Abstract: The invention provides an imaging system (102) for imaging a fundus (104) of an eye (106), which has an optical axis (116). The imaging system (102) has a light source (108), an illumination path (118) along which light travels from the light source (108) to the eye (106), a light sensor (10) and imaging optics (44) defining an imaging axis (114), and at least one objective lens (112) aligned with the optical axis (116). At least a part of the illumination path (118) is substantially coaxial with the imaging axis (114), and the optical axis (116) is tilted with respect to the imaging axis (114).

Abstract: The present disclosure describes image sensor modules that can include auto focus control. The modules also include features that can help reduce or eliminate tilt of the module's optical sub-assembly with respect to the plane of the image sensor. In some instances, the modules include features to facilitate highly precise positioning of the optical sub-assembly, and also can result in modules having a very small z height.

Abstract: Image sensor modules include primary high-resolution imagers and secondary imagers. For example, an image sensor module may include a semiconductor chip including photosensitive regions defining, respectively, a primary camera and a secondary camera. The image sensor module may include an optical assembly that does not substantially obstruct the field-of-view of the secondary camera. Some modules include multiple secondary cameras that have a field-of-view at least as large as the field-of-view of the primary camera. Various features are described to facilitate acquisition of signals that can be used to calculate depth information.

Abstract: An optoelectronic module assembly includes an optoelectronic module. The module includes: an active optoelectronic component in or on a mounting substrate, an optical sub-assembly, and a spacer disposed between the mounting substrate and the optical sub-assembly so as to establish a particular distance between the active optoelectronic component and the optical sub-assembly. The optoelectronic module assembly also includes a recessed substrate including first and second surfaces, wherein the second surface is in a plane closer to the optical sub-assembly than is the first surface. The optoelectronic module is mounted on the first surface. The second surface is for mounting other components.

Abstract: Optical assemblies include a stack of optical elements each of which has one or more alignment features. Each alignment feature traces a respective curve along a surface of one of the optical elements. The alignment feature(s) of one optical element fit within the alignment feature(s) of the other. In some cases, the alignment features can help establish more precise lateral alignment of the optical elements.

Abstract: The disclosure describes customizable optoelectronic modules and methods for standardizing a plurality of the customizable optoelectronic modules. The customizable optoelectronic modules can be configured to mitigate dimensional variations and misalignments in a number of their respective constituent components such as optical assemblies and sensor covers. The customizable optoelectronic modules and methods for standardizing a plurality of the customizable optoelectronic modules can obviate the need for binning during manufacturing thereby saving considerable resources such as time and expense.

Abstract: An optoelectronic module assembly includes an optoelectronic module. The module includes: an active optoelectronic component in or on a mounting substrate, an optical sub-assembly, and a spacer disposed between the mounting substrate and the optical sub-assembly so as to establish a particular distance between the active optoelectronic component and the optical sub-assembly. The optoelectronic module assembly also includes a recessed substrate including first and second surfaces, wherein the second surface is in a plane closer to the optical sub-assembly than is the first surface. The optoelectronic module is mounted on the first surface. The second surface is for mounting other components.

Abstract: Optical modules are made using customizable spacers to reduce variations in the focal lengths of the optical channels, to reduce the occurrence of tilt of the optical channels, and/or prevent adhesive from migrating to active portions of an image sensor.

Abstract: The disclosure describes customizable optoelectronic modules and methods for standardizing a plurality of the customizable optoelectronic modules. The customizable optoelectronic modules can be configured to mitigate dimensional variations and misalignments in a number of their respective constituent components such as optical assemblies and sensor covers. The customizable optoelectronic modules and methods for standardizing a plurality of the customizable optoelectronic modules can obviate the need for binning during manufacturing thereby saving considerable resources such as time and expense.

Abstract: An optical module comprising: a plurality of active optoelectronic components each one mounted on a respective printed circuit board (PCB), wherein each active optoelectronic component is associated with a respective different optical channel; a plurality of optical assemblies, each one is substantially aligned over a different respective optical channel; and a spacer separating the active optoelectronic components and PCBs from the optical assemblies, wherein the optical assemblies are attached by adhesive directly to an optical assembly-side surface of the spacer. A first active optoelectronic component is separated, by the spacer, from a first optical assembly by a first distance and a second active optoelectronic component is separated, by the spacer, from a second optical assembly by a different second distance.

Abstract: Various stacks of arrays of beam shaping elements are described. Each array of beam shaping elements can be formed, for example, as part of a monolithic piece that includes a body portion as well as the beam shaping elements. In some implementations, the monolithic pieces may be formed, for example, as integrally formed molded pieces. The monolithic pieces can include one or more features to facilitate stacking, aligning and/or centering of the arrays with respect to one another.

Abstract: Optical modules are made using customizable spacers to reduce variations in the focal lengths of the optical channels, to reduce the occurrence of tilt of the optical channels, and/or prevent adhesive from migrating to active portions of an image sensor.

Abstract: The present disclosure describes image sensor modules that can include auto focus control. The modules also include features that can help reduce or eliminate tilt of the module's optical sub-assembly with respect to the plane of the image sensor. In some instances, the modules include features to facilitate highly precise positioning of the optical sub-assembly, and also can result in modules having a very small z height.

Abstract: Optical modules are made using customizable spacers to reduce variations in the focal lengths of the optical channels, to reduce the occurrence of tilt of the optical channels, and/or prevent adhesive from migrating to active portions of an image sensor.

Abstract: Compact camera module can include auxiliary spacers to facilitate use of dam-and-fill encapsulation techniques. An encapsulant disposed on side edges of the auxiliary spacer can close off a gap between the auxiliary spacer and a support on which an image sensor is mounted so as to substantially seal off an area in which bond wires or other components are located. In some cases, the thickness of a transmissive substrate in the module can be reduced near its periphery to provide more head room for the bond wires, which can result in a smaller overall footprint for the module.

Abstract: The present disclosure describes modules operable to perform optical sensing. The module can be operable to distinguish between signals indicative of reflections from an object or interest and signals indicative of a spurious reflection such as from a smudge (i.e., a blurred or smeared mark) on the host device's cover glass. Signals assigned to reflections from the object of interest can be used to for various purposes, depending on the application (e.g., determining an object's proximity, a person's heart rate or a person's blood oxygen level).

Abstract: The disclosure describes customizable optoelectronic modules and methods for standardizing a plurality of the customizable optoelectronic modules. The customizable optoelectronic modules can be configured to mitigate dimensional variations and misalignments in a number of their respective constituent components such as optical assemblies and sensor covers. The customizable optoelectronic modules and methods for standardizing a plurality of the customizable optoelectronic modules can obviate the need for binning during manufacturing thereby saving considerable resources such as time and expense.

Abstract: Optical modules are made using customizable spacers to reduce variations in the focal lengths of the optical channels, to reduce the occurrence of tilt of the optical channels, and/or prevent adhesive from migrating to active portions of an image sensor.

Abstract: Various stacks of arrays of beam shaping elements are described. Each array of beam shaping elements can be formed, for example, as part of a monolithic piece that includes a body portion as well as the beam shaping elements. In some implementations, the monolithic pieces may be formed, for example, as integrally formed molded pieces. The monolithic pieces can include one or more features to facilitate stacking, aligning and/or centering of the arrays with respect to one another.

Abstract: Optical assemblies include a stack of optical elements each of which has one or more alignment features. Each alignment feature traces a respective curve along a surface of one of the optical elements. The alignment feature(s) of one optical element fit within the alignment feature(s) of the other. In some cases, the alignment features can help establish more precise lateral alignment of the optical elements.