Cascaded electrical device bus structure systems and methods

The invention claimed is: 1. An electrical system comprising a first bus structure configured to cascade a first plurality of electrical devices, wherein the first bus structure comprises: a first outer conductive layer implemented as a first positive layer; a second outer conductive layer implemented as a first negative layer; a first intermediate conductive layer neighboring the first outer conductive layer and electrically coupled to the second outer conductive layer, wherein the first intermediate conductive layer is implemented as a second negative layer to facilitate reducing stray inductance, increasing stray capacitance, or both introduced in the electrical system during operation; a second intermediate conductive layer neighboring the second outer conductive layer and electrically coupled to the first outer conductive layer, wherein the second intermediate conductive layer is implemented as a second positive layer to facilitate reducing the stray inductance, increasing the stray capacitance, or both introduced in the electrical system during operation; and a third intermediate conductive layer neighboring the second intermediate conductive layer, wherein the third intermediate conductive layer is implemented as a first inter-device layer that facilitates electrically coupling at least two of the first plurality of electrical devices in series. 2. The electrical system of claim 1 , comprising: an alternating current power source configured to output alternating current electrical power; a direct current load configured to operate using direct current electrical power; a power converter electrically coupled between the alternating current power source and the direct current load, wherein the power converter comprises a switching device configured to disable current flow in an open position and enable current flow in a closed position; and a control system communicatively coupled to the power converter, wherein the control system is configured to instruct the switching device to alternatingly switch between the open position and the closed position to facilitate converting alternating current electrical power received from the alternating current power source into direct current electrical power, wherein: switching the switching device from the open position to the closed position produces a voltage overshoot that propagates to the first plurality of electrical devices; and magnitude of the voltage overshoot varies based at least in part on the stray inductance and the stray capacitance introduced in the electrical system. 3. The electrical system of claim 1 , comprising: a positive direct current bus electrically coupled to the first outer conductive layer and the second intermediate conductive layer; and a negative direct current bus electrically coupled to the second outer conductive layer and the first intermediate conductive layer; wherein the first bus structure is configured to electrically couple each of the first plurality of electrical devices in series between the positive direct current bus and the negative direct current bus when deployed in the electrical system. 4. The electrical system of claim 1 , comprising a fourth intermediate conductive layer neighboring the third intermediate conductive layer and neighboring the first intermediate conductive layer, wherein: the first plurality of electrical devices comprises a first electrical device, a second electrical device, and a third electrical device; the first outer conductive layer is implemented as the first positive layer and the second intermediate conductive layer is implemented as the second positive layer to facilitate electrically coupling the first electrical device to a positive direct current bus; the second outer conductive layer is implemented as the first negative layer and the first intermediate conductive layer is implemented as the second negative layer to facilitate electrically coupling the third electrical device to a negative direct current bus; the third intermediate conductive layer is implemented as the first inter-device layer to facilitate electrically coupling the first electrical device and the second electrical device in series between the positive direct current bus and the negative direct current bus; and the fourth intermediate conductive layer is implemented as a second inter-device layer to facilitate electrically coupling the second electrical device and the third electrical device in series between the positive direct current bus and the negative direct current bus. 5. The electrical system of claim 4 , wherein: the first electrical device comprises a first capacitor, the second electrical device comprises a second capacitor, and the third electrical device comprises a third capacitor; or the first electrical device comprises a first semiconductor switching device, the second electrical device comprises a second semiconductor switching device, and the third electrical device comprises a third semiconductor switching device. 6. The electrical system of claim 1 , wherein the first bus structure comprises: a first through-hole formed through at least the first outer conductive layer and the second intermediate conductive layer; a first perpendicular via disposed in the first through-hole, wherein: the first perpendicular via is electrically coupled to the first outer conductive layer and the second intermediate conductive layer in the first through-hole; the first perpendicular via is electrically insulated from the second outer conductive layer, the first intermediate conductive layer, and the third intermediate conductive layer in the first through-hole; and the first perpendicular via extends outwardly from the first bus structure to facilitate electrically and physically coupling a first electrical device of the first plurality of electrical devices to the first perpendicular via; a second through-hole formed through at least the second outer conductive layer and the first intermediate conductive layer; a second perpendicular via disposed in the second through-hole, wherein the second perpendicular via is: electrically coupled to the second outer conductive layer and the first intermediate conductive layer in the second through-hole; electrically insulated from the first outer conductive layer, the second intermediate conductive layer, and the third intermediate conductive layer in the second through-hole; and extends outwardly from the first bus structure to facilitate electrically and physically coupling a second electrical device of the first plurality of electrical devices to the second perpendicular via; a third through-hole formed through at least the third intermediate conductive layer; and a third perpendicular via disposed in the third through-hole, wherein the third perpendicular via is: electrically coupled to the third intermediate conductive layer in the third through-hole; electrically insulated from the first outer conductive layer, the second outer conductive layer, the first intermediate conductive layer, and the second intermediate conductive layer in the third through-hole; and extends outwardly from the first bus structure to facilitate electrically and physically coupling the first electrical device to the third perpendicular via. 7. The electrical system of claim 1 , wherein: the first plurality of electrical devices comprises a first electrical device, a second electrical device, and a third electrical device; the third intermediate conductive layer is implemented as the first inter-device layer to facilitate electrically coupling the first electrical device and the second electrical device in series; and the first bus structure comprises: a fourth intermediate conductive layer neighboring the third