Abstract: Medical implants may include a core body of a first material and one or more attached portions of a second material that enhances osseointegration into the medical implant. The attached portions may include wall-like shapes, sleeve-like shapes, or combinations thereof. The attached portions may be attached to perimeter surfaces of the core body of the implant. The attached portions may conform to and be in substantially continuous contact with the portions of the perimeter surfaces to which they are attached. The attached portions may generally sheathe the geometric area of the portions of the perimeter surfaces to which they are attached.

Abstract: A system and method are provided which include receiving, from a first user, first image data of a second user and a request to provide a value for the second user; storing the first image data of the second user in association with the value; transmitting, to the second user, a notification that the value is available; receiving, from an access device, an authorization request message comprising access data and second image data of the second user; determining a result based on (a) whether the first image data of the second user matches the second image data of the second user and (b) the stored value; and transmitting, to the access device, an authorization response message comprising the result.

Abstract: Embodiments of the present disclosure generally provide improved photolithography systems and methods using a digital micromirror device (DMD). The DMD comprises columns and rows of micromirrors disposed opposite a substrate. Light beams reflect off the micromirrors onto the substrate, resulting in a patterned substrate. Certain subsets of the columns and rows of micromirrors may be positioned to the “off” position, such that they dump light, in order to correct for uniformity errors, i.e., features larger than desired, in the patterned substrate. Similarly, certain subsets of the columns and rows of micromirrors may be defaulted to the “off” position and selectively allowed to return to their programmed position in order to correct for uniformity errors, i.e., features smaller than desired, in the patterned substrate.

Abstract: Embodiments of the present disclosure provide methods for producing images on substrates. The method includes providing a p-polarization beam to a first mirror cube having a first digital micromirror device (DMD), providing an s-polarization beam to a second mirror cube having a second DMD, and reflecting the p-polarization beam off the first DMD and reflecting the s-polarization beam off the second DMD such that the p-polarization beam and the s-polarization beam are reflected towards a light altering device configured to produce a plurality of superimposed images on the substrate.

Abstract: Embodiments of the present disclosure generally relate to an image projection system. The image projection system includes an active matrix solid state emitter (SSE) device. The active matrix solid state emitter includes a substrate, a silicon layer, and a emitter substrate. The silicon layer is deposited over the substrate having a plurality of transistors formed therein. The emitter substrate is positioned between the silicon layer and the substrate. The emitter substrate comprises a plurality of emitter arrays. Each emitter array defines a pixel, wherein one pixel comprises one or more transistors from the plurality of transistors. Each transistor is configured to receive a variable amount of current.

Abstract: One embodiment may include a machine for providing beverages. The machine may include a reader configured to read data representative of an available balance for a user to obtain beverages from the machine from a machine-readable medium and electronics. The electronics may be configured to receive the data from the machine-readable medium in response to the user positioning the machine-readable medium within reading distance of the reader, enable the user to dispense a beverage into a vessel, and update the available balance of the machine-readable medium so as to reduce or prevent the user from dispensing unlimited beverages.

Abstract: The present disclosure generally relates to lithography devices comprising an image projection system. The image projection system comprises a fiber bundle coupled to a first homogenizer and a second homogenizer. The first homogenizer is offset from the second homogenizer along a scan direction. The first homogenizer is optically aligned with a first digital micromirror device, and the second homogenizer is optically aligned with a second digital micromirror device. The first digital micromirror device is offset from the second digital micromirror device along the scan direction within an optical field of view of a projection lens. A scan field of the first digital micromirror device overlaps or aligns with a scan field of the second digital micromirror device to eliminate a gap between the scan field of the first digital micromirror device and the scan field of the second digital micromirror device.

Abstract: The embodiments described herein relate to a software application platform, which enhances image patterns resolution on a substrate. The application platform method includes running an algorithm to provide different target polygons for forming a pattern on a target. A minimum feature size which may be formed by a DMD is determined. For each target polygons smaller than the minimum feature size determining to line bias or shot bias the one or more target polygons to achieve an acceptable exposure contrast at the target polygon boundary. The one or more target polygons smaller than the minimum feature size are biased to form a digitized pattern on the substrate. Electromagnetic radiation is delivered to reflect off of a first mirror of the DMD when the centroid for the first mirror is within the one or more target polygons.

Abstract: Embodiments described herein provide a method shifting mask pattern data during a digital lithography process to reduce line waviness of an exposed pattern. The method includes providing a mask pattern data having a plurality of exposure polygons to a processing unit of a digital lithography system. The processing unit has a plurality of image projection systems that receive the mask pattern data. Each image projection system corresponds to a portion of a plurality of portions of a substrate and receives an exposure polygon corresponding to the portion. The substrate is scanned under the plurality of image projection systems and pluralities of shots are projected to the plurality of portions while shifting the mask pattern data. Each shot of the pluralities of shots is inside the exposure polygon corresponding to the portion.

Abstract: Embodiments of the present disclosure generally provide improved photolithography systems and methods using a digital micromirror device (DMD). The DMD comprises columns and rows of micromirrors disposed opposite a substrate. Light beams reflect off the micromirrors onto the substrate, resulting in a patterned substrate. Certain subsets of the columns and rows of micromirrors may be positioned to the “off” position, such that they dump light, in order to correct for uniformity errors, i.e., features larger than desired, in the patterned substrate. Similarly, certain subsets of the columns and rows of micromirrors may be defaulted to the “off” position and selectively allowed to return to their programmed position in order to correct for uniformity errors, i.e., features smaller than desired, in the patterned substrate.

Abstract: Embodiments described herein provide a system, a software application, and a method of a lithography process, to write full tone portions and grey tone portions in a single pass. One embodiment of the system includes a controller configured to provide mask pattern data to a lithography system. The controller is configured to divide a plurality of spatial light modulator pixels temporally by grey tone shots and full tone shots of a multiplicity of shots, and the controller is configured to vary a second intensity of a light beam generated by a light source and vary a first intensity of the light beam generated by the light source of each image projection system at the full tone shots.

Abstract: The present disclosure generally relates to light field displays and methods of displaying images with light field arrays. In one example, the present disclosure relates to pixel arrangements for use in light field displays. Each pixel includes a plurality of LEDs, such as micro LEDs, positioned adjacent respective micro-lenses of each pixel.

Abstract: Certain example embodiments relate to a distributed computing system including servers organized in a cluster and clients. One server is elected leader and is responsible for maintaining consensus information among the other servers. Each server is configured to determine whether a new leader election is to take place. If so, the respective server requests votes for a new leader from the other server(s) and determines whether it has won by a clear majority. Depending on the implementation, votes from eligible client devices are counted, either in a main election together with server votes, or in a tie-break election (if needed) after server votes. Once a server has won, the other servers are informed accordingly. It therefore is possible to maintain a highly-available, consistent, partition-tolerant cluster in the distributed computing systems, using client voters.

Abstract: Certain example embodiments relate to a distributed computing system including servers organized in a cluster and clients. One server is elected leader and is responsible for maintaining consensus information among the other servers. Each server is configured to determine whether a new leader election is to take place. If so, the respective server requests votes for a new leader from the other server(s) and determines whether it has won by a clear majority. Depending on the implementation, votes from eligible client devices are counted, either in a main election together with server votes, or in a tie-break election (if needed) after server votes. Once a server has won, the other servers are informed accordingly. It therefore is possible to maintain a highly-available, consistent, partition-tolerant cluster in the distributed computing systems, using client voters.

Abstract: Photoresist compositions, methods of manufacturing the photoresist compositions, and methods of using the photoresist compositions are provided. In one implementation, the photoresist composition comprises a novolac (novolac) resin, a diazonaphthoquinone (DNQ) dissolution inhibitor, a bis(azide) crosslinker, and a casting solvent. In one implementation, the bis(azide) crosslinker absorbs at wavelengths in a range between 325 nanometers and 400 nanometers. In one implementation, the bis(azide) crosslinker is an aromatic bi(azide) crosslinker.

Abstract: The invention relates to heterocyclic compounds consisting of a core nitrogen atom surrounded by three pendant groups, wherein two of the three pendant groups are preferably benzimidazolyl methyl and tetrahydroquinolyl, and the third pendant group contains N and optionally contains additional rings. The compounds bind to chemokine receptors, including CXCR4 and CCR5, and demonstrate protective effects against infection of target cells by a human immunodeficiency virus (HIV).

Abstract: Embodiments described herein provide a method shifting mask pattern data during a digital lithography process to reduce line waviness of an exposed pattern. The method includes providing a mask pattern data having a plurality of exposure polygons to a processing unit of a digital lithography system. The processing unit has a plurality of image projection systems that receive the mask pattern data. Each image projection system corresponds to a portion of a plurality of portions of a substrate and receives an exposure polygon corresponding to the portion. The substrate is scanned under the plurality of image projection systems and pluralities of shots are projected to the plurality of portions while shifting the mask pattern data. Each shot of the pluralities of shots is inside the exposure polygon corresponding to the portion.

Abstract: Systems and methods discussed herein relate to patterning substrates during lithography and microlithography to form features to a set or sets of critical dimensions using dose. The dose maps are generated based upon images captured during manufacturing to account for process variation in a plurality of operations employed to pattern the substrates. The dose maps are used along with imaging programs to tune the voltages applied to various regions of a substrate in order to produce features to a set or sets of critical dimensions and compensate for upstream or downstream operations that may otherwise result in incorrect critical dimension formation.

Abstract: Embodiments of the present disclosure generally provide improved photolithography systems and methods using a digital micromirror device (DMD). The DMD comprises columns and rows of micromirrors disposed opposite a substrate. Light beams reflect off the micromirrors onto the substrate, resulting in a patterned substrate. Certain subsets of the columns and rows of micromirrors may be positioned to the “off” position, such that they dump light, in order to correct for uniformity errors, i.e., features larger than desired, in the patterned substrate. Similarly, certain subsets of the columns and rows of micromirrors may be defaulted to the “off” position and selectively allowed to return to their programmed position in order to correct for uniformity errors, i.e., features smaller than desired, in the patterned substrate.

Abstract: An image correction application relating to the ability to apply maskless lithography patterns to a substrate in a manufacturing process is disclosed. The embodiments described herein relate to a software application platform, which corrects non-uniform image patterns on a substrate. The application platform method includes in a digital micromirror device (DMD) installed in an image projection system, the DMD having a plurality of columns, each column having a plurality of mirrors, disabling at least one entire column of the plurality of columns, exposing a first portion of the substrate to a first shot of electromagnetic radiation, exposing a second portion of the substrate to a second shot of electromagnetic radiation, and iteratively translating the substrate a step size and exposing another portion of the substrate to another shot of electromagnetic radiation until the substrate has been completely exposed to shots of electromagnetic radiation.