Emitter driver for noninvasive patient monitor
First Claim
Patent Images
1. A non-invasive physiological sensor configured to output one or more output signals indicative of one or more physiological conditions of a patient being monitored, the sensor comprising:
- a plurality of light emitting sources configured for transmitting optical radiation to a measurement site;
one or more detectors configured to output to a patient monitor said one or more output signals responsive to said optical radiation detected after attenuation by body tissue of said patient at said measurement site, said one or more output signals indicative of said one or more physiological conditions of said patient;
a plurality of switches configured for selectively connecting one or more of the light emitting sources to one or more drive signals; and
a decoder circuit comprising N input terminals and up to 2N output terminals, said decoder circuit configured to control the plurality of switches via the up to 2N output terminals and receive N input signals via the N input terminals, wherein N is greater than 2, said decoder circuit configured to implement an addressing system capable of selectively individually addressing 2N unique outputs based on the N input signals, said decoder circuit configured to activate an output terminal of the up to 2N output terminals based on the N input signals to cause one or more of said plurality of switches to connect at least one of said light emitting sources to transmit said optical radiation to said measurement site.
3 Assignments
0 Petitions
Accused Products
Abstract
Embodiments of the present disclosure include an emitter driver configured to be capable of addressing substantially 2N nodes with N cable conductors configured to carry activation instructions from a processor. In an embodiment, an address controller outputs an activation instruction to a latch decoder configured to supply switch controls to activate particular LEDs of a light source.
669 Citations
19 Claims
-
1. A non-invasive physiological sensor configured to output one or more output signals indicative of one or more physiological conditions of a patient being monitored, the sensor comprising:
-
a plurality of light emitting sources configured for transmitting optical radiation to a measurement site; one or more detectors configured to output to a patient monitor said one or more output signals responsive to said optical radiation detected after attenuation by body tissue of said patient at said measurement site, said one or more output signals indicative of said one or more physiological conditions of said patient; a plurality of switches configured for selectively connecting one or more of the light emitting sources to one or more drive signals; and a decoder circuit comprising N input terminals and up to 2N output terminals, said decoder circuit configured to control the plurality of switches via the up to 2N output terminals and receive N input signals via the N input terminals, wherein N is greater than 2, said decoder circuit configured to implement an addressing system capable of selectively individually addressing 2N unique outputs based on the N input signals, said decoder circuit configured to activate an output terminal of the up to 2N output terminals based on the N input signals to cause one or more of said plurality of switches to connect at least one of said light emitting sources to transmit said optical radiation to said measurement site. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8)
-
-
9. A method to selectively drive light emitting sources in a noninvasive optical physiological sensor configured to monitor parameters of a patient and communicate with a patient monitor, the method comprising:
-
attaching said sensor to said patient, said sensor including at least one different semiconductor switch in series with each of the light emitting sources; and activating said semiconductor switches to connect associated light emitting sources to a drive signal, the light emitting source transmitting optical radiation into a measurement site of said patient, and said activation comprises providing N conductors to N input terminals of a decoder having up to 2N output terminals, said decoder configured to implement an addressing system capable of selectively individually addressing 2N unique outputs based on N input signals received via the N input terminals, said decoder capable of controlling about 2N of the semiconductor switches to individually control the light emitting sources via the up to 2N output terminals based on the N input signals, wherein N is greater than 2.
-
-
10. A method of activating a non-invasive physiological sensor, the method comprising:
-
receiving N input signals at N inputs of a decoder circuit of said sensor where N is greater than 2, said decoder circuit having up to 2N outputs and configured to implement an addressing system capable of selectively individually addressing 2N unique outputs based on the N input signals; activating an output of the up to 2N outputs based on the N input signals to cause one or more of a plurality of switches to operably connect at least one of one or more light emitting sources to one or more drive signals, said operable connection causing said light emitting source to transmit optical radiation to a measurement site; and outputting from one or more detectors to a patient monitor one or more output signals responsive to said optical radiation detected after attenuation by body tissue of said patient at said measurement site, said one or more output signals indicative of said one or more physiological conditions of said patient. - View Dependent Claims (11, 12, 13)
-
-
14. An apparatus for monitoring a physiological parameter of a patient, the apparatus comprising:
a non-invasive physiological sensor configured to communicate with a patient monitor, the sensor comprising; a plurality of light emitting sources configured for transmitting optical radiation to a measurement site; one or more detectors configured to output to the patient monitor one or more output signals responsive to said optical radiation detected after attenuation by body tissue of said patient at said measurement site, said one or more output signals indicative of one or more physiological conditions of said patient; a plurality of switches configured for selectively connecting one or more of the light emitting sources to one or more drive signals; and a decoder circuit configured to control the plurality of switches and receive N input signals from the patient monitor, wherein the N input signals comprise a set of N bits received in parallel and N is greater than 2, said decoder circuit configured to implement an addressing system capable of selectively individually addressing 2N unique outputs based on the N input signals, said decoder circuit configured to activate a location including one or more of said plurality of switches based on the N input signals to cause at least one of said light emitting sources to transmit said optical radiation to said measurement site. - View Dependent Claims (15, 16, 17, 18, 19)
Specification