A light sensor having an adaptively controlled gain includes a photoelectric element, an operational amplifier, a comparator, an adaptive gain control circuit, a variable capacitor and a pulse accumulator circuit. The photoelectric element converts light energy into a photocurrent. The operational amplifier outputs an error amplified signal based on a gain multiplied by a voltage difference between an input voltage and a reference voltage. The comparator compares the error amplified signal with a voltage of a reference voltage source to output a comparison signal. The adaptive gain control circuit includes a pulse detector circuit and a gain control circuit. The pulse detector circuit detects the comparison signal and a clock signal to output a pulse detected signal. The adaptive gain control circuit outputs a capacitance modulating signal according to the pulse detected signal. A capacitance of the variable capacitor is modulated according to the capacitance modulating signal.

A UV exposure dosimetry system includes at least one UV sensor that accurately measures the UV irradiance intensity. The UV dosimetry system integrates the measured UV irradiance intensity over time to calculate the real-time UV dosage and the vitamin D production by taking into account factors comprising UV sensor location, body surface area, clothing coverage, and sunscreen usage. Based on the measurement, the system can predict the time remaining to skin burn and the time remaining to reach daily goal of vitamin D production. The system can also estimate UV intensity for a time in the future at a geographic location based on the forecast UV index data, and predict UV dose and vitamin D generation for the user corresponding to user defined scenarios. The UV dosimetry system supports multi-user control through an advanced and user friendly input and output interface.

The present disclosure describes systems, methods, and devices for estimating spectral contributions in ambient light. The present disclosure also describes systems, methods, and devices for compensating for field of view errors resulting from the user, contextual structures (e.g., buildings, trees, fixtures, or geological formations), atmospheric effects (e.g., ozone coverage, smog, fog, haze, or clouds), device structures, and/or device orientation/tilt relative to a light source being measured (e.g., sun, indoor/outdoor light emitter, or an at least partially reflective surface). The present disclosure also describes systems, methods, and devices for estimating spectral contributions in light or color measurements and accounting for field of view errors to obtain a refined estimate.

A system for recommending ultraviolet protection for a subject's skin includes an interrogation device, an analysis device, and an output device. The interrogation device has an ultraviolet sensitive module configured to generate interrogation data based on sensed electromagnetic energy reflected by the subject's skin in response to irradiation of the subject's skin by an ultraviolet electromagnetic energy source. The analysis device is configured to receive the interrogation data from the interrogation device and generate an ultraviolet analysis, which includes a recommendation for further ultraviolet protection of the subject's skin, based at least in part on the interrogation data. The output device receives the ultraviolet analysis and outputs the recommendation for further ultraviolet protection of the subject's skin.

An external element of a timepiece including a frame made of a first material, the external element further including at least one light sensor.

Methods, systems, and apparatus, including computer programs encoded on computer storage media, for a light-to-frequency sensor conversion. In some implementations, a first output waveform is generated from a light signal, a frequency of the first output waveform being based on an intensity of the light signal, including integrating the light signal across multiple clock cycles. In response to receiving a notification, a hold operation is performed to stop integrating the light signal for a period of time. In response to an end of the hold operation, a second output waveform is generated that includes integrating the intensity of the light signal starting from the end of the hold operation over a count of the multiple clock cycles that start after the end of the hold operation by a delay amount. The first output waveform and the second output waveform are summed to determine the intensity of the light signal.

A photodetector of the invention is characterized by having a plurality of detector elements that are arranged over a light-transparent substrate and are connected in parallel. A foldable portable communication tool having two display portions of the invention is characterized by including one photodetector which includes a plurality of detector elements connected in parallel.

A system for measuring light intensity of a specific location and wirelessly transferring the light intensity data contains at least one light intensity sensing assembly and a computing device. The light intensity data is recorded by the light intensity sensing assembly and is wirelessly transferred to the computing device. The light intensity sensing assembly contains a dome lens, a photocell, a processing unit, a wireless data-transferring module, and a portable power source. The photocell is centrally mounted within the dome lens in order to receive a maximum amount of light. The photocell is electronically connected to the processing unit. In order to transmit the light intensity data, the processing unit is electronically connected to the wireless data transfer module. The photocell, the processing unit, and the wireless data-transferring module are powered by the portable power source.

A method for calculating a rate of UV radiation absorbed by a user's skin including: capturing image data of an area of the user's skin; determining a skin tone of the user's skin based on the captured image data; calculating a rate of UV radiation absorption for the determined skin tone; measuring an amount of UV radiation exposed to the user's skin; and calculating a rate of UV radiation that would be absorbed by the user's skin based on the user's skin tone and the amount of UV radiation exposed to the user's skin. The method can further comprise calculating an amount of time that the user can be exposed to the amount of UV radiation exposed to the user's skin based on predetermined criteria. The predetermined criteria can at least include an SPF level of sunscreen applied to the user's skin.

An improved case for use with a computing device provides at least one sensor, preferably for use with a processor of the computing device. For many embodiments, the computing device has a storage configuration with the computing device located below an upper surface of the case and a lifted configuration with the computing device supported at an angle alpha with a portion extending above the upper surface of the case.