A digital pathology scanning apparatus is configured to initiate a rescan of a portion of a sample responsive to detecting a mechanical vibration during image acquisition that exceeds a predetermined threshold. The digital pathology scanning apparatus includes a plurality of sensors and a processor that analyzes sensor data received during movement of a scanning stage supporting a sample during image acquisition. The processor is configured to identify a mechanical vibration imparted on the scanning stage during image acquisition and determine if the mechanical vibration exceeds a predetermined threshold. If the predetermined threshold is exceeded, the processor is configured to initiate a rescan of the portion of the sample being scanned at the time of the mechanical vibration.

A digital pathology scanning apparatus is configured to initiate a rescan of a portion of a sample responsive to detecting a mechanical vibration during image acquisition that exceeds a predetermined threshold. The digital pathology scanning apparatus includes a plurality of sensors and a processor that analyzes sensor data received during movement of a scanning stage supporting a sample during image acquisition. The processor is configured to identify a mechanical vibration imparted on the scanning stage during image acquisition and determine if the mechanical vibration exceeds a predetermined threshold. If the predetermined threshold is exceeded, the processor is configured to initiate a rescan of the portion of the sample being scanned at the time of the mechanical vibration.

A slide rack determination system for a digital slide scanning apparatus. In an embodiment, a motor drives a slide rack at a known rate toward an engagement surface. The elapsed time until engagement may be used to detect the presence or absence of the slide rack and/or the height of the slide rack. In addition, one or more sensors may detect one or more features of the slide rack, and these feature(s) may be used to determine the presence or absence of a slide rack, whether usage of the slide rack is supported or unsupported by the digital slide scanning apparatus, the orientation of the slide rack, and/or the manufacturer and/or model of the slide rack.

A slide rack determination system for a digital slide scanning apparatus. In an embodiment, a motor drives a slide rack at a known rate toward an engagement surface. The elapsed time until engagement may be used to detect the presence or absence of the slide rack and/or the height of the slide rack. In addition, one or more sensors may detect one or more features of the slide rack, and these feature(s) may be used to determine the presence or absence of a slide rack, whether usage of the slide rack is supported or unsupported by the digital slide scanning apparatus, the orientation of the slide rack, and/or the manufacturer and/or model of the slide rack.

A digital pathology scanning apparatus is configured to initiate a rescan of a portion of a sample responsive to detecting a mechanical vibration during image acquisition that exceeds a predetermined threshold. The digital pathology scanning apparatus includes a plurality of sensors and a processor that analyzes sensor data received during movement of a scanning stage supporting a sample during image acquisition. The processor is configured to identify a mechanical vibration imparted on the scanning stage during image acquisition and determine if the mechanical vibration exceeds a predetermined threshold. If the predetermined threshold is exceeded, the processor is configured to initiate a rescan of the portion of the sample being scanned at the time of the mechanical vibration.

A digital pathology scanning apparatus is configured to initiate a rescan of a portion of a sample responsive to detecting a mechanical vibration during image acquisition that exceeds a predetermined threshold. The digital pathology scanning apparatus includes a plurality of sensors and a processor that analyzes sensor data received during movement of a scanning stage supporting a sample during image acquisition. The processor is configured to identify a mechanical vibration imparted on the scanning stage during image acquisition and determine if the mechanical vibration exceeds a predetermined threshold. If the predetermined threshold is exceeded, the processor is configured to initiate a rescan of the portion of the sample being scanned at the time of the mechanical vibration.

A digital pathology scanning apparatus is configured to initiate a rescan of a portion of a sample responsive to detecting a mechanical vibration during image acquisition that exceeds a predetermined threshold. The digital pathology scanning apparatus includes a plurality of sensors and a processor that analyzes sensor data received during movement of a scanning stage supporting a sample during image acquisition. The processor is configured to identify a mechanical vibration imparted on the scanning stage during image acquisition and determine if the mechanical vibration exceeds a predetermined threshold. If the predetermined threshold is exceeded, the processor is configured to initiate a rescan of the portion of the sample being scanned at the time of the mechanical vibration.

A digital pathology scanning apparatus is configured to initiate a rescan of a portion of a sample responsive to detecting a mechanical vibration during image acquisition that exceeds a predetermined threshold. The digital pathology scanning apparatus includes a plurality of sensors and a processor that analyzes sensor data received during movement of a scanning stage supporting a sample during image acquisition. The processor is configured to identify a mechanical vibration imparted on the scanning stage during image acquisition and determine if the mechanical vibration exceeds a predetermined threshold. If the predetermined threshold is exceeded, the processor is configured to initiate a rescan of the portion of the sample being scanned at the time of the mechanical vibration.

Various embodiments may relate to a semiconductor laser device, including at least one laser diode, and at least one reflection surface which reflects diffusely and which is irradiated by the laser diode during operation, and an additional light-nontransmissive housing body having a cutout. The laser diode is the sole light source of the semiconductor laser device. The laser diode is mounted immovably relative to the at least one reflection surface. Light emitted by the semiconductor laser device during operation has the same spectral components as, or fewer spectral components than, light emitted by the laser diode. An interspace between the laser diode and the at least one reflection surface is free of an optical assembly. A light-emitting area of the semiconductor laser device is greater than a light-emitting area of the laser diode by at least a factor of 100.

Technologies for managing access to image data streams generated by a plurality of image sensors of an image sensor array include a camera driver module. The camera driver module limits exposure to a user to all but one of the image sensors of the image sensor array. In some embodiments, the image sensor array may include a single primary image sensor that is exposed to the user and one or more secondary sensors that are not exposed to the user. In other embodiments, the image sensor array may include more than one primary image sensor and any number of secondary image sensors. In such an embodiment, only one of the primary image sensors are exposed to the user, and none of the secondary image sensors, if available, are exposed to the user. Other embodiments are described herein and claimed.