Optical system with offloaded optical components

We claim: 1 . An optical system comprising: a substrate; a first photonic integrated circuit positioned on the substrate; a second photonic integrated circuit positioned on the first photonic integrated circuit, wherein the second photonic integrated circuit is arranged to receive a first optical signal comprising a first mode and a second mode different from the first mode, and wherein the second photonic integrated circuit comprises: a polarization splitter rotator arranged to separate the first optical signal into a second optical signal with the first mode and a third optical signal with the first mode; a first demultiplexer arranged to separate the second optical signal into a first plurality of optical signals; and a second demultiplexer arranged to separate the third optical signal into a second plurality of optical signals, wherein the first plurality of optical signals and the second plurality of optical signals couple into the first photonic integrated circuit; and an electronic integrated circuit positioned on the first photonic integrated circuit wherein the first photonic integrated circuit is arranged to produce, based on the first plurality of optical signals or the second plurality of optical signals, electronic signals for the electronic integrated circuit. 2 . The optical system of claim 1 , wherein the first photonic integrated circuit comprises a through silicon via. 3 . The optical system of claim 1 , wherein the first plurality of optical signals and the second plurality of optical signals couple into the first photonic integrated circuit using a grating coupler positioned in the first photonic integrated circuit or the second photonic integrated circuit. 4 . The optical system of claim 1 , wherein the first plurality of optical signals and the second plurality of optical signals evanescently couple to the first photonic integrated circuit. 5 . The optical system of claim 1 , wherein the first plurality of optical signals and the second plurality of optical signals couple into the first photonic integrated circuit using a free space coupler positioned in the first photonic integrated circuit or the second photonic integrated circuit. 6 . The optical system of claim 1 , wherein the second photonic integrated circuit is arranged to edge couple with an optical fiber that carries the first optical signal to the second photonic integrated circuit. 7 . The optical system of claim 1 , wherein the second photonic integrated circuit is coupled to the first photonic integrated circuit by an epoxy. 8 . The optical system of claim 1 , wherein a portion of the second photonic integrated circuit extends beyond a boundary of the first photonic integrated circuit. 9 . A method comprising: receiving, at a first photonic integrated circuit, a first optical signal comprising a first mode and a second mode different from the first mode, and wherein the first photonic integrated circuit comprises a polarization splitter rotator, a first demultiplexer, and a second demultiplexer; separating, by the polarization splitter rotator, the first optical signal into a second optical signal with the first mode and a third optical signal with the first mode; separating, by the first demultiplexer, the second optical signal into a first plurality of optical signals; separating, by the second demultiplexer, the third optical signal into a second plurality of optical signals; coupling the first plurality of optical signals and the second plurality of optical signals couple into a second photonic integrated circuit, wherein the first photonic integrated circuit is positioned on the second photonic integrated circuit; and producing, by the second photonic integrated circuit and based on the first plurality of optical signals or the second plurality of optical signals, electronic signals for an electronic integrated circuit positioned on the second photonic integrated circuit. 10 . The method of claim 9 , wherein the second photonic integrated circuit comprises a through silicon via. 11 . The method of claim 9 , wherein the first plurality of optical signals and the second plurality of optical signals couple into the second photonic integrated circuit using a grating coupler positioned in the first photonic integrated circuit or the second photonic integrated circuit. 12 . The method of claim 9 , wherein the first plurality of optical signals and the second plurality of optical signals evanescently couple to the first photonic integrated circuit. 13 . The method of claim 9 , wherein the first plurality of optical signals and the second plurality of optical signals couple into the first photonic integrated circuit using a free space coupler positioned in the first photonic integrated circuit or the second photonic integrated circuit. 14 . The method of claim 9 , wherein the second photonic integrated circuit is arranged to edge couple with an optical fiber that carries the first optical signal to the second photonic integrated circuit. 15 . The method of claim 9 , wherein the second photonic integrated circuit is coupled to the first photonic integrated circuit by an epoxy. 16 . An optical circuit comprising: a first photonic integrated circuit comprising: a polarization splitter rotator arranged to separate a first optical signal into a second optical signal with a first mode and a third optical signal with the first mode, wherein the first optical signal comprises the first mode and a second mode different from the first mode; a plurality of demultiplexers arranged to separate the second optical signal into a first plurality of optical signals and the third optical signal into a second plurality of optical signals; a second photonic integrated circuit arranged to produce one or more electronic signals based on the first plurality of optical signals and the second plurality of optical signals from the first photonic integrated circuit, wherein the first photonic integrated circuit is positioned on the second photonic integrated circuit; and an electronic integrated circuit positioned on the second photonic integrated circuit, wherein the electronic integrated circuit is arranged to receive the one or more electronic signals from the photonic integrated circuit.