An assisted perception (AP) module comprises an attachment mechanism to attach the AP module to a helmet, and a housing to integrate modular components of the AP module. The housing comprises a front portion and side portion, the front portion located over an eye of the user. The modular components include sensors to collect information about an environment as sensor data, and processors located in the side portion. The processors execute one or more assisted perception engines that process the sensor data from the sensors into enhanced characterization data. Output devices electronically communicate the enhanced characterization data to a user, wherein at least one of the output devices protrudes from the front portion of the housing in front of an eye of the user.

A wearable device for spacing awareness including a housing assembly and an electronics assembly is disclosed. The housing assembly includes a housing which includes a lens. The housing includes a securing clip at a rear side to easily attach the housing to a wearer. Within the housing is the electronics assembly. The electronics assembly includes sensors securing within the housing and behind the lens. The sensors being infrared sensors that detect when someone is too close to the wearer through heat detection. The lens help improve the function of the sensors. When the sensors detect a person is too close to the wear a laser beam is emitted. The laser beam indicates how far from the wearer other people must remain so that proper social distancing is achieved. With proper social distancing the likelihood of cross contamination from air borne diseases, bacteria and viruses is reduced.

A monitoring system that is configured to monitor a property is disclosed. In one aspect, the monitoring system includes a sensor that is located in a room of the property and that is configured to generate sensor data. The monitoring system further includes a monitor control unit that is configured to receive the sensor data; based on the sensor data, determine environmental conditions of the room; determine whether the environmental conditions of the room are conducive to a baby sleeping; and, based on determining whether the environmental conditions of the room are conducive to a baby sleeping, perform a monitoring system action.

An optical module includes a base, a first optical component and at least two washers. The first optical component is disposed on the base and the first optical component has a flange. The washers are disposed on the first optical component and sandwiched in between the base and the flange. Each of the washers has a first side surface and a second side surface, wherein the first side surface and the second side surface tilt with respect to each other by an angle.

Some examples include a thermal imaging assembly, comprising a thermal sensor having a field of view and optics, an emitting source to validate the optics in the field of view, an emitter storage to selectively house the emitting source outside of the field of view, and a carrier to move the emitting source between the emitter storage and the field of view.

Disclosed herein are a spherical-motion average radiant temperature sensor (SMART Sensor) system which can be used in various applications, including but not limited to, informing or controlling HVAC systems in buildings, locating and tracking people or objects, and detecting the release of gases. The system may optionally include the use of sensors other than a non-contacting temperature sensor to improve calculations and determinations made by the system.

A hands-free measuring by an operator a temperature of a subject is carried out by arranging a remote temperature measuring module including a contactless infrared thermometer with a laser providing a pointer spot, on an operator's head, positioning the operator with the applied temperature measuring module at a safe distance from the subject, moving the operator's body and/or head so as to point the contactless infrared thermometer and the laser pointer spot at the subject hands-free, activating the temperature measuring module and thereby measuring a temperature of the subject by the contactless infrared thermometer hands-free, and displaying the measured temperature of the subject on a digital display.

A monitor device is provided, including: a fixing seat, for fixing to a structure; a casing, with an accommodating space, upper end of the longitudinal axis of the casing rotatably connected to the fixing seat; a first optoelectronic device, disposed on the lower end of the casing; a second photoelectric device and a third photoelectric device, respectively rotatably disposed at a first position and a second position outside the casing; a transmission mechanism, disposed in the accommodating space of the casing, and the transmission mechanism including: an angle rotation mechanism, connected to the fixing seat to drive the casing to rotate in a first direction relative to the fixing seat; and a second angle rotation mechanism connected to and driving the first, the second and the third optoelectronic device to rotate synchronously in a second direction; wherein the first direction and the second direction are orthogonal to each other.

The goal of the METHOD FOR ENVIRONMENTAL ANALYSIS AND CONTROL OF SPATIAL AREAS as a continuation of The Spatial Environmental Control Unit is a method of logging multi-spectral, multi-pixel infrared radiation data of objects in a spatial area for the analysis and control of heat transfer dynamics in the spatial area that is responsive to feedback for controlling the thermal conditions in the spatial area. The METHOD FOR ENVIRONMENTAL ANALYSIS AND CONTROL OF SPATIAL AREAS further makes the current norm of an absolute temperature control approach for thermal control and human comfort obsolete. Ambient environmental conditions and user preference variables makes the current approach to thermal control time consuming, inaccurate and tedious. The Spatial Environmental Control Unit as one of our foundation patents disclosed the physical components make thermal control and analysis more responsive and user friendly. The METHOD FOR ENVIRONMENTAL ANALYSIS AND CONTROL OF SPATIAL AREAS makes the control and analysis of the thermal properties of the spatial area more intuitive by providing visual images on any compatible device simplifying the understanding of the dynamics of heat transfer in an environment. Tedium and frustration become understanding and empowerment. This method enables gaining knowledge and using tools for analysis, allowing a user to redesign his environment by correcting ambient conditions and improving the operation of the thermal conditioning equipment. The end result is a better thermal environment with higher energy efficiency.

A method of detecting defects in a composite structure includes applying heat to a surface of a composite structure. Thermographic images or frames captured by a moving camera may be utilized to form temporally aligned images that include temperature data (pixels) from a plurality of frames, wherein the (pixels) comprise data captured at a simple (uniform) time delay from the time at which heat was applied. The temporally aligned thermographic data for the surface region may include variations due to differences in thermal transients caused by defects in the composite structure. The variations in the thermographic data may be utilized to detect one or more defects in the composite structure.