Manual and automatic probe calibration
First Claim
1. A sensor used in an oximeter system for monitoring oxygen level in blood of a patient, the sensor comprising:
- at least one light emitting diode configured to transmit light energy through human tissue carrying the blood, wherein the blood attenuates the light energy;
a photodetector configured to detect the attenuated light energy; and
an information element configured to indicate a characteristic of the patient, wherein the information element is electrically coupled in parallel with the at least one light emitting diode.
6 Assignments
0 Petitions
Accused Products
Abstract
The method and apparatus of the present invention provides a system wherein light-emitting diodes (LEDs) can be tuned within a given range by selecting their operating drive current in order to obtain a precise wavelength. The present invention further provides a manner in which to calibrate and utilize an LED probe, such that the shift in wavelength for a known change in drive current is a known quantity. In general, the principle of wavelength shift for current drive changes for LEDs is utilized in order to allow better calibration and added flexibility in the use of LED sensors, particularly in applications when the precise wavelength is needed in order to obtain accurate measurements. The present invention also provides a system in which it is not necessary to know precise wavelengths of LEDs where precise wavelengths were needed in the past. Finally, the present invention provides a method and apparatus for determining the operating wavelength of a light emitting element such as a light emitting diode.
1204 Citations
17 Claims
-
1. A sensor used in an oximeter system for monitoring oxygen level in blood of a patient, the sensor comprising:
-
at least one light emitting diode configured to transmit light energy through human tissue carrying the blood, wherein the blood attenuates the light energy;
a photodetector configured to detect the attenuated light energy; and
an information element configured to indicate a characteristic of the patient, wherein the information element is electrically coupled in parallel with the at least one light emitting diode. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8)
-
-
9. A medical probe for non-invasive monitoring of a constituent in blood, said medical probe comprising:
-
a light emitter configured to transmit light of a selected wavelength, wherein said light is attenuated after traveling through a medium with blood flow;
a detector configured to receive said attenuated light; and
an information element electrically coupled to said light emitter and configured to indicate a patient type. - View Dependent Claims (10, 11, 12, 13)
-
-
14. A medical probe for non-invasive monitoring of a constituent in blood, said medical probe comprising:
-
a light emitter configured to transmit light of a selected wavelength, wherein said light is attenuated after traveling through a medium with blood flow and the selected wavelength of the light emitter changes to monitor a different constituent;
a detector configured to receive said attenuated light; and
an information element electrically coupled to said light emitter and configured to indicate a patient type.
-
-
15. A probe for medical monitoring of a patient, the probe comprising:
-
a light emitting diode configured to receive a drive signal and to generate light energy for transmission through a fleshy medium of the patient;
a photodetector configured to receive the light energy attenuated by the transmission through the fleshy medium and to generate an output signal corresponding to intensity of the attenuated light energy; and
an indicator configured to communicate a characteristic of the patient, wherein the indicator is electrically coupled in parallel with the light emitting diode. - View Dependent Claims (16)
-
-
17. A probe for medical monitoring of a patient, the probe comprising:
-
a light emitting diode configured to receive a drive signal and to generate light energy for transmission through a fleshy medium of the patient;
a photodetector configured to receive the light energy attenuated by the transmission through the fleshy medium and to generate an output signal corresponding to intensity of the attenuated light energy; and
an indicator configured to communicate a characteristic of the patient, wherein the indicator is electrically coupled in parallel with the light emitting diode, and the drive signal operates at a relatively high frequency, and the indicator communicates at a relatively low frequency.
-
Specification