Electronic device with optical heart rate monitor

What is claimed is: 1. An electronic fitness device comprising: a housing including a bottom wall configured to contact a user's wrist; a first optical transmitter array positioned at a first location on the bottom wall and operable to output a plurality of optical signals that pass through a user's skin, each optical signal having a unique wavelength; a first optical receiver positioned at a second location on the bottom wall and operable to receive the optical signals from the first optical transmitter array such that the optical signals travel along a first signal path and a first distance from the first optical transmitter array to the first optical receiver; and a second optical receiver positioned at a third location on the bottom wall and operable to receive the optical signals from the first optical transmitter array such that the optical signals travel along a second signal path and a second distance from the first optical transmitter array to the second optical receiver, wherein the second signal path is roughly orthogonal to the first signal path and the second distance is different from the first distance; wherein the first optical receiver is spaced apart from the first optical transmitter array along a first axis, and the second optical receiver is spaced apart from the first optical transmitter array along a second axis, the second axis orthogonal to the first axis, on the bottom wall. 2. The electronic fitness device of claim 1 , wherein each optical receiver is operable to generate an electronic signal corresponding to the plurality of optical signals output by the first optical transmitter array. 3. The electronic fitness device of claim 2 , wherein the electronic fitness device further comprises: a memory element configured to store a signal to noise ratio threshold; and a processing element coupled with the memory element and each of the optical receivers, the processing element configured to: receive the electronic signals from each of the optical receivers, determine a signal to noise ratio of each electronic signal, process the electronic signals having a determined signal to noise ratio is above the signal to noise threshold. 4. The electronic fitness device of claim 1 , wherein the first optical receiver and the second optical receiver each have an elongated aspect ratio. 5. The electronic fitness device of claim 1 , further comprising a second optical transmitter array positioned at a fourth location on the bottom wall and operable to output a plurality of optical signals that pass through the user's skin, each optical signal having a wavelength equal to a wavelength of a corresponding optical signal of the first optical transmitter array, wherein the first optical transmitter array and the second optical transmitter array are spaced apart from one another along the first axis and along the second axis on the bottom wall. 6. The electronic fitness device of claim 5 , further comprising a third optical receiver positioned at a fifth location on the bottom wall and operable to receive the optical signals from the first optical transmitter array and the second optical transmitter array, the third optical receiver spaced apart from the first optical receiver with the first optical transmitter array and the second optical transmitter array positioned therebetween, and a fourth optical receiver positioned at a sixth location on the bottom wall and operable to receive the optical signals from the first optical transmitter array and the second optical transmitter array, the fourth optical receiver spaced apart from the second optical receiver with the first optical transmitter array and the second optical transmitter array positioned therebetween. 7. The electronic fitness device of claim 6 , wherein the third optical receiver and the fourth optical receiver each have an elongated aspect ratio, and wherein the third optical receiver is oriented longitudinally along the first axis and the fourth optical receiver is oriented along the second axis on the bottom wall. 8. The electronic fitness device of claim 6 , further comprising: a first lens covering the first optical transmitter array and configured to direct optical signals to the skin of the user, a second lens covering the second optical transmitter array and configured to direct optical signals to the skin of the user, and third, fourth, fifth, and sixth lenses, each lens covering a corresponding optical receiver and configured to direct optical signals exiting from the skin onto the associated optical receiver. 9. The electronic fitness device of claim 5 , further comprising a third optical transmitter array positioned at a fifth location on the bottom wall approximately midway between the first optical transmitter array and the second optical transmitter array along the first axis and along the second axis, and operable to output a plurality of optical signals that pass through the user's skin, each optical signal having a wavelength equal to a wavelength of a corresponding optical signal of the first optical transmitter array. 10. An electronic fitness device comprising: a housing including a bottom wall configured to contact a user's wrist; a first optical transmitter array positioned at a first location on the bottom wall and including a first optical transmitter, a second optical transmitter, and a third optical transmitter, each optical transmitter operable to output a first optical signal that passes through a user's skin, each first optical signal having a unique wavelength; a second optical transmitter array positioned at a second location on the bottom wall and including a first optical transmitter, a second optical transmitter, and a third optical transmitter, each optical transmitter operable to output a second optical signal that passes through a user's skin, each second optical signal having a wavelength equal to a wavelength of a corresponding first optical signal of the first optical transmitter array; and a first optical receiver, a second optical receiver, a third optical receiver, and a fourth optical receiver, the first optical receiver spaced apart from the third optical receiver with the first optical transmitter array and the second optical transmitter array positioned therebetween, the second optical receiver spaced apart from the fourth optical receiver with the first optical transmitter array and the second optical transmitter array positioned therebetween, and each optical receiver operable to receive the first optical signals and the second optical signals; wherein the first optical signals travel along a different signal path from the first optical transmitter array to each of the optical receivers; wherein the second optical signals travel along a different signal path from the second optical transmitter array to each of the optical receivers; and wherein the first optical receiver is spaced apart from the first optical transmitter array along a first axis, and the second optical receiver is spaced apart from the first optical transmitter array along a second axis, the second axis orthogonal to the first axis, on the bottom wall. 11. The electronic fitness device of claim 10 , wherein the first optical transmitter array and the second optical transmitter array are spaced apart from one another along the first axis and along the second axis on the bottom wall, and wherein each optical receiver is operable to generate a first electronic signal corresponding to the first optical signals and a second electronic signal corresponding to the second optical signals. 12. The electronic fitness device of claim 10 , wherein the first optical receiver, th