Abstract: In general, this disclosure relates to an apparatus that compresses lightweight plastic waste (e.g., used grocery bags, empty trash bags, food wrappers, etc.), and then applies a limited amount of heat to “bake” the compressed plastic into a “brick” of plastic. The plastic is compressed, and then heated enough to cause it to retain its compressed shape, without melting or substantial outgassing.

Abstract: In general, this disclosure relates to an apparatus that compresses lightweight plastic waste (e.g., used grocery bags, empty trash bags, food wrappers, etc.), and then applies a limited amount of heat to “bake” the compressed plastic into a “brick” of plastic. The plastic is compressed, and then heated enough to cause it to retain its compressed shape, without melting or substantial outgassing.

Abstract: In general, this disclosure relates to an apparatus that compresses lightweight plastic waste (e.g., used grocery bags, empty trash bags, food wrappers, etc.), and then applies a limited amount of heat to “bake” the compressed plastic into a “brick” of plastic. The plastic is compressed, and then heated enough to cause it to retain its compressed shape, without melting or substantial outgassing.

Abstract: An observation unit (OU) and auxiliary observation unit (AOU) sensor are calibrated in relation to an ambient environment. The OU sensor and the AOU sensor are calibrated in relation to an observational subject. Monitoring parameters are established for the calibrated sensors using a receiving unit (RU). Monitoring types are activated using the RU. Data is gathered from the OU sensor and the AOU sensor. A determination is made that the gathered data exceeds the established monitoring parameters. One or more alerts are generated based on the determination.

Abstract: A monocular unit permits visualization of image data received from an imaging device associated with a mobile computing device. The image data is displayed on a display of the mobile computing device. A trigger unit indicates a trigger actuation, where the trigger unit includes a trigger and a trigger bar, and where the trigger bar is moved by actuation of the trigger. A mounting component mounts the mobile computing device in relation to the monocular unit and the trigger unit. Adjustment wheels permit adjustment of the position of the mobile computing device in relation to the monocular unit, the trigger unit, and the mounting component.

Abstract: A monocular unit permits visualization of image data received from an imaging device associated with a mobile computing device. The image data is displayed on a display of the mobile computing device. A trigger unit indicates a trigger actuation, where the trigger unit includes a trigger and a trigger bar, and where the trigger bar is moved by actuation of the trigger. A mounting component mounts the mobile computing device in relation to the monocular unit and the trigger unit. Adjustment wheels permit adjustment of the position of the mobile computing device in relation to the monocular unit, the trigger unit, and the mounting component.

Abstract: The present disclosure describes methods and systems, including computer-implemented methods, computer-readable media, and computer systems, for measuring range to an object (e.g., range finding) by reflection of laser radiation. One computer-implemented method includes the following operations executed on a mobile computing device (MCD): targeting an object with the MCD display operating as a viewfinder, receiving a request to trigger a laser range finding operation, initiating triggering of an emitter on a laser range finding attachment (LRFA) coupled to the MCD, receiving range finding data from the LRFA, processing the range finding data, and initiating display of data associated with the object, the data corresponding to the processed range finding data.

Abstract: The present disclosure describes methods and systems, including computer-implemented methods, computer-readable media, and computer systems, for measuring range to an object (e.g., range finding) by reflection of laser radiation. One computer-implemented method includes the following operations executed on a mobile computing device (MCD): targeting an object with the MCD display operating as a viewfinder, receiving a request to trigger a laser range finding operation, initiating triggering of an emitter on a laser range finding attachment (LRFA) coupled to the MCD, receiving range finding data from the LRFA, processing the range finding data, and initiating display of data associated with the object, the data corresponding to the processed range finding data.

Abstract: The present disclosure describes methods, systems, and computer program products for a modular camera attachment for optical devices and its use. One computer-implemented method includes linking a modular camera accessory (MCA) to a smart device using a data connection; activating the application on the smart device for a collimation function between the MCA and a modular camera attachment-enabled optical (MCO) device; receiving collimation data from the MCA and a camera of the smart device configured to capture collimation data from the optical path of the MCO device; processing the collimation data received from the MCA and the MCO device to determine alignment indicators; using the determined alignment indicators, aligning the MCA with the MCO device optical characteristics; and activating the application on the smart device to process data received from the MCA.

Abstract: An observation unit (OU) and auxiliary observation unit (AOU) sensor are calibrated in relation to an ambient environment. The OU sensor and the AOU sensor are calibrated in relation to an observational subject. Monitoring parameters are established for the calibrated sensors using a receiving unit (RU). Monitoring types are activated using the RU. Data is gathered from the OU sensor and the AOU sensor. A determination is made that the gathered data exceeds the established monitoring parameters. One or more alerts are generated based on the determination.

Abstract: The present disclosure describes methods, systems, and computer program products for a modular camera attachment for optical devices and its use. One computer-implemented method includes linking a modular camera accessory (MCA) to a smart device using a data connection; activating the application on the smart device for a collimation function between the MCA and a modular camera attachment-enabled optical (MCO) device; receiving collimation data from the MCA and a camera of the smart device configured to capture collimation data from the optical path of the MCO device; processing the collimation data received from the MCA and the MCO device to determine alignment indicators; using the determined alignment indicators, aligning the MCA with the MCO device optical characteristics; and activating the application on the smart device to process data received from the MCA.

Abstract: A thermal imaging accessory (TIA) is linked with a head-mounted smart device (HMSD) with a data display for displaying data for an eye of a user wearing the HMSD. The HMSD supports the TIA in an orientation where a field-of-view of a thermal imaging camera of the TIA is substantially in alignment with the field-of-view of an eye looking through the data display. The HMSD is configured to: link the TIA to the HMSD, activate a thermal imaging application on the HMSD to receive data from the TIA and display it on an HMSD data display, receive thermal imaging data of a target from the TIA, process the thermal imaging data received from the TIA, and initiate a display of the processed thermal imaging data on the HMSD data display.

Abstract: The present disclosure describes methods and systems, including computer-implemented methods, computer-readable media, and computer systems, for measuring range to an object (e.g., range finding) by reflection of laser radiation. One computer-implemented method includes the following operations executed on a mobile computing device (MCD): targeting an object with the MCD display operating as a viewfinder, receiving a request to trigger a laser range finding operation, initiating triggering of an emitter on a laser range finding attachment (LRFA) coupled to the MCD, receiving range finding data from the LRFA, processing the range finding data, and initiating display of data associated with the object, the data corresponding to the processed range finding data.

Abstract: The “Universal Digital Camera Remote Control” (“UDCRC”) allows users to add a remote control to any camera having an interface port. The UDCRC comprises an adapter unit that connects to the interface port of the digital camera, and a remote unit that communicates with the adapter unit. Controls on the remote unit correspond to various functions of the digital camera so that when a user selects and activates one of the controls on the remote unit, a signal corresponding to the control selected is sent to the adapter unit. The adapter unit detects the signal and sends a corresponding command to the digital camera via the interface port so that the digital camera performs the function corresponding to the control selected by the user.

Abstract: A system and method is provided to assist a user going to a tradeshow to make detailed plans for visiting exhibitors at the show. The user may download a show-planning program and a database containing tradeshow information. By running the program, the user can search for exhibitors of interest, contact the exhibitors if desired, and set schedules for visiting exhibitors along selected paths, and identify the visit paths on the exhibition floor map of the tradeshow. Other useful information, such as transportation, hotels, restaurants, and interesting events and activities, may be provided to assist the user in making arrangements for attending the show. The scheduled visit plans can be printed out or downloaded to a portable computing device, which may include a GPS device for guiding the user along a planned visit path through the show floor.