provided below the horizontal stadia line with a hold point feature within a lower portion of the Christmas tree dot pattern.

Microlens array formation and alignment to heterogeneously integrated optoelectronic devices. Optoelectronic devices are printed or transferred in a single process step while also creating inactive optoelectronic devices that are precisely shaped for alignment purposes rather than for optical or electrical performance. Microlenses are integrated monolithically. The microlenses are aligned directly to a fiducial generated by the device integration step, reducing overall misalignment. Additionally, we use specific optical designs for the lenses to add novel functionalities to the system. By designing the lenses with engineered offsets, distances and curvatures with respect to the arrays of optoelectronic devices, we control properties of light such as: angles, phase, beam widths, and wavelength dependence.