Abstract: A frequency domain diffuse optical spectroscopy (FD-DOS) device and calibration method. The FD-DOS device includes a radio frequency signal generator, a driver, a light source, a silicon photomultiplier, an analog to digital conversion circuit, and an electronic processing circuit. The light source is configured to generate modulated light at a plurality of different wavelengths and modulation frequencies. The silicon photomultiplier is configured to generate analog detection signals indicative of detected optical signals. The analog to digital conversion circuit is configured to generate digital sample values from the analog detection signals. The electronic processing circuit is configured to determine absorption values and scattering values based on the digital sample values. The electronic processing circuit is also configured to determine concentration values based on the absorption values and the scattering values.

Abstract: A low cost portable high speed quantitative system for diffuse optical spectroscopic imaging of human tissue. The hybrid system (CWFD) can measure absolute optical properties from 660 nm to 980 nm and recover all tissue chromophore concentrations. The standalone FD module can be utilized to measure scattering at every measurement and recover deoxygenated and oxygenated hemoglobin concentrations. The CW module can operate concurrently with the FD module to also measure water and lipid. The high temporal resolution and large signal-to-noise ratio of the CWFD system may be used to explore tissue oximetry, vascular occlusion, and paced breathing models to measure and analyze tissue hemodynamics response to changes in blood flow. Continuous monitoring of vasculature response to various modified blood perfusion conditions can provide information about local tissue metabolism and physiological state (dysfunction).

Abstract: A low cost portable high speed quantitative system for diffuse optical spectroscopic imaging of human tissue. The hybrid system (CWFD) can measure absolute optical properties from 660 nm to 980 nm and recover all tissue chromophore concentrations. The standalone FD module can be utilized to measure scattering at every measurement and recover deoxygenated and oxygenated hemoglobin concentrations. The CW module can operate concurrently with the FD module to also measure water and lipid. The high temporal resolution and large signal-to-noise ratio of the CWFD system may be used to explore tissue oximetry, vascular occlusion, and paced breathing models to measure and analyze tissue hemodynamics response to changes in blood flow. Continuous monitoring of vasculature response to various modified blood perfusion conditions can provide information about local tissue metabolism and physiological state (dysfunction).

Abstract: The present invention provides a new and novel method of and system for predicting remaining battery capacity. The present invention is based upon the ability to predict remaining battery capacity from noting the discharge characteristics over a relatively short period of time at the beginning of full discharge. In particular, the present invention has found correlation factors which can be used in combination with discharge characteristics early in the full discharge, to predict the remaining battery capacity to a predetermined end discharge voltage. The ability to predict remaining battery capacity to a predetermined end discharge voltage can be extremely valuable in preventing battery shut down by allowing early detection of potential problems. Further, the present invention relates to a system of monitoring batteries using the method, which system can be operated a t a remote location from the batteries.

Abstract: In order to extend the useful life of electrical storage battery cells under float voltage charge it is advisable to maintain the polarization of the positive plates of the cell relative to a reference electrode in the cell at a predetermined level. This invention provides a sensing and controller circuit which drains minute amounts of current from the positive cell plates when the polarization rises above the desired level and thereby prevents plate corrosion and loss of electrolyte. The present invention may be combined with a circuit for increasing cell polarization levels to provide a system for maintaining battery cells at optimum polarization levels over extended float charging periods.

Abstract: The useful life of an electrolytic battery cell commonly employed in a series string as a backup power source is significantly extended by maintaining the polarization of the positive plates of such a cell at a predetermined level relative to a reference electrode of similar composition in contact with the cell electrolyte. While the cell is being supplied with the usual float charging voltage, a controller circuit senses any variance of polarization below the desired level and meters a minute input current to the positive plates with a resulting increase in the polarization over a substantial time period. The slow biasing of the polarization effects a passivation of the surface of the plates which deters the penetration of oxygen to the plate metal and prevents the deep destructive formation of expansive metal oxide.

Abstract: A process is described for making porous nickel bodies of various shapes. The process is advantageous because it permits casting, molding or extruding into various shapes before sintering. Such porous nickel bodies are useful as plaques in various kinds of batteries as well as filters, sieves and inert bodies for holding catalysts. Porous nickel bodies might also be useful for promoting heterogeneous gaseous reactions (with or without catalysis) particularly for gaseous exchange reactions.

Abstract: A process is described for loading nickel electrodes in porous plaques using an electrolytic technique. The process involves use of a counter electrolyte covered with a cobalt compound. This process is highly efficient because less hydrogen ions are liberated during the impregnation process and less buffering substance is needed to stabilize the pH of the solution.