Use of frequency division multiplexing for optical cardiac signals

What is claimed is: 1 . An electronic wearable device comprising: a housing including a bottom wall configured to contact a user's skin; a first modulator configured to output a first modulated electronic signal having a first carrier frequency; a second modulator configured to output a second modulated electronic signal having a second carrier frequency; a first optical transmitter coupled with the first modulator, positioned on the bottom wall and configured to output a first optical signal based on the first modulated electronic signal, the first optical signal output into the user's skin and having the first carrier frequency; a second optical transmitter coupled with the second modulator, positioned on the bottom wall and configured to output a second optical signal based on the second modulated electronic signal, the second optical signal output into the user's skin and having the second carrier frequency; an optical receiver positioned on the bottom wall and configured to receive the first optical signal and the second optical signal from the user's skin as a broadband electronic signal including the first optical signal and the second optical signal associated with the first carrier frequency and the second carrier frequency, respectively, and output the broadband electronic signal; a first receive processor circuit configured to receive the broadband electronic signal including the first optical signal having the first carrier frequency and output a first photoplethysmogram (PPG) electronic signal corresponding to the first optical signal based on the first carrier frequency; and a second receive processor circuit configured to receive the broadband electronic signal including the second optical signal having the second carrier frequency and output a second PPG electronic signal corresponding to the second optical signal based on the second carrier frequency. 2 . The electronic wearable device of claim 1 , wherein the broadband electronic signal includes the first carrier frequency and the second carrier frequency as frequency components. 3 . The electronic wearable device of claim 2 , wherein the first receive processor circuit is electrically coupled with the optical receiver and includes a first filter configured to receive the broadband electronic signal, perform a band pass function based on the first carrier frequency, and output a first filtered electronic signal having the first carrier frequency. 4 . The electronic wearable device of claim 3 , wherein the first receive processor circuit includes a first demodulator configured to receive the first filtered electronic signal, extract the amplitude of the first carrier frequency, and output the first PPG electronic signal. 5 . The electronic wearable device of claim 2 , wherein the second receive processor circuit is electrically coupled with the optical receiver and includes a second band pass filter configured to receive the broadband electronic signal, perform a band pass function based on the second carrier frequency, and output a second filtered electronic signal having the second carrier frequency. 6 . The electronic wearable device of claim 5 , wherein the second receive processor circuit includes a second demodulator configured to receive the second filtered electronic signal, extract the amplitude of the second carrier frequency, and output the second PPG electronic signal. 7 . The electronic wearable device of claim 1 , wherein the first modulator and the second modulator each include a transconductance amplifier, wherein the first optical transmitter and the second optical transmitter are each a light-emitting diode (LED), and wherein the optical receiver is a photodiode. 8 . The electronic wearable device of claim 1 , wherein the first optical transmitter and the second optical transmitter are positioned at a first location on the bottom wall, and wherein the optical receiver is positioned at a second location on the bottom wall. 9 . The electronic wearable device of claim 1 , wherein the first receive processor circuit includes a first analog to digital converter configured to receive the first PPG electronic signal and output the first PPG electronic signal as a stream of digital data values that represent a PPG waveform, and wherein the second receive processor circuit includes a second analog to digital converter configured to receive the second PPG electronic signal and output the second PPG electronic signal as a stream of digital data values that represent a PPG waveform. 10 . The electronic wearable device of claim 1 , wherein the first optical transmitter is positioned at a first location on the bottom wall, wherein the second optical transmitter is positioned at a second location on the bottom wall, and wherein the optical receiver is positioned at a third location on the bottom wall. 11 . An electronic wearable device comprising: a housing including a bottom wall configured to contact a user's skin; a plurality of modulators, each modulator configured to output one of a plurality of modulated electronic signals, each modulated electronic signal having a predetermined carrier frequency; a plurality of optical transmitters positioned on the bottom wall and configured to output a plurality of optical signals, each optical transmitter coupled with one of the plurality of modulators and configured to receive one of the modulated electronic signals and output an optical signal into a user's skin that corresponds to the carrier frequency of the modulated electronic signal; an optical receiver positioned on the bottom wall and configured to receive the plurality of optical signals from the user's skin as a broadband electronic signal including optical signals associated with at least two carrier frequencies, and output the broadband electronic signal; and a plurality of receive processor circuits, each receive processor circuit and configured to receive the broadband electronic signal and output one of a plurality of photoplethysmogram (PPG) electronic signals corresponding to the one of the plurality of optical signals. 12 . The electronic wearable device of claim 11 , wherein each receive processor circuit is electrically coupled with the optical receiver and includes: a filter configured to output a filtered electronic signal corresponding to one of the plurality of carrier frequencies, and a demodulator configured to receive the filtered electronic signal and output one of the plurality of PPG electronic signals. 13 . The electronic wearable device of claim 12 , wherein at least two of the plurality of optical transmitters are positioned at a first location on the bottom wall, and wherein the optical receiver is positioned at a second location on the bottom wall. 14 . The electronic wearable device of claim 11 , wherein a first of the plurality of optical transmitters is positioned at a first location on the bottom wall, wherein a second of the plurality of optical transmitters is positioned at a second location on the bottom wall, and wherein the optical receiver is positioned at a third location on the bottom wall. 15 . The electronic wearable device of claim 11 , wherein each modulator includes a transconductance amplifier, wherein each of the plurality of optical transmitter is a light-emitting diode (LED), and wherein the of the plurality of optical receivers is a photodiode configured to receive the optical signals and output the broadband electronic signal having frequencies that include the carrier frequencies. 16 . An electronic wearable device comprising: a housing incl