Pulse oximeter with adaptive power conservation

What is claimed is: 1. A method for measuring oxygen saturation of a patient's blood comprising: operating a pulse oximeter in a high power mode, the pulse oximeter utilizing a sensor configured to generate data indicative of the oxygen saturation of the patient's blood; comparing, via a processor of the pulse oximeter, the data generated by the pulse oximeter to a plurality of predefined data profiles that includes a first data profile associated with a moving patient and a second data profile associated with an improperly positioned pulse oximeter on the patient; detecting, via the processor, that the data matches the first data profile or the second data profile; selecting, via the processor, a low power mode from a plurality of different low power modes that consume comparatively less power than the high power mode, wherein a first low power mode of the plurality of different low power modes is selected when the data matches the first data profile and a second low power mode of the plurality of different low power modes that is different from the first low power mode is selected when the data matches the second data profile; switching, via the processor, the pulse oximeter from the high power mode to the selected first low power mode or second low power mode for a first time interval; monitoring, via the processor, the oxygen saturation of the patient's blood while the pulse oximeter is in the selected first low power mode or second low power mode; and after the first time interval, returning, via the processor, the pulse oximeter to the high power mode. 2. The method of claim 1 , wherein detecting that the data matches the first data profile or the second data profile comprises determining from the data that patient movement or an improperly positioned pulse oximeter, respectively, is affecting the characteristics of the data generated by the pulse oximeter in the high power mode. 3. The method of claim 1 , wherein a third data profile is associated with a patient with a stable pulse and stable oxygen saturation and determining comprises: determining from the data that the oxygen saturation of the patient's blood has been within a predetermined range for a time interval; and identifying the data as matching the second data profile. 4. The method of claim 1 , wherein determining comprises: determining, based at least in part upon the data, that the sensor is not installed on the patient. 5. The method of claim 1 , wherein each of the plurality of predefined data profiles is associated with a different low power mode of the plurality of different low power modes and selecting comprises: identifying the low power mode of the plurality of different low power modes associated with the at least one predefined data profile matching the data. 6. The method of claim 1 , wherein the plurality of predefined data profiles comprises a third data profile associated with a pulse oximeter that is used in conjunction with an electrocardiograph monitoring the patient. 7. The method of claim 1 , wherein: the first low power mode comprises reducing a number of samples taken within a period of time, reducing a signal-to-noise ratio of data generated by the pulse oximeter, using a different data processing algorithm than that used in the high power mode, causing the pulse oximeter to obtain data from only one of a plurality of light sources in the sensor, and reducing a sampling resolution of the data generated by the pulse oximeter; and the second low power mode comprises at least one of reducing a number of samples taken within a period of time, reducing a signal-to-noise ratio of data generated by the pulse oximeter, using a different data processing algorithm than that used in the high power mode, causing the pulse oximeter to obtain data from only one of a plurality of light sources in the sensor, and reducing a sampling resolution of the data generated by the pulse oximeter that is different from the first low power mode. 8. A pulse oximeter for determining oxygen saturation in a patient's blood comprising: a high power mode of operation; and a power conservation engine comprising a memory and a processor configured to execute instructions stored on the memory to compare data generated by the pulse oximeter to a plurality of data profiles and based at least in part upon determination that the data generated by the pulse oximeter matches at least one of the plurality of data profiles, to switch the pulse oximeter into one of a plurality of different low power modes of operation based at least in part upon the data profile matching the data generated by the pulse oximeter, wherein the plurality of data profiles comprises a first data profile associated with a moving patient and a second data profile associated with an improperly positioned pulse oximeter, wherein the power conservation engine switches the pulse oximeter to a first low power mode of the plurality of low power modes when the data profile matches the first data profile and switches the pulse oximeter to a second low power mode of the plurality of low power modes different from the first low power mode when the data profile matches the second data profile, and wherein the pulse oximeter monitors and records additional data while in the at least one of the plurality of different low power modes. 9. The pulse oximeter of claim 8 , wherein the plurality of data profiles comprises a third data profile associated with a patient with a stable pulse and stable oxygen saturation. 10. The pulse oximeter of claim 8 , wherein the plurality of data profiles comprises a fourth data profile associated with a pulse oximeter that is used in conjunction with an electrocardiograph monitoring the patient. 11. The pulse oximeter of claim 8 , wherein the first or second low power reduce a number of oxygen saturation samples taken within a period of time in comparison with the high power mode. 12. The pulse oximeter of claim 8 , wherein the first or the second low power mode reduces a signal-to-noise ratio of oxygen saturation data generated by the pulse oximeter. 13. The pulse oximeter of claim 8 , wherein the first or the second low power mode uses a different data processing algorithm to determine oxygen saturation from the data than that used in the high power mode. 14. The pulse oximeter of claim 8 , wherein the first or the second low power mode causes the pulse oximeter to use data from only one of a plurality of light sources in the pulse oximeter. 15. The pulse oximeter of claim 14 , wherein the first or the second low power mode causes the pulse oximeter to generate data from one of a plurality of light sources in the pulse oximeter. 16. The pulse oximeter of claim 8 , wherein the first or the second low power mode reduces a sampling resolution of the oxygen saturation data generated by the pulse oximeter. 17. The pulse oximeter of claim 8 , wherein the power conservation engine is configured to receive a command from a user and to select one of the plurality of different low power modes based at least in part on the command from the user. 18. A pulse oximeter comprising: a power conservation engine comprising a memory and a processor configured to execute instructions stored on the memory to: compare data generated by the pulse oximeter to a plurality of data profiles, wherein each of the plurality of data profiles is associated with one of a plurality of different low power modes; and based at least in part upon determination that the data generated by the pulse oximeter matches at least one of the plurali