A fetal movement measuring device includes a wearable article to be worn on a pregnant woman's abdomen, plural measurement units, and a mobile device pre-installed with a fetal movement algorithm. The measurement units are provided separately on the outer surface of the wearable article and each include a fetal movement sensor for sensing a dynamic physiological signal of the abdomen and a power supply element for supplying necessary electricity to the fetal movement sensor. The dynamic physiological signals sensed by the fetal movement sensors are received by the mobile device, processed with the fetal movement algorithm, and rid of synchronous signal components. Then, the fetal movement algorithm performs calculation on the remaining signal components to generate fetal movement information, which includes a fetal movement location and a fetal movement magnitude. Thus, each fetal movement is measured in a non-contact manner, and its location, obtained through asynchronous multipoint measurement.

Systems and methods directed to the assessment of tissue vascular health. An optical measurement device includes a light source with one or more wavelengths, configured to illuminate an area of tissue, a detector configured to capture the light reflecting from the tissue at the one or more illumination wavelengths, a processor configured to compute, based on the detected signal, one or more estimates of tissue vascular health, and a display or communication device (e.g., electronic data transfer) configured to store or report the tissue vascular health.

A health monitoring toilet system collects urine in a toilet system which may resemble a traditional water toilet. The toilet system may include a urine capture basin for collecting urine as a user urinates as with a traditional toilet. The urine capture basin may include a urine entry aperture which is an orifice leading into a urine sample cell. A fiber optic spectrometer may analyze the urine in the urine sample cell to collect relevant health data. The system may include a controller which may store and analyze spectral data and compile longitudinal data over time. The system may be in connection with other such systems to compare the analysis of a user's urine with those of other users stored in other such health monitoring toilet systems.

A far-infrared emitters with physiological signal detection and method of operating the same is disclosed. A far-infrared beam module is switched on and generates far-infrared beam irradiating to a human body when a control unit starting up a microwave detecting module detecting physiological signal of the human body. The control unit is switched off when the time that the far-infrared beam irradiating on the human body reach a presetting period of time, thereby achieving the purpose of energy conservation.

A patient diabetes monitoring system with an efficient unsupervised daily monitoring profile clustering algorithm, a method, and a computer product thereof are disclosed. The system may include a physiological data input device or sensor which receives a plurality of physiological measurements to generate a dataset, a memory which stores a clustering algorithm, and a processor. The clustering algorithm when executed by the processor, causes the processor to automatically pre-process the dataset to control an amount of bias/aggressiveness from the collected unsupervised daily monitoring profiles, thereby generating a pre-processed dataset, build a similarity matrix from the pre-processed dataset, and output an optimum number of similarity clusters found by the processor from the similarity matrix.

Examples herein may include a computer-implemented method for contextually transforming data into an aggregated display feed. The method may include determining a first biomarker from a first data stream and a second biomarker from a second data stream. The method may include determining that the first biomarker and the second biomarker are interlinked to a physiologic function or morbidity. The method may include determining one or more cooperative measures related to the physiologic function or morbidity using the first biomarker and the second biomarker. The method may include generating a directional measure to indicate a contextual summary of the one or more cooperative measure. The method may include displaying the directional measure to a health care provider.

An analyzing apparatus according to an embodiment includes processing circuitry. The processing circuitry is configured to calculate a tissue characteristic parameter value with respect to each of a plurality of positions within a region of interest, by analyzing a result of a scan performed on a patient. The processing circuitry is configured to determine a measurement region in the region of interest by performing an analysis while using the tissue characteristic parameter values. The processing circuitry is configured to calculate a statistic value of the tissue characteristic parameter values in the measurement region.

A method for providing a thermal feedback performed by a feedback device is disclosed. The method includes: applying an operating power to a thermoelectric element to start a thermoelectric operation for outputting a thermal feedback; stopping the application of the operating power to terminate the thermoelectric operation; and when the application of the operating power is stopped, applying a buffering power to the thermoelectric element to reduce a temperature returning speed of a contact surface so that a thermal inversion illusion is prevented. The thermal inversion illusion being opposite to the outputted thermal feedback.

The present disclosure provides a system and method for analyzing a physiological parameter of a vital sign signal. The method may include acquiring a vital sign signal, storing data, computing and analyzing, processing, and outputting a result. The system may compute and analyze the physiological parameter of the vital sign signal, especially a blood oxygen saturation, via a plurality of algorithms, judge or process the computation result, and output the judgment result.

A mobile imaging system can include a camera system configured to capture images in a visible, a near-infrared, and an infrared light spectrum, a filter assembly including at least two optical filters, an illumination module activatable to emit light, and a computer system including processing circuitry configured to perform operations including control the camera system to collect multispectral imaging data of biological tissue associated with an injury or ailment of a patient and process the multispectral imaging data to assess the injury or ailment; a battery arranged to power the mobile imaging system, and a housing encompassing the processing circuitry and the battery.