This document describes assessment of human physiological systems. Various noninvasive sensors can be used to detect vitals and other parameters and combined with mathematical models to assess the functional state of physiological systems. Conventional techniques can use invasive sensors to monitor cardiac pressures and volumes, along with pressure transit to quantify cardiovascular health. While known to be effective these invasive techniques often require surgery and are resource intensive limiting their use to cases where the risks and costs are of clear immediate benefit. In contrast, noninvasive health monitors present little if any risk and are easy to use. Further, the techniques described herein can determine trends in a person's cardiovascular health. With these trends, a person can know if the effort they expend to improve heart health actually makes a difference. Further, negative trends can be found that can spur people to improve their health or get medical attention.

Methods and apparatuses for determining in-situ a temperature of a substrate with a thermal sensor in a vacuum chamber are described herein. In one embodiment a thermal sensor has a transmitter configured to transmit electromagnetic waves, a receiver configured to receive electromagnetic waves, and a controller configured to control the transmitter and receiver, wherein the controller determines a temperature from a difference between the transmitted electromagnetic wave and the received electromagnetic wave.

A thermal sensing device can include an electromagnetic radiation source configured to generate electromagnetic radiation, a first antenna configured to direct electromagnetic radiation generated by the radiation source toward a target, and a second antenna configured to receive microwave radiation emitted from an internal portion of the target. The thermal sensing device can also include a microwave sensor coupled to the second antenna and configured to acquire sensor data regarding the microwave radiation emitted from an internal portion of the target. A processing device, included in the thermal sensing device, can be configured to produce thermal data based on the sensor data.

A system includes a first printed circuit board (PCB), a temperature sensor, a switching circuit provided on the first PCB, and a controller. The temperature sensor is configured to measure temperature of at least an area of the first PCB. The controller is configured to trigger the switching circuit to turn off power to the first PCB, based at least in part on the temperature sensor detecting a temperature above a temperature threshold. The system is able to disrupt power much faster than conventional methods of power protection which may have a blind spot to certain areas of the first PCB, since these methods rely on power disruption when a maximum power is sensed.

Devices, systems, and techniques for monitoring the temperature of a device used to charge a rechargeable power source are disclosed. Implantable medical devices may include a rechargeable power source that can be transcutaneously charged. The temperature of an external charging device and/or an implantable medical device may be monitored to control the temperature exposure to patient tissue. In one example, a temperature sensor may sense a temperature of a portion of a device, wherein the portion is non-thermally coupled to the temperature sensor. A processor may then control charging of the rechargeable power source based on the sensed temperature.

Embodiments of a code modulated phased-array interferometer are described. In one embodiment, a code modulated phased-array interferometer includes a phased array having a plurality of receiver elements that receive a plurality of received signals. A code multiplexer multiplexes each of the plurality of received signals to generate a plurality of code multiplexed signals, and a combiner combines the plurality of code multiplexed signals into a combined signal. After other processing for signal reception, a code demultiplexer demultiplexes the combined baseband signal, and a complex correlator correlates unique pairs of baseband signals to generate a plurality of visibility products. Finally, the plurality of visibility products are transformed to generate an image. The concepts described herein may be relied upon to reconfigure or repurpose a phased-array receiver to achieve imaging.

The invention provides devices and systems, as well as associated methods of using them, that employ a remote Dicke switching elementi.e., distal to a radiometer. The devices, systems, and methods are suitable for both diagnostic and therapeutic applications in a wide variety of tissues.

Apparatuses and systems for determining a temperature of a targeted subject are disclosed. A temperature sensing system may include an antenna for sensing electromagnetic radiation (e.g., microwaves, etc.) emanating from the source. Based on that electromagnetic radiation, the antenna generates a temperature signal. A switch, which is located at or adjacent to an output of the antenna, receives the temperature signal, as well as a reference signal from a termination. The temperature signal and the reference signal are conveyed along a cable to a signal converter. Signal-altering events that affect the temperature signal as it is conveyed also affect the reference signal. Thus, any error caused by a signal-altering event automatically cancels out. The signal converter measures or otherwise processes the temperature signal and, since there is no need to correct for errors in the temperature signal, the reference signal, and accurately calculates the temperature of the source.

Disclosed is a remote observation system including: a radar for calculating a rain cloud profile; a GNSS for calculating total rain cloud profiles; a radiometer for calculating a light cloud profile; and a lidar for calculating an aerosol profile. The remote observation method according to the present invention includes: the first step of calculating a rain cloud profile by means of a radar; the second step of calculating total rain cloud profiles by means of a GNSS; the third step of calculating a light cloud profile by means of a radiometer; and the fourth step for calculating an aerosol profile by means of a lidar.

Radiometer for non-invasive measurement of internal tissue temperature of biological objects. The radiometer comprises, connected in series, antenna, SPDT switch, circulator, receiver including amplifier with bandpass filters, amplitude detector, narrowband low-frequency amplifier and synchronous detector, integrator, direct current power amplifier, reference voltage generator connected to the SPDT switch and synchronous detector. A Peltier element is connected to the receiver output. First and second microwave loads are installed on the Peltier element and have thermal contact with it. There is at least one temperature sensor for measuring the temperature of microwave loads. The first microwave load is adapted for connection to the SPDT switch. The SPDT switch is adapted to connect either, to a first arm of the circulator, the antenna, or the first microwave load. A second arm of the circulator is connected to the receiver, and a third arm of the circulator is connected to the second microwave load.