Non-invasive optical physiological differential pathlength sensor

1 . A physiological measurement system based on optical transmission spectroscopy comprising: an emitter configured to emit light at a wavelength; a first detector set at a shorter transmission path configured to detect a first beam of transmitted light, the detected light being attenuated by a sample tissue, the first detector further configured to output a first signal responsive to the detected light of the first beam; a second detector fixed at a second, longer transmission path configured to detect a second beam of transmitted light and to output a second signal responsive to the detected light of the second beam; and a processor configured to receive signals responsive to the first and second signals to determine a bulk absorbance of an analyte in the sample tissue. 2 . The optical physiological measurement system of claim 1 , further comprising a first thermal controller, thermally coupled to the emitter, the first thermal controller configured to regulate a temperature of the emitter. 3 . The optical physiological measurement system of claim 2 , wherein the first thermal controller comprises a temperature sensor, a thermoelectric cooler, and a heat sink. 4 . The optical physiological measurement system of claim 2 , wherein the first thermal controller is further configured to modulate the temperature of the emitter to cause the emitter to emit light comprising a range of wavelengths. 5 . The optical physiological measurement system of claim 4 , wherein the thermal controller further comprises a thermoelectric cooler. 6 . The optical physiological measurement system of claim 5 , wherein the thermoelectric cooler comprises a Peltier device. 7 . The optical physiological measurement system of claim 2 , wherein the emitter further comprises an operational temperature and wherein the first thermal controller is further configured to cause a change to the emitter's operational temperature. 8 . The optical physiological measurement system of claim 1 , wherein the second detector is optically shielded. 9 . The optical physiological measurement system of claim 1 , comprising a second thermal controller, thermally coupled to the first detector, configured to control the temperature of the first detector. 10 . The optical physiological measurement system of claim 9 , comprising a third thermal controller, thermally coupled to the second detector, configured to control the temperature of the second detector. 11 . The optical physiological measurement system of claim 1 , wherein the analyte is at least one of glucose, water content, and hydration. 12 . (canceled) 13 . The optical physiological measurement system of claim 10 , further comprising a fourth thermal controller, thermally coupled to the sample tissue, the fourth thermal controller configured to measure a temperature of the sample tissue. 14 . The optical physiological measurement system of claim 13 , wherein the fourth thermal controller is further configured to regulate the temperature of the sample tissue. 15 . The optical physiological measurement system of claim 1 , wherein the emitter is further configured to receive a drive signal, and wherein the processor is further configured to control the drive signal delivered to the emitter. 16 . The optical physiological measurement system of claim 15 , wherein the drive signal further comprises a drive current and a duty cycle, and wherein the processor is further configured to control and vary the drive current and/or the duty cycle. 17 . The optical physiological measurement system of claim 1 , further comprising an emitter that has an emission area between 1 mm-10 mm diameter. 18 . The optical physiological measurement system of claim 1 , wherein a difference in distance between the emitter and the first detector and the emitter and the second detector is 0.2 mm to 1 mm. 19 .- 66 . (canceled) 67 . A method of varying light emitted in a physiological optical sensor, the method comprising: determining a temperature, a drive current, a forward voltage, and a duty cycle of a light emitter that emits light at a first wavelength at a first time; measuring a first indication of a physiological parameter; altering at least one of the determined temperature, drive current, forward voltage, and duty cycle of the emitter at a second time to cause the emitter to emit light at a second wavelength; and measuring a second indication of a physiological parameter. 68 . The method of claim 67 , wherein altering the determined temperature of the emitter comprises using a circuitry-based temperature alteration device or a thermal controller. 69 . (canceled) 70 . The method of claim 68 , wherein the circuitry-based temperature alteration device or the thermal controller comprises a Peltier device. 71 . (canceled) 72 .- 86 . (canceled)