System and method for voice control of medical devices
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
A61B-005/00
H01S-003/30
A61B-005/1455
A61B-005/02
A61B-005/021
A61B-005/024
A61B-005/06
A61B-001/00
출원번호
US-0186814
(2014-02-21)
등록번호
US-9456750
(2016-10-04)
발명자
/ 주소
Islam, Mohammed N.
출원인 / 주소
Omni Medsci, Inc.
대리인 / 주소
Brooks Kushman P.C.
인용정보
피인용 횟수 :
0인용 특허 :
160
초록▼
A diagnostic system includes sensors with at least one being a diagnostic device comprising one or more solid state light sources used in a measurement. A software application capable of generating physiological information based on the sensors is operable on a control system adapted to receive, sto
A diagnostic system includes sensors with at least one being a diagnostic device comprising one or more solid state light sources used in a measurement. A software application capable of generating physiological information based on the sensors is operable on a control system adapted to receive, store and process the physiological information. The control system includes a touch-screen, circuitry for obtaining position information from a location sensor, and a wireless transceiver to transmit wireless data including the physiological information over a wireless link and is further capable of receiving voice and manually entered input signals. A host includes a digital file for receiving and storing the wireless data, control logic to process the wireless data to generate a status of the user, memory for recording the status, and an output for communicating the status or associated information over a communication link to display output devices located remotely from the host.
대표청구항▼
1. A diagnostic system comprising: one or more solid state light sources adapted to be used in obtaining a physiological measurement from a user and to generate a first input signal;a software applicationconfigured to operate on a control system adapted to receive and process physiological informati
1. A diagnostic system comprising: one or more solid state light sources adapted to be used in obtaining a physiological measurement from a user and to generate a first input signal;a software applicationconfigured to operate on a control system adapted to receive and process physiological information associated with the user, the control system comprising a touch-screen, a proximity sensor, circuitry for obtaining movement information from a positioning sensor, a mechanical system comprising one or more actuators, and a wireless transmitter to transmit data over a wireless link to a host, the software application operable to generate the physiological information based at least in part on the first input signal, at least some of the physiological information comprising at least a part of the data, wherein the control system is further capable of receiving a voice input signal and a manually entered second input signal; andthe host to generate a status of the user from the data comprising:a memory storage device for recording the status; anda communication device for communicating at least a portion of the status over a communication link to one or more display output devices, wherein the one or more display output devices are located remotely from the host. 2. The diagnostic system of claim 1, wherein the one or more solid state light sources generate a plurality of wavelengths operating in a pulsed mode, and the physiological measurement further comprises a comparison of two or more of the plurality of wavelengths transmitted or reflected from the user. 3. The diagnostic system of claim 1, wherein at least a portion of the data comprises information representing movement in position of the user. 4. The diagnostic system of claim 1, wherein the host includes voice recognition software to process at least a portion of the voice input signal. 5. The diagnostic system of claim 1, wherein the physiological information is blood pressure, heart rate, blood oxygen level, bleeding or proximity to a tissue associated with the user. 6. The diagnostic system of claim 1, wherein the control system is further coupled to an audio output device capable of communicating at least a part of the processed physiological information. 7. A diagnostic system comprising: one or more sensors configured to generate an input signal, wherein at least one of the one or more sensors is adapted to be coupled to a tissue comprising blood;a software application configured to operate on a control system adapted to receive and process sensor data, the control system having a touch-screen, a proximity sensor, circuitry for obtaining movement information from a positioning sensor, a mechanical system comprising one or more actuators, and a wireless transmitter to transmit data over a wireless link to a host, the software application operable to generate the sensor data based at least in part on the input signal received from the one or more sensors, wherein the sensor data comprises information representing a movement in position associated with a user sensed by at least one of the one or more sensors, at least some of the sensor data comprising at least a part of the data, wherein the control system is further capable of receiving a voice input signal and a manually entered second input signal; andthe host to generate a status of the user from the data comprising:a memory storage device for recording the status; anda communication device for communicating at least a portion of the status over a communication link to one or more display output devices, wherein the one or more display output devices are located remotely from the host. 8. The diagnostic system of claim 7, wherein the system comprises one or more solid state light sources that are adapted to be used to obtain a physiological measurement from the user. 9. The diagnostic system of claim 7, wherein the system comprises one or more solid state light sources that generate a plurality of wavelengths operating in a pulsed mode and wherein a comparison of two or more of the plurality of wavelengths can be used to obtain a physiological measurement from the user. 10. The diagnostic system of claim 7, wherein the host includes voice recognition software to process at least a portion of the voice input signal. 11. A diagnostic system comprising: one or more sensors configured to generate an input signal comprising at least in part physiological information associated with a user, wherein the physiological information includes heart rate or blood oxygen level;a softwareconfigured to operate on a control system adapted to receive and process sensor data, the control system comprising a touch-screen, a proximity sensor, a mechanical system comprising one or more actuators, and a wireless transmitter to transmit data over a wireless link to a host, the software application operable to generate the sensor data based at least in part on the input signal received from the one or more sensors, wherein the sensor data represents at least in part information based on a movement in position of one or more of the sensors and at least in part some of the physiological information associated with the user, at least some of the sensor data comprising at least a part of the data, and wherein the control system is further capable of receiving a voice input signal and a manually entered second input signal; andthe host to generate a status of the user from the data comprising: a memory storage device for recording the status; anda communication device for communicating at least a portion of the status over a communication link to one or more display output devices, wherein the one or more display output devices are located remotely from the host. 12. The diagnostic system of claim 11, wherein the system comprises one or more solid state light sources that are adapted to be used in obtaining a physiological measurement from the user. 13. The diagnostic system of claim 11, wherein the system comprises one or more solid state light sources configured to generate a plurality of wavelengths operating in a pulsed mode and to perform a measurement comprising a comparison of two or more of the plurality of wavelengths. 14. The diagnostic system of claim 11, wherein the control system is further coupled to a headset or a heads-up display, and wherein gesture signals are capable of being generated in response to a head motion. 15. The diagnostic system of claim 11, wherein the host includes voice recognition software to process at least a portion of the voice input signal. 16. The diagnostic system of claim 11, wherein the host is adapted to permit access of the status stored on the host from two or more different locations remote from the host. 17. A method of processing physiological information, the method comprising: providing a software application operable to generate data based at least in part on an input signal generated by one or more solid state light sources, wherein the one or more solid state light sources are adapted to be used in obtaining physiological information from a user, wherein the data represents at least in part the physiological information, and wherein the software application is configured to operate on a control system comprising a touch-screen, a proximity sensor, circuitry for obtaining movement information from a positioning sensor, a mechanical system comprising one or more actuators, and a transmitter operable to wirelessly transmit data over a wireless link to a host, at least some of the physiological information comprising at least a part of the wirelessly transmitted data, wherein the control system is further configured to receive a voice input signal and a manually entered second input signal;receiving at least a portion of the wirelessly transmitted data at the host;processing at the host at least a portion of the physiological information contained in the wirelessly received data to generate status information;recording the status information within a memory storage device accessible by the host; andcommunicating at least a portion of the status information over a communication link to one or more display output devices, wherein the one or more display output devices are located remotely from the host. 18. The method of claim 17, further comprising generating a plurality of wavelengths from the one or more solid state light sources operating in a pulsed mode, and obtaining the physiological information based on a comparison of two or more of the plurality of wavelengths. 19. A method of processing physiological data, the method comprising: providing a software application operable to generate physiological data based at least in part on a first input signal generated by one or more sensors, wherein at least one of the one or more sensors is adapted to be coupled to a tissue comprising blood, and wherein the data comprises information representing a movement in position associated with a user sensed by at least one of the one or more sensors, and wherein the software application is configured to operate on a control system comprising a touch-screen, a proximity sensor, a mechanical system comprising one or more actuators, and a transmitter operable to wirelessly transmit data over a wireless link to a host, at least some of the physiological data comprising at least a part of the data, wherein the control system is further configured to receive a voice input signal and a manually entered second input signal;receiving at least a portion of the wirelessly transmitted data at the host;processing at the host at least a portion of the physiological data contained in the wirelessly received data to generate status information;recording the status information within a memory storage device accessible by the host; andcommunicating at least a portion of the status information over a communication link to one or more display output devices, wherein the one or more display output devices are located remotely from the host. 20. The method of claim 19, further comprising generating an input light beam from one or more semiconductor diodes and communicating at least a portion of the input light beam onto the tissue comprising blood using a lens system. 21. A method of processing physiological information, the method comprising: providing a software application operable to generate physiological data based at least in part on an input signal generated by one or more sensors, wherein the physiological data comprises at least in part physiological information and at least in part information representing a movement in position of one or more of the sensors, wherein the physiological information includes heart rate or blood oxygen level, and wherein the software application is configured to operate on a control system comprising a touch-screen, a proximity sensor, circuitry for obtaining movement information from a positioning sensor, a mechanical system comprising one or more actuators, and a transmitter operable to wirelessly transmit data over a wireless link to a host, at least some of the physiological information comprising at least a part of the wirelessly transmitted data, wherein the control system is further configured to receive voice input signals and manually entered input signals;receiving at least a portion of the wirelessly transmitted data at the host;processing at the host at least a portion of the physiological information contained in the wirelessly received data to generate status information;recording the status information within a memory storage device accessible by the host; andcommunicating at least a portion of the status information over a communication link to one or more display output devices, wherein the one or more display output devices are located remotely from the host. 22. The method of claim 21, further comprising generating an input light beam from one or more semiconductor diodes and communicating at least a portion of the input light beam onto a tissue comprising blood using a lens system.
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