Embodiments herein relate to devices and methods for deep tissue optical sensing. In an embodiment, an optical monitoring device is included having a first optical emitter, where the first optical emitter is configured to emit light at a first wavelength. The optical monitoring device includes a first optical detector, where the first optical detector is configured to selectively detect incident light with respect to its angle of incidence on the optical monitoring device. The first optical emitter is configured so that the emitted light from the optical emitter propagates through a tissue at a depth of at least 1 cm into the tissue as measured from a surface of the optical monitoring device. The optical monitoring device is configured to determine a physiological parameter of the tissue using incident light detected by the first optical detector. Other embodiments are also included herein.

Provided is a monitor for monitoring the condition of the interior of a living organism from the surface of the living organism. The monitor is provided with: a probe which includes an observation window and is attached to the organism surface; a unit which irradiates, with a laser, at least a portion of an observation region; a unit which detects scattered light resulting from the laser irradiation; a Doppler analysis unit and a SORS analysis unit which narrow down the observation spots to a first observation spot; and a CARS analysis unit which obtains the optical spectrum for at least one component, and outputs first information indicating the condition of the organism interior on the basis of the intensity of the spectrum.

Aspects relate to an energy harvesting device adapted for use by an athlete while exercising. The device may utilize a mass of phase-change material to store heat energy, the stored heat energy subsequently converted into electrical energy by one or more thermoelectric generator modules. The energy harvesting device may be integrated into an item of clothing, and such that the mass of phase change material may store heat energy as the item of clothing is laundered.

A wearable device is provided. The wearable device includes a housing including a transparent part, a circuit board disposed in the housing and including a first surface facing the transparent part and a second surface opposite to the first surface, a first integrated circuit (IC) layer disposed adjacent to the circuit board, a first sensor module, at least a part of which is disposed in the first IC layer, a second sensor module disposed adjacent to the first sensor module, and a second IC layer electrically connected to the first IC layer and the circuit board, and including a processor configured to process data acquired by the first sensor module and the second sensor module, wherein the circuit board, the first IC layer, and the second IC layer are stacked and disposed in a direction perpendicular to the first surface or the second surface of the circuit board.

A heart rate module, comprising a housing structure composed of a rear housing (2) and a light-transmitting cover plate (3), the housing structure being internally provided with a PCB assembly (1); the PCB assembly (1) comprises a PCB, PDs (6, 7) and an LED (5), the PDs (6, 7) and the LED (5) being fixed on the PCB according to a preset distance; a hot melt positioning column (21) is provided on the rear housing (2), and the PCB assembly (1) is fixed, by means of the hot melt positioning column (21), on the rear housing (2). Use of the heart rate module can solve the problems of the assembly method of the available heart rate meter being complicated and the requirement for a terminal product being high.

A measurement system is provided with an array of laser diodes with one or more Bragg reflectors. At least a portion of the light generated by the array is configured to penetrate tissue comprising skin. A detection system configured to: measure a phase shift, and a time-of-flight, of at least a portion of the light from the array of laser diodes reflected from the tissue relative to the portion of the light generated by the array; generate one or more images of the tissue; detect oxy- or deoxy-hemoglobin in the tissue; non-invasively measure blood in blood vessels within or below a dermis layer within the skin; measure one or more physiological parameters based at least in part on the non-invasively measured blood; and measure a variation in the blood or physiological parameter over a period of time.

A trans-illuminative intraoral diagnostic lighting system includes a housing containing at least one LED and has a removable light diffusing positioning apparatus attached to it that facilitates proper positioning of the housing within the oral cavity of a person behind their teeth. When the LED(s) is/are activated, the oral cavity is illuminated and light passes through the teeth making their internal structures visible outside the oral cavity. A retractor may be used to retract the cheeks and lips to allow full exposure of the teeth and a camera may be employed to photograph the teeth from outside the oral cavity.

The invention is a breath sensing device comprising a sensing pad, a plurality of coverage sensing units, and a signal processor, the coverage sensing units are disposed on the sensing pad, when a user lies down on the sensing pad, a plurality of coverage signals sensed by the coverage sensing units respectively produce a periodic change according to the deformation of a curve along the body of the user while breathing, the signal processor is electrically connected to the coverage sensing units to receive the coverage signals, and the signal processor calculates to obtain duration and proportion of the user's inspiration, expiration, and pause phase and depth information of breathing from a waveform of the coverage signals based on a signal-processing algorithm.

The present disclosure generally relates to wearable devices and methods for measuring a photoplethysmographic (PPG) signal. The wearable devices and methods described herein are capable of obtaining PPG signals by employing a PPG sensor array configured to receive light at angles associated with a high perfusion index. Viewing components may be coupled to the PPG sensor array to effect transmission of light at these preferential angles.

An analysis device includes a substrate including a first surface, and a second surface positioned at a side opposite to the first surface; a light source part located at the first surface of the substrate, the light source part including a quantum cascade laser; a light detector located at the first surface of the substrate; and a wiring part located at the first surface of the substrate, the wiring part being electrically connected with the light source part and the light detector.