Patent application number | Description | Published |
20110077487 | Evaluation Kit For Medical Monitoring Module System and Method - An evaluation kit for monitoring, testing, and debugging a medical monitoring module is provided. The kit includes a hardware and software to provide for monitoring of communication between the medical monitoring module and a host or host simulator. The kit may provide for various system configurations having a sensor device, a computer having a protocol analyzer and a host simulator, a medical monitoring module, a software host, a medical monitor, or any combination thereof. | 03-31-2011 |
20110077488 | Evaluation Board For A Medical Monitoring Module System And Method - An evaluation board for a medical monitoring module is provided. The evaluation board includes a socket configured to receive a medical monitoring module and a plurality of connections for connection to a host or host simulator and a second device. The evaluation board may include a non-isolated power supply to provide power to the medical monitoring module. The evaluation board may also provide communication in a protocol between the host or host simulator and the medical monitoring module. | 03-31-2011 |
20110078596 | Protocol Analyzer System And Method For Medical Monitoring Module - A protocol analyzer and a host simulator for a medical monitoring module testing system are provided. The protocol analyzer may monitor communication in a first protocol from the medical monitoring module to a host or host simulator. The protocol analyzer may parse and display the messages of the first protocol on a display of a computer. The host simulator may receive data from the medical monitoring module and display data corresponding to a physiological parameter on the display. | 03-31-2011 |
20120029330 | Cable cross talk suppression - Systems, methods, and devices are provided for suppressing cross-talk noise due to capacitive and/or inductive coupling in a medical sensor signal. For example, an embodiment of a patient monitor may include driving circuitry, an amplifier, and transient current discharge circuitry. When the driving circuitry drives an emitter to emit light into a patient, a detector may detect a portion of the light that passes through the patient, generating a detector signal. Cross-talk between the emitter driving signals and the detector signal may generate interference in the form of a transient current in the detector signal. Before the amplifier receives the detector signal, transient current discharge circuitry may discharge the transient current. | 02-02-2012 |
20120136257 | SNR Through Ambient Light Cancellation - Systems, methods, and devices for improved patient monitor signal processing with higher signal-to-noise ratio (SNR) are provided. In accordance with an embodiment, an electronic patient monitor may include drive circuitry, a current-to-voltage converter, and feedback circuitry. The drive circuitry may drive an emitter of a medical sensor with dark periods during which the emitter does not emit light, and the current-to-voltage converter may receive and amplify a photocurrent signal from a detector of the sensor. The feedback circuitry may provide a feedback signal to the current-to-voltage converter. The feedback signal, based at least in part on the output of the current-to-voltage converter during the dark periods, may cause the current-to-voltage converter to substantially exclude an ambient light component of the photocurrent. As a result, the current-to-voltage converter may employ a higher transimpedance without distorting the output voltage signal due to oversaturation, and thus may achieve a higher SNR. | 05-31-2012 |
20120218404 | Medical Monitor Data Collection System And Method - A system and method for generating results indicative of physiological parameters of a patient and for capturing the results. The capture of the results may include recordation of the results through the use of a camera, while the physiological parameters may be generated through monitoring of a patient or by simulating such monitoring. | 08-30-2012 |
20130007083 | SYSTEMS AND METHODS FOR COMPUTING CONTINUOUS WAVELET TRANSFORM ON A DEDICATED INTEGRATED CIRCUIT - Methods and systems are disclosed for computing one or more continuous wavelet transforms on a dedicated integrated circuit. The systems comprise an integrated circuit having a receiver, memory, and processing circuitry. The receiver receives input data corresponding to an input signal. The memory stores information corresponding to one or more wavelet functions scaled over a set of scales. The processing circuitry is configured to compute, in-parallel, various portions of a single continuous wavelet transform of the input signal based on the received input data and the stored information corresponding to a single wavelet function computed over a set of scales. | 01-03-2013 |
20130134989 | CALIBRATION RESISTANCE EMULATOR - The present disclosure relates generally to patient monitoring systems and, more particularly, to a resistance emulator for patient monitors. In an embodiment, a resistance emulator includes a first plug configured to couple with a medical monitor. The medical monitor is configured to receive a calibration resistance value of a medical device sensor from a coded resistor. The resistance emulator further includes a second plug configured to couple with a medical device sensor. The medical device sensor is configured without the coded resistor. The resistance emulator also includes emulation circuitry configured to provide an emulated signal representative of the calibration resistance value to the medical monitor. | 05-30-2013 |
20140187992 | SYSTEM AND METHOD FOR NON-INVASIVELY DETERMINING CARDIAC OUTPUT - A system for non-invasively determining cardiac output of a patient may include a physiological signal detection unit and a cardiac output determination module. The physiological signal detection unit may be configured to detect first and second physiological signals with respect to first and second locations of vasculature of the patient. The cardiac output determination module may be configured to receive the first and second physiological signals and calculate the cardiac output of the patient based, at least in part, on a phase difference between the first and second physiological signals. | 07-03-2014 |