A system and method for controlling an emitter assembly comprising a single electromagnetic radiation source for visualizing a surgical site. The emitter assembly comprises a light valve assembly that is coupled to a control circuit. The emitter assembly is configured to emit visible light, infrared radiation, or a combination thereof in either structured or unstructured formats. The control circuit is configured to control the light valve assembly to control which emitter of the emitter assembly is emitting electromagnetic radiation. The light valve assembly can include light valves for controlling whether an emitter receives electromagnetic radiation. Further, the control circuit can control the wavelength of the electromagnetic radiation emitted by the source in accordance with which emitter is receiving electromagnetic radiation.

A surgical suturing tracking system configured for use with a suturing needle is disclosed. The surgical suturing tracking system comprises a spectral light emitter, a waveform sensor, and a control circuit coupled to the waveform sensor. The control circuit is configured to cause the spectral light emitter to emit spectral light waves toward a suturing needle and a tissue structure, receive an input corresponding to the spectral light waves reflected by the needle and the tissue structure and determine a distance between the needle and the tissue structure based on the received input.

The present invention relates generally to a slope spectroscopy standards and methods of making slope spectroscopy standards, specifically standards and methods of developing standards specifically for variable pathlength (slope) measurements.

There is presented an apparatus for determining one or more time response values of an analyte or a group of analytes (96) in a liquid (99) comprising a translucent element comprising pores (6), wherein the pores (6) are dead end pores (6) extending into the translucent element from respective openings (7) in the translucent element, wherein a cross-sectional dimension of the openings (7) of the pores (6) is dimensioned so as to prevent larger particles or debris from entering the pores (6), while allowing the analyte or the group of analytes in the liquid (99) to enter the pores (6) via diffusion, one or more light sources (10) being adapted to illuminate at least the pores (6) in the translucent element (2), and a light detector (20) being adapted to at each of multiple points in time receive light (21) emerging from the pores (6) in response to illumination (11) by the one or more light sources, wherein the light detector is further adapted to generate one or more signals based on the received light, each of the one or more signals being temporally resolved and representative of at least a part of the received light, and wherein the apparatus is further comprising a data processing device comprising a processor configured to determine one or more time response values based on the one or more signals.

The disclosure provides an apparatus, a device, and methods for improving optical analysis of a thin layer of a sample between two plates, particularly for multiple wavelengths.

Fertilizer application is challenged by inadequate constraints on key factors that determine how much to apply, and when to apply. Systems and methods for are disclosed that can make use of prior information (e.g. from field trials), time series data from a radiation measuring device, and episodic but spatially extensive satellite data, to constrain these uncertainties.

The invention relates to a method for determining concentrations of absorbing gases by means of a spectroscopic measuring device, wherein wavelength-dependent measurement values for a light intensity are obtained and a wavelength-dependent measurement value function is represented based on these values. A wavelength-dependent theoretical function is defined, which includes as parameters a calibration parameter and the concentrations. The calibration parameter is defined as a function of a device parameter and a correction parameter that depends on the concentrations. A cycle comprising a sequence of steps is performed several times in a row, wherein in a first step a numerical value for the correction factor is calculated from stipulated assumed values of the concentrations, wherein in a second step the theoretical function is determined using the calculated numerical value, wherein in a third step values for the concentrations are obtained by a curve adjustment calculation between the theoretical function determined in the second step and the measurement value functions and are stipulated as new assumed values. The assumed values obtained in the third step of the last cycle are output as new measured values.

Disclosed is a spectroscopic device, system, and method for measuring the concentration of one or more molecular species of interest in a gas, liquid or solid sample, where the device may be portable, may be commercially manufactured, and/or may be adapted to existing systems and/or integrated with new systems to provide optical gas sensing for such systems. The disclosed devices, systems, and methods can be particularly useful in monitoring the purity of, e.g., a certain gas species, including determining whether a gas mixture contains certain gas species above a set concentration limit.

An image analysis apparatus includes: a distribution data generator that generates, on the basis of a sample image obtained by irradiating a biological tissue with light having an infrared bandwidth, distribution data indicating a distribution of light intensity in the infrared bandwidth in the tissue; a differential calculator that calculates, on the basis of the distribution data, an Nth-order derivative of the distribution of the light intensity in a first wavelength band in the infrared bandwidth, where N is an integer of 2 or more, for each region in the sample image; and an image data generator that converts the Nth-order derivative into a gray-scale value to generate image data.

The invention relates to a non-destructive and non-invasive method for determining the concentration or other parameters of constituent substances in fluids, which method is capable of minimizing the optical interfering influences, which are unknown but constant during the individual measurement, of the vessel wall on the measurement result or the evaluation, in that measurements are carried out with different through-radiation path lengths and quotient calculations eliminate the influences of the vessel wall. Wide-area illumination and detection ensure that non-linearities occurring during said measurements do not interfere with the accuracies of the determination.