Urine collection systems and associated methods and devices are disclosed herein. A representative system can include a urine collection device, a flow control assembly configured to direct a urine flow from the patient to the urine collection device, and a urine measurement device including a first sensor and a second sensor. The first sensor is configured to generate first sensor data based on a weight of the container, and the second sensor is configured to generate second sensor data based on the urine flow from the patient to the container. The system can further include non-transitory computer readable media having instructions that, when executed by one or more processors, cause the system to perform operations comprising determining a first patient urine output based on the first sensor data; and determining a second patient urine output based on the second sensor data.

Methods of performing diagnostic tests on electroencephalography (EEG) recording devices comprising at least one stimulator coupled with a plurality of EEG electrode recording channels and corresponding recording channel connectors are performed by a test fixture comprising a plurality of resistors coupled with one or more of the EEG electrode recording channels and corresponding recording channel connectors. The methods include performing an impedance test for determining if each EEG recording channel of the EEG recording device has a predefined impedance, performing a channel uniqueness test for each EEG recording channel, performing a test for verifying the state of a switch of the stimulator of the EEG recording device, and performing a test for verifying connector IDs of the recording channel connectors connecting the EEG electrodes to respective EEG recording channels.

The present technology relates to intracardiac sensors and associated systems and methods. In some embodiments, the present technology includes a device for monitoring pressure within a patient's heart. The device can include an implantable capacitor having a capacitance value that is variable based on the pressure within the patients heart and a sensing circuit configured to measure the capacitance value. The device can also include an implantable inductor and a power circuit configured to wirelessly receive power from an external source via the inductor. When the device is in a first configuration, the capacitor can be electrically coupled to the sensing circuit and the inductor can be electrically coupled to the power circuit. When the device is in a second configuration, the capacitor can be electrically coupled to the inductor to form a resonant circuit.

A patch configured for being applied to a patients skin, said patch comprising a contact area configured for being in direct contact with the patients skin when applied thereto, and a detector configured for detecting contact between the contact area and the patients skin.

Mitigating a user interface display function of a modular energy system includes receiving formatted video data at a video data converter circuit, providing differential video signaling data to the display from the video data converter circuit, providing a copy of the differential video signaling data to a processor, and determining that the differential video signaling data is changing over time. Mitigating erroneous outputs from an isolated interface includes receiving a state of a first switch of a first footswitch coupled to a first comparator and a reference voltage coupled to the first comparator, receiving the state of the first switch coupled to the first duplicate comparator and the reference voltage coupled to the first duplicate comparator, comparing the output of the first comparator with the output of the first duplicate comparator, and determining activation or deactivation of a surgical instrument coupled to the controller based on the comparison.

Provided is a method, a system, a wearable device, and a medium for measuring a physiological signal. The method includes acquiring the physiological signal of a user, and controlling a haptic feedback device to activate to generate and output a haptic feedback signal in response to the physiological signal and starting a first timer simultaneously. When the time duration of the first timer is greater than a first time threshold, the first timer is stopped, the haptic feedback device is controlled to be disactivated, and a measuring result is output.

An embodiment of the present disclosure discloses a device including a housing and a biometric sensor, the biometric sensor is configured to sense whether a first part of a human body is in contact with a first electrode and a second electrode, detect whether a second part of the human body is in contact with a third electrode and a fourth electrode, obtain phase information of the impedance of the human body by using the first, second, third and fourth electrodes, determine whether the acquired phase information of the impedance is within a designated range, and provide a guide for a measurement method when the acquired phase information of the impedance deviates from the designated range. Various other embodiments identified through the specification are possible.

A surgical robotic testing unit for testing a surgical robotic system, the surgical robotic system comprising a first subsystem configured to generate a first signal having a first characteristic behaviour and a second subsystem configured to receive the first signal and to respond to the received first signal, the testing unit being configured to: emulate the first subsystem by: generating an emulated signal representative of the first signal of the first subsystem, the emulated signal having an emulated behaviour that exceeds a boundary of the first characteristic behaviour of the first signal, such that the testing unit is operable to test the second subsystem beyond the capability of the first subsystem; transmitting the generated emulated signal for receiving at the second subsystem; and receiving a response signal from the second subsystem indicative of the response of the second subsystem to the emulated signal; analyse the received response signal; and determine a state of the second subsystem based on the analysis.

The present technology relates to intracardiac sensors and associated systems and methods. In some embodiments, the present technology includes a device for monitoring pressure within a patient's heart. The device can include an implantable capacitor having a capacitance value that is variable based on the pressure within the patient's heart and a sensing circuit configured to measure the capacitance value. The device can also include an implantable inductor and a power circuit configured to wirelessly receive power from an external source via the inductor. When the device is in a first configuration, the capacitor can be electrically coupled to the sensing circuit and the inductor can be electrically coupled to the power circuit. When the device is in a second configuration, the capacitor can be electrically coupled to the inductor to form a resonant circuit.

The present invention relates generally to systems and methods for measuring an analyte in a host. More particularly, the present invention relates to systems and methods for transcutaneous measurement of glucose in a host.